fbpx
Wikipedia

NASA-ESA Mars Sample Return

January 01, 1970

The NASA-ESA Mars Sample Return is a proposed Flagship-class Mars sample return (MSR) mission[3] to collect Martian rock and soil samples in 43 small, cylindrical, pencil-sized, titanium tubes and return them to Earth around 2033.[4]

NASA-ESA MSR Patch
Mars Sample Return Program[1]
(Artwork; July 27, 2022)
Mars Sample Return[2](Video; November 17, 2022)

The NASAESA plan, approved in September 2022, is to return samples using three missions: a sample collection mission (Perseverance), a sample retrieval mission (Sample Retrieval Lander + Mars Ascent Vehicle + Sample Transfer Arm + 2 Ingenuity-class helicopters), and a return mission (Earth Return Orbiter).[5][6][7] The mission hopes to resolve the question of whether Mars once harbored life.

Although the proposal is still in the design stage, the Perseverance rover is currently gathering samples on Mars and the components of the sample retrieval lander are in testing phase on earth.[8][9]

After a project review critical of its cost and complexity,[10][11] NASA announced that the project was "paused" as of 13 November 2023.[12] On 22 November 2023, NASA was reported to have cut back on the Mars sample-return mission due to a possible shortage of funds.[13] In April 2024, in a NASA update via teleconference, the NASA Administrator emphasized continuing the commitment to retrieving the samples. However, under the then-current mission profile, the cost of $11 billion was infeasible, therefore NASA would turn to industry and the Jet Propulsion Laboratory to form a new, more fiscally feasible mission profile to retrieve the samples, with responses expected by fall 2024.[14][15][16]

History edit

See also: Mars sample-return mission § History

2001 to 2004 edit

In the summer of 2001 the Jet Propulsion Laboratory (JPL) requested mission concepts and proposals from industry-led teams (Boeing, Lockheed Martin, and TRW).[17] The science requirements included at least 500 grams (18 oz) of samples, rover mobility to obtain samples at least 1 kilometre (0.62 mi) from the landing spot, and drilling to obtain one sample from a depth of 2 metres (6 ft 7 in). That following winter, JPL made similar requests of certain university aerospace engineering departments (MIT and the University of Michigan).

Also in 2001, a separate set of industry studies was done for the Mars ascent vehicle (MAV) due to the uniqueness and key role of the MAV for MSR.[18] Figure 11 in this reference summarized the need for MAV flight testing at a high altitude over Earth, based on Lockheed Martin's analysis that the risk of mission failure is "extremely high" if launch vehicle components are only tested separately.

In 2003 JPL reported that the mission concepts from 2001 had been deemed too costly, which led to the study of a more affordable plan accepted by two groups of scientists, a new MSR Science Steering Group and the Mars Exploration Program Analysis Group (MEPAG).[19] Instead of a rover and deep drilling, a scoop on the lander would dig 20 centimetres (7.9 in) deep and place multiple samples together into one container. After five years of technology development, the MAV would be flight-tested twice above Earth before the mission PDR (Preliminary Design Review) in 2009.

Based on the simplified mission plan, assuming a launch from Earth in 2013 and two weeks on Mars for a 2016 return, technology development was initiated for ensuring with high reliability that potential Mars microbes would not contaminate Earth, and also that the Mars samples would not be contaminated with Earth-origin biological materials.[20] The sample container would be clean on the outside before departing from Mars, with installation onto the MAV inside an "Earth-clean MAV garage."

In 2004 JPL published an update on the 2003 plan.[21] MSR would use the new large sky crane landing system in development for the Mars Science Laboratory rover (later named Curiosity). A MSR Technology Board was formed, and it was noted that the use of a rover might return to the MSR plan, in light of success with the Spirit and Opportunity rovers that arrived early in 2004. A 285-kilogram (628 lb) ascent rocket would carry 0.5-kilogram (1.1 lb) of samples inside a 5-kilogram (11 lb) payload, the Orbiting Sample (OS). The MAV would transmit enough telemetry to reconstruct events in case of failure on the way up to Mars orbit.

2005 to 2008 edit

As of 2005 a rover had returned to the MSR plan, with a rock core drill in light of results from the Mars Exploration Rover discoveries.[22] Focused technology development would start before the end of 2005 for mission PDR in 2009, followed by launch from Earth in 2013. Related technologies in development included potential advances for Mars arrival (navigation and descent propulsion) and implementing pump-fed liquid launch vehicle technology on a scale small enough for a MAV.[23]

In late 2005 a peer-reviewed analysis showed that ascent trajectories to Mars orbit would differ depending on liquid versus solid propulsion, largely because small solid rocket motors burn faster, requiring a steeper ascent path to avoid excess atmospheric drag, while slower burning liquid propulsion might take advantage of more efficient paths to orbit.[24]

Early in 2006 the Marshall Space Flight Center noted the possibility that a science rover would cache the samples on Mars, then subsequently a mini-rover would be sent along with the MAV on a sample return lander, in which case either the mini-rover or the science rover would deliver the samples to the lander for loading onto the MAV.[25] A two-stage 250-kilogram (550 lb) solid propellant MAV would be gas ejected from a launch tube with its 5-kilogram (11 lb) payload, a 16-centimetre (6.3 in) diameter spherical package containing the samples. The second stage would send telemetry and its steering thrusters would use hydrazine fuel with additives. The authors expected the MAV to need multiple flight tests at a high altitude over Earth.

A peer-reviewed publication in 2007 described testing of autonomous sample capture for Mars orbit rendezvous.[26] Free-floating tests were done on board a NASA aircraft using a parabolic "zero-g" flight path.

In 2007 Alan Stern, then NASA's Associate Administrator for Science, was strongly in favor of completing MSR sooner, and he asked JPL to include sample caching on the Mars Science Laboratory mission (later named Curiosity).[27] A team at the Ames Research Center was designing a hockey puck-sized sample-caching device to be installed as an extra payload on MSL.[28]

A review analysis in 2008 compared Mars ascent to lunar ascent, noting that the MAV would be not only technically daunting, but also a cultural challenge for the planetary community, given that lunar ascent has been done using known technology, and that science missions typically rely on proven propulsion for course corrections and orbit insertion maneuvers, similar to what Earth satellites do routinely.[29]

2009 to 2011 edit

Early in 2009 the In-Space Propulsion Technology project office at the NASA Glenn Research Center (GRC) presented a ranking of six MAV options, concluding that a 285-kilogram (628 lb) two-stage solid rocket with continuous telemetry would be best for delivering a 5-kilogram (11 lb) sample package to Mars orbit.[30] A single-stage pump-fed bipropellant MAV[31] was noted to be less heavy and was ranked second.

Later in 2009 the chief technologist of the Mars Exploration Directorate at JPL referred to a 2008 workshop on MSR technologies at the Lunar and Planetary Institute, and wrote that particularly difficult technology challenges included the MAV, sample acquisition and handling, and back planetary protection, then further commented that "The MAV, in particular, stands out as the system with highest development risk, pointing to the need for an early start" leading to flight testing before preliminary design review (PDR) of the lander that would deliver the MAV.[32]

In October 2009 NASA and ESA established the Mars Exploration Joint Initiative to proceed with the ExoMars program, whose ultimate aim is "the return of samples from Mars in the 2020s".[33][34] ExoMars's first mission was planned to launch in 2018[35][36] with unspecified missions to return samples in the 2020–2022 time frame.[37] As reported to the NASA Advisory Council Science Committee (NAC-SC)[38] early in 2010, MEPAG estimated that MSR "will cost $8-10B, and it is obvious that NASA and ESA can't fund this amount by themselves."[39] The cancellation of the caching rover MAX-C in 2011, and later NASA withdrawal from ExoMars, due to budget limitations, ended the mission.[40] The pull-out was described as "traumatic" for the science community.[40]

In 2010–2011 the NASA In-Space Propulsion Technology (ISPT) program at the Glenn Research Center received proposals and funded industry partners for MAV design studies with contract options to begin technology development, while also considering propulsion needs for Earth return spacecraft.[41] Inserting the spacecraft into Mars orbit, then returning to Earth, was noted to need a high total of velocity changes, leading to a conclusion that solar electric propulsion could reduce mission risk by improving mass margins, compared to the previously assumed use of chemical propulsion along with aerobraking at Mars.[42] The ISPT team also studied scenarios for MAV flight testing over Earth and recommended two flight tests prior to MSR mission PDR, considering the historical low probability of initial success for new launch vehicles.[43]

The NASA–ESA potential mission schedule anticipated launches from Earth in 2018, 2022 and 2024 to send respectively a sample caching rover, a sample return orbiter and a sample retrieval lander for a 2027 Earth arrival, with MAV development starting in 2014 after two years of technology development identified by the MAV design studies.[44] The ISPT program summarized a year of propulsion technology progress for improving Mars arrival, Mars ascent, and Earth return, stating that the first flight test of a MAV engineering model would need to occur in 2018 to meet the 2024 launch date for the sample retrieval lander.[45]

The 2011 MAV industry studies were done by Lockheed-Martin teamed with ATK; Northrop-Grumman; and Firestar Technologies, to deliver a 5-kg (11-lb), 16-cm (6.3-inch) diameter sample sphere to Mars orbit.[46] The Lockheed-Martin-ATK team focused on a solid propellant first stage with either solid or liquid propellant for the upper stage, estimated MAV mass in the range 250 to 300 kg (550 to 660 lb), and identified technologies for development to reduce mass.[47] Northrop-Grumman (the former TRW) similarly estimated a mass below 300 kg using pressure-fed liquid bipropellants for both stages,[48] and had plans for further progress.[49] Firestar Technologies described a single-stage MAV design having liquid fuel and oxidizer blended together in one main propellant tank.[50]

In early 2011 the US National Research Council's Planetary Science Decadal Survey, which laid out mission planning priorities for the period 2013–2022, declared an MSR campaign its highest priority Flagship Mission for that period.[51][52] In particular, it endorsed the proposed Mars Astrobiology Explorer-Cacher (MAX-C) mission in a "descoped" (less ambitious) form. This mission plan was officially cancelled in April 2011. The plan cancelled in 2011 for budget reasons had been for NASA and ESA to each build a rover to send together in 2018.[53]

2012 to 2013 edit

In 2012 prospects for MSR were slowed further by a 38-percent cut in NASA's Mars program budget for fiscal year 2013, leading to controversy among scientists over whether Mars exploration could thrive on a series of small rover missions.[54] A Mars Program Planning Group (MPPG) was convened as one response to budget cuts.[55]

In mid-2012, eight weeks before Curiosity arrived on Mars, the Lunar and Planetary Institute hosted a NASA-sponsored three-day workshop[56] to gather expertise and ideas from a wide range of professionals and students, as input to help NASA reformulate the Mars Exploration Program, responsive to the latest Planetary Decadal Survey[51] that prioritized MSR. A summary report noted that the workshop was held in response to recent deep budget cuts, 390 submissions were received, 185 people attended and agreed that "credible steps toward MSR" could be done with reduced funding.[57] The MAX-C rover (ultimately implemented as Mars 2020, Perseverance) was considered beyond financial reach at that time, so the report noted that progress toward MSR could include an orbiter mission to test autonomous rendezvous, or a Phoenix-class lander to demonstrate pinpoint landing while delivering a MAV as a technology demonstration. The workshop consisted largely of three breakout group discussions for Technology and Enabling Capabilities, Science and Mission Concepts, and Human Exploration and Precursors.

Wide-ranging discussions were documented by the Technology Panel,[58] which suggested investments for improved drilling and "small is beautiful" rovers with an "emphasis on creative mass-lowering capabilities." The panel stated that MAV "functional technology is not new" but the Mars environment would pose challenges, and referred to MAV technologies as "a risk for most sample return scenarios of any cost range." MAV technology was addressed in numerous written submissions[59][60][61][62][63] to the workshop, one of which described Mars ascent as "beyond proven technology" (velocity and acceleration in combination for small rockets) and a "huge challenge for the social system," referring to a "Catch-22" dilemma "in which there is no tolerance for new technology if sample return is on the near-term horizon, and no MAV funding if sample return is on the far horizon."[61]

In September 2012 NASA announced its intention to further study MSR strategies as outlined by the MPPG – including a multiple launch scenario, a single-launch scenario, and a multiple-rover scenario – for a mission beginning as early as 2018.[64][65][66][67] A "fetch rover" would retrieve the sample caches and deliver them to a Mars ascent vehicle (MAV). In July 2018, NASA contracted Airbus to produce a "fetch rover" concept.[68] As of late 2012, It was determined that the MAX-C rover concept to collect samples could be implemented for a launch in 2020 (Mars 2020), within available funding using spare parts and mission plans developed for NASA's Curiosity Mars rover[69]

In 2013 the NASA Ames Research Center proposed that a SpaceX Falcon Heavy could deliver two tons of useful payload to the Mars surface, including an Earth return spacecraft that would be launched from Mars by a one-ton single-stage MAV using liquid bipropellants fed by turbopumps.[70][71][72] The successful landing of the Curiosity rover directly on its wheels (August 2012) motivated JPL to take a fresh look at carrying the MAV on the back of a rover.[73] A fully guided 300-kg MAV (like Lockheed's 2011 two-stage solid[46][47]) would avoid the need for a round-trip fetch rover. A smaller 150-kg MAV would permit one rover to also include sample collection while using MSL heritage to reduce mission cost and development time, placing most development risk on the MAV. The 150-kg MAV would be made lightweight by spinning it up before stage separation, although the lack of telemetry data from the spin-stabilized unguided upper stage was noted as a disadvantage.

JPL later presented more details of the 150-kg solid propellant mini-MAV concept of 2012, in a summary of selected past efforts.[74] The absence of telemetry data during the 1999 loss of the Mars Polar Lander had put an emphasis on "critical event communications", subsequently applied to MSR. Then after the MSL landing in 2012, requirements had been revisited with a goal to reduce MAV mass. Single fault tolerance and continuous telemetry data to Mars orbit were questioned. For the 500 grams (1.1 lb) of samples, a 3.6-kg (7.9 lb) payload was deemed possible instead of 5 kg (11 lb). The 2012 mini-MAV concept had single-string avionics, in addition to the spin-stabilized upper stage without telemetry.

2014 to 2017 edit

In 2014–2015 JPL analyzed many options for Mars ascent including solid, hybrid and liquid propellants, for payloads ranging from 6.5 kg to 25 kg.[75] Four MAV concepts using solid propellant had two stages, while one or two stages were considered for hybrid and liquid propellants. Seven options were scored for ten attributes ("figures of merit"). A single stage hybrid received the highest overall score, including the most points for reducing cost and separately for reducing complexity, with the fewest points for technology readiness. Second overall was a single-stage liquid bipropellant MAV using electric pumps. A pressure-fed bipropellant design was third, with the most points for technology readiness. Solid propellant options had lower scores, partly due to receiving very few points for flexibility. JPL and NASA Langley Research Center cautioned that the high thrust and short burn times of solid rocket motors would result in early burnout at a low altitude with substantial atmosphere remaining to coast through at high Mach numbers, raising stability and control concerns.[74][76] With concurrence from the Mars Program Director, a decision was made in January 2016 to focus limited technology development funds on advancing a hybrid propellant MAV (liquid oxidizer with solid fuel).[77]

Starting in 2015, a new effort for planetary protection moved the backward planetary protection function from the surface of Mars to the sample Return Orbiter, to "break-the-chain" in flight.[78] Concepts for brazing, bagging, and plasma sterilization were studied and tested, with a primary focus on brazing as of 2016.

2018 to 2022 edit

In April 2018 a letter of intent was signed by NASA and ESA that may provide a basis for a Mars sample-return mission.[79][80] The agreement[81] was dated during the 2nd International Mars Sample Return Conference in Berlin, Germany.[82] The conference program was archived along with 125 technical submissions that covered sample science (anticipated findings, site selection, collection, curation, analysis) and mission implementation (Mars arrival, rovers, rock drills, sample transfer robotics, Mars ascent, autonomous orbit rendezvous, interplanetary propulsion, Earth arrival, planetary protection).[83] In one of many presentations, an international science team noted that collecting sedimentary rock samples would be required to search for ancient life.[84] A joint NASA-ESA presentation described the baseline mission architecture, including sample collection by the Mars 2020 Rover derived from the MAX-C concept, a Sample Retrieval Lander, and an Earth Return Orbiter.[85] An alternative proposal was to use a SpaceX Falcon Heavy to decrease mission cost while delivering more mass to Mars and returning more samples.[86] Another submission to the Berlin conference noted that mission cost could be reduced by advancing MAV technology to enable a significantly smaller MAV for a given sample payload.[87]

In July 2019 a mission architecture was proposed.[88][89] In 2019, JPL authors summarized sample retrieval, including a sample fetch rover, options for fitting 20 or 30 sample tubes into a 12-kilogram (26 lb) payload on a 400-kilogram (880 lb) single-stage-to-orbit (SSTO) MAV that would use hybrid propellants, a liquid oxidizer with a solid wax fuel, which had been prioritized for propulsion technology development since 2016.[90] Meanwhile, the Marshall Space Flight Center (MSFC) presented a comparison of solid and hybrid propulsion for the MAV.[91] Later in 2019, MSFC and JPL had collaborated on designing a two-stage solid propellant MAV, and noted that an unguided spinning upper stage could reduce mass, but this approach was abandoned at the time due to the potential for orbital variations.[92]

Early in 2020 JPL updated the overall mission plan for an orbiting sample package (the size of a basketball[93]) containing 30 tubes, showing solid and hybrid MAV options in the range 400 to 500 kilograms (880 to 1,100 lb).[94] Adding details, MSFC presented designs for both the solid and hybrid MAV designs, for a target mass of 400 kilograms (880 lb) at Mars liftoff to deliver 20 or 30 sample tubes in a 14-to-16-kilogram (31 to 35 lb) payload package.[95][96] In April 2020, an updated version of the mission was presented.[97] The decision to adopt a two-stage solid rocket MAV was followed by Design Analysis Cycle 0.0 in the spring of 2020, which refined the MAV to a 525-kilogram (1,157 lb) design having guidance for both stages, leading to reconsideration of an unguided spin-stabilized second stage to save mass.[98]

In October 2020, the MSR Independent Review Board (IRB) released its report[99] recommending overall that the MSR program proceed, then in November NASA responded to detailed IRB recommendations.[100] The IRB noted that MSR would have eight first-time challenges including the first launch from another planet, autonomous orbital rendezvous, and robotic sample handling with sealing to "break-the-chain".[101] The IRB cautioned that the MAV will be unlike any previous launch vehicle, and experience shows that the smaller a launch vehicle, the more likely it is to end up heavier than designed.[102] Referring to the unguided upper stage of the MAV, the IRB stated the importance of telemetry for critical events, "to allow useful reconstruction of a fault during second stage flight".[103] The IRB indicated that the most probable mission cost would be $3.8-$4.4B.[104] As reported to the NAC-SC[38] in April 2021, the Planetary Science Advisory Committee (PAC)[105] was "very concerned about the high cost" of MSR, and wanted to be sure that astrobiology considerations would be included in plans for returned sample laboratories.[106]

Early in 2022 MSFC presented the guided-unguided MAV design for a 125-kilogram (276 lb) mass reduction and documented remaining challenges including aerodynamic complexities during the first stage burn and coast to altitude, a desire to locate hydrazine steering thrusters farther from the center of mass, and stage separation without tip-off rotation.[107] While stage separation and subsequent spin-up would be flight tested, the authors noted that it would be ideal to flight test an entire flight-like MAV, but there would be a large cost.

In April 2022, the United States National Academies released the Planetary Science Decadal Survey report for 2023-2032, a review of plans and priorities for the upcoming ten years, after many committee meetings starting in 2020, with consideration of over 500 independently submitted white papers, more than 100 regarding Mars including comments on science and technology for sample return.[108] The published document noted NASA's 2017 plan for a "focused and rapid" sample return campaign with essential participation from ESA, then recommended, "The highest scientific priority of NASA's robotic exploration efforts this decade should be completion of Mars Sample Return as soon as is practicably possible."[109] Decadal white papers emphasized the importance of MSR for science,[110] included a description of implementing MSR,[111] and noted that the MAV has been underestimated despite needing flight performance beyond the state of the art for small rockets,[112] needs a sustained development effort,[113] and that technology development for a smaller MAV has the potential to reduce MSR mission cost.[114] Decadal Survey committee meetings hosted numerous invited speakers, notably a presentation from the MSR IRB.[115]

As of March 2022, separate landers were planned for the fetch rover and the MAV because together they would be too large and heavy for a single lander, then a cost-saving plan as of July was to send only one lander with the MAV and rely on the Perseverance rover to pass sample tubes to the MAV in the absence of a fetch rover.[5][116] Two new lightweight helicopters on the MAV lander would serve as a backup for moving the samples on Mars.[117]

2023 to 2024 edit

At the start of 2023 it was revealed that a "Mars Sample Fetch Helicopter" had been envisioned since at least 2021 by the team at AeroVironment that created Ingenuity to fly in the thin atmosphere of Mars.[118] In a public budget meeting in March, NASA noted the high cost of MSR and had begun to assemble a second independent review board to assess the design, schedule and required funding.[119]

In September 2023, NASA convened a second independent review board for the Mars Sample Return mission.[14] [120]

In January 2024, a related proposed NASA plan had been challenged due to budget and scheduling considerations, and a newer overhaul plan undertaken.[120]

On April 15, 2024, NASA Administrator Bill Nelson and Science Mission Director Nicola Fox announced the organization's response to the September 2023 independent review board's investigation, notably the finding that Mars Sample Return at its current design and cost, originally estimated at $7 billion with Earth re-entry by 2033, would now cost more than an unacceptable $11 billion and end in Earth re-entry no sooner than 2040.[16] In response, Nelson and Fox stated that NASA would make requests to industry the next day to come up with alternatives that would likely utilize more proven mission architectures with longer heritages and comply with the board's recommendations, with responses preferred by fall 2024. They also said they would spend $310 million on the program for fiscal year 2024.[14]

Sample collection edit

The Mars 2020 mission landed the Perseverance rover, which is storing samples to be returned to Earth later.

Mars 2020 Perseverance rover edit

 
Perseverance rover - cored rock sample collection at 1000 sols (December 12, 2023)
 
Mapping Perseverance's samples collected to date (The 10 duplicate samples to be left behind at Three Forks Sample Depot are framed in green colour.)
 
Facsimiles of Perseverance's sample tubes at JPL in Southern California

The Mars 2020 mission landed the Perseverance rover in Jezero crater in February 2021. It collected multiple samples and packed them into cylinders for later return. Jezero appears to be an ancient lakebed, suitable for ground sampling.[121][122][123]

At the beginning of August 2021, Perseverance made its first attempt to collect a ground sample by drilling out a finger-size core of Martian rock.[124] This attempt did not succeed. A drill hole was produced, as indicated by instrument readings, and documented by a photograph of the drill hole. However, the sample container turned out to be empty, indicating that the rock sampled was not robust enough to produce a solid core.[125]

 
Perseverance's sampling bits
  • Far left: One pointed regolith drill
  • Middle: Six rock drills
  • Right: Two shorter abrasion tools

A second target rock judged to have a better chance to yield a sufficiently robust sample was sampled at the end of August and the beginning of September 2021. After abrading the rock, cleaning away dust by puffs of pressurized nitrogen, and inspecting the resulting rock surface, a hole was drilled on September 1. A rock sample appeared to be in the tube, but it was not immediately placed in a container. A new procedure of inspecting the tube optically was performed.[126] On September 6, the process was completed and the first sample placed in a container.[127]

In support of the NASA-ESA Mars Sample Return, rock, regolith (Martian soil), and atmosphere samples are being cached by Perseverance. As of October 2023, 27 out of 43 sample tubes have been filled,[128] including 8 igneous rock samples, 12 sedimentary rock sample tubes, a Silica-cemented carbonate rock sample tube,[129] two regolith sample tubes, an atmosphere sample tube,[130] and three witness tubes.[131] Before launch, 5 of the 43 tubes were designated "witness tubes" and filled with materials that would capture particulates in the ambient environment of Mars. Out of 43 tubes, 3 witness sample tubes will not be returned to Earth and will remain on rover as the sample canister will only have 30 tube slots. Further, 10 of the 43 tubes are left as backups at the Three Forks Sample Depot.[132]

From December 21, 2022 Perseverance started a campaign to deposit 10 of its collected samples at the backup depot, Three Forks. This work was completed on January 28, 2023.

List of samples cached edit

Sample Tube Status
  Left at Three Forks Sample Depot
  Remain stowed in the Rover
Sample Details
Sampling Attempt Date Tube No. Seal No. Ferrule Prefix[note 1] Ferrule No. Contents Sample Name and Image during Caching[note 2] Sample Depot Deposit Date, Spot and Image Rock Name Core Length[note 3] Estimated Martian Atmosphere Headspace Gas[note 4] Location Notes
1 June 22, 2021
(Sol 121) 		SN061 SN147 10464848-7 SN090[133] Witness Tube (Empty)  
WB-1 		N/A N/A 2.2 x 10−6 mol North Séítah Unit[134] This was taken as a dry-run in preparation for later sampling attempts, and did not aim to sample a rock. During final pre-launch activities, this witness tube was activated (the inner seal was punctured to begin accumulation) and placed in the Bit Carousel. This tube will therefore have accumulated contaminants for the entire duration of exposure from a few months before launch through cruise and EDL until it was sealed on the surface of Mars. Given its long exposure, it is likely that the inner surfaces of WB1 will be saturated with organic contaminants, i.e., they will be in adsorption equilibrium with their immediate surroundings in the rover (and or the entire spacecraft prior to landing). WB1 is therefore expected to have higher concentrations of contaminants, and potentially different contaminants, than the sample tubes.
2 August 6, 2021
(Sol 164) 		SN233 SN025 10464848-7 SN062 Atmospheric Gas  
Roubion (failed attempt of caching rock sample) 		 
January 4, 2023 (Sol 667) at Three Forks Sample Spot "4" 		Roubion
18°25′40″N 77°27′06″E / 18.42767°N 77.45167°E / 18.42767; 77.45167 		N/A 4.9x10−6 mol Polygon Valley, Cratered Floor Fractured Rough Unit[135] Attempted to sample a rock consisting of Basaltic lava flow or sandstone or Microgabbro but did not succeed, as they didn't reach the bit carousel and the caching system stored and sealed an empty tube. However, in this process, it collected atmospheric samples.
3 September 6, 2021
(Sol 195) 		SN266 SN170 10464848-6 SN099[136] Basalt (or possibly basaltic sandstone) Rock Sample  
Montdenier 		 
January 10, 2023 (Sol 672) at Three Forks Sample Spot "6" 		Rochette
18°25′51″N 77°26′40″E / 18.43074°N 77.44433°E / 18.43074; 77.44433 		5.98 cm (2.35 in) 1.2x10−6 mol Arturby Ridge, Citadelle, South Séítah Unit Successful sample.[137][138][139]
4 September 8, 2021
(Sol 196) 		SN267 SN170 10464848-6 SN074[140] Basalt (or possibly basaltic sandstone) Rock Sample  
Montagnac 		Rochette
18°25′51″N 77°26′40″E / 18.43074°N 77.44433°E / 18.43074; 77.44433 		6.14 cm (2.42 in) 1.3x10−6 mol Arturby Ridge, Citadelle, South Séítah Unit Sampled from same rock as previous sample.
5 November 15, 2021
(Sol 263) 		SN246 SN194 10464848-5 SN107[141] Olivine cumulate Rock Sample  
Salette 		Brac
18°26′02″N 77°26′35″E / 18.43398°N 77.44305°E / 18.43398; 77.44305 		6.28 cm (2.47 in) 1.1 x10−6 mol Brac Outcrop, South Séítah Unit
6 November 24, 2021
(Sol 271) 		SN284 SN219 10464848-6 SN189[141] Olivine cumulate Rock Sample  
Coulettes 		 
January 6, 2023 (Sol 668) at Three Forks Sample Spot "5" 		Brac
18°26′02″N 77°26′35″E / 18.43398°N 77.44305°E / 18.43398; 77.44305 		3.30 cm (1.30 in) 2.5 x10−6 mol Brac Outcrop, South Séítah Unit
7 December 22, 2021
(Sol 299) 		SN206 SN184 10464848-7 SN064 Olivine cumulate Rock Sample  
Robine 		Issole
18°25′58″N 77°26′29″E / 18.43264°N 77.44134°E / 18.43264; 77.44134 		6.08 cm (2.39 in) 1.0 x10−6 mol Issole, South Séítah Unit
8 December 29, 2021
(Sol 306) 		SN261 SN053 10464848-6 SN062 Olivine cumulate Rock Sample  
Pauls (Abandoned sample from this site due to Core Bit Dropoff.) 		 
December 21, 2022 (Sol 653) at Three Forks Sample Spot "1" 		Issole
18°25′58″N 77°26′29″E / 18.43264°N 77.44134°E / 18.43264; 77.44134 		N/A N/A Issole, South Séítah Unit Pebble-sized debris from the first sample fell into the bit carousel during transfer of the coring bit, which blocked the successful caching of the sample.[142] It was decided to abandon this sample and do a second sampling attempt again. Subsequent tests and measures cleared remaining samples in tube and debris in caching system[143][144] The tube was reused for second sample attempt, which was successful.

It was the first sample tube to be deposited at a Sample Depot (in this case the depot is Three Forks).[145]

9 January 31, 2022
(Sol 338) 		 
Malay (During Caching) 		3.07 cm (1.21 in) 2.7 x10−6 mol
10 March 7, 2022
(Sol 372) 		SN262 SN172 10464848-6 SN129 Basaltic andesite Rock Sample  
Ha'ahóni (aka "Hahonih") 		Sid
18°27′09″N 77°26′38″E / 18.45242°N 77.44386°E / 18.45242; 77.44386 		6.50 cm (2.56 in) 0.98 x10−6mol Ch'ał outcrop(100 m (330 ft) east of Octavia E. Butler Landing), Séítah Unit
11 March 13, 2022
(Sol 377) 		SN202 SN168 10464848-4 SN074 Basaltic andesite Rock Sample  
Atsá (aka "Atsah") 		 
January 20, 2023 (Sol 682) at Three Forks Sample Spot "9" 		Sid
18°27′09″N 77°26′38″E / 18.45242°N 77.44386°E / 18.45242; 77.44386 		6.00 cm (2.36 in) 1.3 x10−6 mol Ch'ał outcrop(100 m (330 ft) east of Octavia E. Butler Landing), Séítah Unit
12 July 7, 2022
(Sol 490) 		SN186 SN188 10464848-4 SN101 Clastic Sedimentary Rock Sample  
Swift Run 		Skinner Ridge
18°24′22″N 77°27′32″E / 18.40617°N 77.45893°E / 18.40617; 77.45893 		6.69 cm (2.63 in) 1.23 x 10−6 mol Skinner Ridge, Delta Front First Deltaic and First sedimentary sample cached by Perseverance.
13 July 12, 2022
(Sol 495) 		SN272 SN192 10464848-6 SN068 Clastic Sedimentary Rock Sample  
Skyland 		 
January 18, 2023 (Sol 680) at Three Forks Sample Spot "8" 		Skinner Ridge
18°24′22″N 77°27′32″E / 18.40617°N 77.45893°E / 18.40617; 77.45893 		5.85 cm (2.30 in) 1.7 x 10−6 mol Skinner Ridge, Delta Front
14 July 16, 2022
(Sol 499) 		SN205 SN119 10464848-6 SN170 Witness Tube (Empty)  
WB2 		N/A N/A 2.7 x 10−6 mol Hogwallow Flats,[146] Delta Front This may have been done to clean out any leftover debris during the previous sampling attempts. On sol 495, a string-like piece of foreign object debris (FOD) similar to materials released during EDL was observed in the workspace images. On sol 499 this object was no longer observed, presumably because it blew out of the scene. This observation suggests the possibility of FOD in tubes sealed in this general area.
15 July 27, 2022
(Sol 510) 		SN172 SN157 10464848-7 SN099 Fine grained, well-sorted sedimentary rock sample, sulphate-bearing coarse mudstone  
Hazeltop 		Wildcat Ridge
18°24′21″N 77°27′31″E / 18.40589°N 77.45863°E / 18.40589; 77.45863 		5.97 cm (2.35 in) 1.63 x 10−6 mol Wildcat Ridge, Delta Front
16 August 3, 2022
(Sol 517) 		SN259 SN177 10464848-5 SN110 Fine grained, well-sorted sedimentary rock sample, sulphate-bearing coarse mudstone  
Bearwallow 		 
January 13, 2023 (Sol 675) at Three Forks Sample Spot "7" 		Wildcat Ridge
18°24′21″N 77°27′31″E / 18.40589°N 77.45863°E / 18.40589; 77.45863 		6.24 cm (2.46 in) 1.43 x 10−6 mol Wildcat Ridge, Delta Front
17 October 2, 2022
(Sol 575) 		SN264 SN068 10464848-5 SN085 Fine grained, well-sorted sedimentary rock, olivine-bearing coarse mudstone  
Shuyak 		Amalik outcrop
77°24′05″N 18°27′03″E / 77.40144°N 18.45073°E / 77.40144; 18.45073 		5.55 cm (2.19 in) 1.73 x 10−6 mol Amalik outcrop, Delta Front
18 October 6, 2022
(Sol 579) – November 16, 2022 (Sol 589) 		SN184 SN587 10464848-4 SN030 Fine grained, well-sorted sedimentary rock, olivine-bearing coarse mudstone  
Mageik 		 
December 23, 2022 (Sol 655) at Three Forks Sample Spot "2" 		Amalik outcrop
77°24′05″N 18°27′03″E / 77.40144°N 18.45073°E / 77.40144; 18.45073 		7.36 cm (2.90 in) 0.63 x 10−6 mol Amalik outcrop, Delta Front The anomaly first appeared on Oct 5 after the successful coring of the mission's 14th sample, called "Mageik," when the seal assigned to cap the rock-core-filled sample tube did not release as expected from its dispenser.

The process of sealing a sample happens in the rover's Sampling and Caching System. During sealing, a small robotic arm moves the rock-core-filled tube to one of seven dispensers and presses its open end against a waiting seal. On the 17 previous occasions when a sample tube had been sealed during the mission, the seal was pressed fully into the tube. That allowed the seal to be extracted from the dispenser and the arm to move the seal-tube combination to a different station where they are pressed together, creating a hermetic seal. However, when the sample handling system attempted to dispense a seal in the tube of the Mageik sample, the seal encountered too much resistance and did not come free. The sampling system automatically detected the lack of seal and stored the unsealed tube safely so the tube and sample hardware remain in a stable configuration.

One of the possible causes of the seal's nondeployment may be that Martian dust adhered to a location on the tube's interior surface where the dust could impede successful coupling and extraction. To ensure a hermetic seal, the tolerances between tube and seal are, by necessity, extremely small: 0.00008 inches (0.002 mm). The rover's CacheCam captured images showing light deposits of dust on the tube's lip, but the camera's imaging capabilities along the tube's inner surface are quite limited.

Sealing which was tried again and again was finally completed on November 16, 2022 (Sol 589) successfully.[147]

19 October 14, 2022
(Sol 586) 		SN188 SN153 10464848-5 SN073 Witness Tube (Empty)  
WB3 		 
January 28, 2023 (Sol 690) at Three Forks Sample Spot "10" 		N/A N/A 2.31 x 10−6 mol The witness tubes do not collect samples but are opened near the sampling location to "witness" the Martian environment. The witness tubes go through the motions of sample collection without collecting rock or soil samples and are sealed and cached like Martian samples. Witness tubes aim to ensure that any potential Earth contaminants are detected during sample collection. This is to provide the validity of the samples once returned to Earth for analysis. During the processing of the WTA, two faults occurred. On sol 584 there was a fault during the simulated coring which resulted in only 5 of the normally 7 spindle/percuss motions being performed, and no percuss-to-ingest motion was executed. While anomaly recovery was being undertaken, the tube remained in the corer and exposed to the Martian environment about 10 times longer than normal WTA/sample exposure time. A second fault occurred after the sealing of the tube on sol 586, and left the hermetically sealed WTA sitting in the sealing station at an elevated temperature (up to 40 °C) until sol 591. The witness tube was successfully sealed on October 14, 2022 (Sol 587) and placed into storage on October 19, 2022
(Sol 592).[148]
20 November 24, 2022
(Sol 627) – November 29, 2022
(Sol 631) 		SN242 SN151 10464848-5 SN113 Fine grained, moderately-sorted sedimentary rock, sulphate-bearing coarse sandstone  
Kukaklek 		Hidden Harbor
77°23′57″N 18°27′13″E / 77.39911°N 18.45364°E / 77.39911; 18.45364 		4.97 cm (1.96 in) 1.78 x 10−6 mol Hidden Harbor, Delta Front First Sample from an abrasion patch, abraded earlier on the rock. It was sampled on November 29, 2022
(Sol 631)
21 December 2, 2022
(Sol 634) 		SN059 SN098 10464848-5 SN063 Regolith Sand Sample, likely containing mixed sedimentary and igneous grains  
Atmo Mountain 		Observation Mountain
77°24′04″N 18°27′05″E / 77.40122°N 18.45131°E / 77.40122; 18.45131 		5.30 cm (2.09 in) 1.87 x 10−6 mol Observation Mountain, Delta Front First Regolith Sample.
22 November 7, 2022
(Sol 639) 		SN173 SN191 10464848-6 SN106 Regolith Sand Sample, likely containing mixed sedimentary and igneous grains  
Crosswind Lake 		 
December 29, 2022 (Sol 661) at Three Forks Sample Spot "3" 		Observation Mountain
77°24′04″N 18°27′05″E / 77.40122°N 18.45131°E / 77.40122; 18.45131 		5.30 cm (2.09 in) 1.88 x 10−6 mol Observation Mountain, Delta Front
23 March 30, 2023
(Sol 749) 		SN214 SN066 1064848-5 SN150 Sedimentary Rock Sample  
Melyn 		Berea Outcrop
77°23′02″N 18°28′13″E / 77.383946°N 18.470216°E / 77.383946; 18.470216 		6.04 cm (2.38 in) Berea, Tenby, Upper Fan First Sample taken after completion of sample depot and the first taken under the new mission campaign.
24 May 23, 2023
(Sol 802) 		SN094 10464848-3 Conglomerate Sedimentary Rock Sample N/A (Abandoned sample from this site due to small sample collection.) Onahu outcrop
77°22′07″N 18°26′00″E / 77.368526°N 18.433455°E / 77.368526; 18.433455 		1.30 cm (0.51 in) (Non-Cached) N/A Onahu, Upper Fan The first attempt yielded a sample that was unfortunately too small, and the second attempt was unsuccessful and caching would have resulted in another empty Roubion atmospheric sample tube.

A conglomerate rock is of special interest to the Science Team because they are made up of many clasts of rocks. These distinct clasts become cemented together over time to form the conglomerate. Importantly, these clasts were likely transported to Jezero crater from much farther away. Analyzing the distinct clasts and cements captured in a sample of the conglomerate would give insights into where these materials were sourced, how far they traveled, and what the martian environment was like, both when the clasts first formed and when the conglomerate rock formed.

25 June 4, 2023
(Sol 813) 		N/A (Abandoned after failed attempt of collecting rock sample) N/A N/A
26 June 23, 2023
(Sol 832) 		Otis Peak Emerald Lake
77°22′05″N 18°28′59″E / 77.368179°N 18.482989°E / 77.368179; 18.482989 		5.77 cm (2.27 in) Emerald Lake, Upper Fan
27 September 15, 2023
(Sol 914) 		SN258 SN451 10464848-4 SN196 Pilot Mountain Dream Lake 6.00 cm (2.36 in) Dream Lake, Upper Fan
28 September 23, 2023
(Sol 922) 		Sedimentary Rock Sample Pelican Point Hans Amundsen Memorial Workspace 6.10 cm (2.40 in) Hans Amundsen Memorial Workspace, Margin Unit
29 October 21, 2023
(Sol 949) 		Sedimentary Rock Sample Lefroy Bay Turquoise Bay 4.70 cm (1.85 in) Turquoise Bay, Margin Unit
30 March 11, 2024
(Sol 1087) 		Silica-cemented Carbonate Comet Geyser Bunsen Peak 5.78 cm (2.28 in) Bunsen Peak, Margin Unit
Sources:[149][150][151][152][153][154]
Sample and Depot Overview
Samples Tubes Cached  (63%)
43
27
Samples Tubes Left at Three Forks Sample Depot  (100%)
10


Type Of Cached Samples

Samples By Type

  Witness (3) (11.11%)
  Atmospheric (1) (3.70%)
  Igneous (8) (29.63%)
  Sedimentary (12) (44.44%)
  Regolith (2) (7.40%)
  Silica-cemented Carbonate (1) (3.70%)
Drilled Holes
 
All Drilled Holes On Mars By Perseverance (except Atsá sample) (Scrollable image)
Sample Depot at Three Forks
 
Mars Sample Depot at 3 forks

Three Forks Sample Depot edit

After nearly a Martian year of NASA's Perseverance Mars rover's science and sample caching operations for MSR campaign, the rover is currently tasked to deposit ten samples that it has cached from beginning at Three Forks Sample Depot as NASA aims to eventually return them to Earth starting from December 19, 2022. This depot will serve as a backup spot, in case Perseverance cannot deliver its samples. Perseverance is depositing the samples at a relatively flat terrain known as Three Forks so that NASA and ESA could recover them in its successive missions in the MSR campaign. It is even selected as the backup landing spot for the Sample Retrieval Lander. It is a relatively benign place. It is as flat and smooth as a table top.

 
Testing a Sample Drop in the Mars Yard with VSTB OPTIMISM Rover

Perseverance's complex Sampling and Caching System takes almost an hour to retrieve the metal tube from inside the rover's belly, view it one last time with its internal Cachecam, and drop the sample ~0.89 m (2 ft 11 in) onto a carefully selected patch of Martian surface.[145]

 
Mars Perseverance rover – wind lifts a massive dust cloud (June 18, 2021)

The tubes will not be piled up at a single spot. Instead, each tube-drop location will have an "area of operation" ~5.5 m (18 ft) in diameter. To that end, the tubes will be deposited on the surface in an intricate zigzag pattern of 10 spots for 10 tubes, with each sample ~5 m (16 ft) to ~15 m (49 ft) apart from one another near the proposed Sample retrieval lander's landing site. There are various reasons for this plan, most significantly the design of the sample recovery helicopters. They are designed to interact with only one tube at a time. Alongside, they will perform takeoffs and landings, and driving in that spot. To ensure a helicopter could retrieve samples without any problem, the plan is to be executed properly and would span over more than two months.

 
Perseverance Views Dust Devils Swirling Across Jezero Crater

Before and after Perseverance drops each tube, mission controllers will review a multitude of images from the rover's SHERLOC WATSON camera. Images by the SHERLOC WATSON camera are also used to check for surety that the tube had not rolled into the path of the rover's wheels. They also look to ensure the tube had not landed in such a way that it was standing on its end (each tube has a flat end piece called a "glove" to make it easier to be picked up by future missions). That occurred less than 5% of the time during testing with Perseverance's Earthly twin OPTIMISM in JPL's Mars Yard. In case it does happen on Mars, the mission has written a series of commands for Perseverance to carefully knock the tube over with part of the turret at the end of its robotic arm.

 
A Map of Perseverance's Sample Depots

These SHERLOC WATSON camera images will also give the Mars Sample Return team the precise data necessary to locate the tubes in the event of the samples becoming covered by dust or sand before they are collected. Mars does get windy, but not like on Earth, as the atmosphere on Mars is 100 times less dense than that of Earth's atmosphere, so winds on Mars can pick up speed (the fastest are Dust devils), but they don't pick up a lot of dust particles. Martian wind can certainly lift fine dust and leave it on surfaces, but even if significant dust is accumulated these images the depositing pattern will help to recover them back.[155] A lucky encounter with a dust devil could remove dust over the samples as in case with the solar panels of Spirit rover and Opportunity rover.

Once this whole task of depositing all the 10 samples is completed, Perseverance will carry on with its mission, traversing to the Crater floor and scaling Delta's summit. The rover be traversing along the edge of the crater and probably, caching more tubes then whilst following the plan of taking single sample at one rock. Till now, several pairs of samples were taken and one samples from pair will be placed at the depot and the other pair will stay on board the rover.[156][157]

Sample retrieval edit

The Mars Sample Return mission earlier in its design process consisted of the ESA Sample Fetch Rover and its associated second lander, alongside the Mars ascent vehicle and its lander that will take the samples to it, from where the samples will be launched back to Earth. But after consideration and cost overruns, it was decided that given Perseverance's expected longevity, the extant rover will be the primary means of transporting samples to the Sample Retrieval Lander (SRL).

Sample Retrieval Lander edit

The sample retrieval mission involves launching a 5-solar array sample return lander in 2028 with the Mars Ascent Vehicle and two sample recovery helicopters as a backup for Perseverance. The SRL lander is about the size of an average two-car garage weighing ~3,375 kg (7,441 lb); tentatively planned to be 7.7 m (25 ft) wide and 2.1 m (6.9 ft) high when fully deployed. The payload mass of the lander is double that of the Perseverance rover, that is, ~563 kg (1,241 lb). The lander needs to be close to the Perseverance rover to facilitate the transfer of Mars samples. It must land within 60 m (200 ft) of its target site – much closer than previous Mars rovers and landers. Thus, it will have a secondary battery to power the lander to land on Mars. The lander would take advantage of an enhanced version of NASA's successful Terrain Relative Navigation that helped land Perseverance safely. The new Enhanced Lander Vision System would, among other improvements, add a second camera, an altimeter, and better capabilities to use propulsion for precision landing. It is planned to land near at Three Forks in 2029.

 
ESA Sample Transfer Arm

The Mars 2020 rover and helicopters will transport the samples to the SRL lander. SRL's ESA-built ~2.40 m (7.9 ft) long, Sample Transfer Arm will be used to extract the samples and load them into the Sample Return Capsule in the Ascent Vehicle.[5][158]

Mars Sample Recovery Helicopters edit

Main article: Mars Sample Recovery Helicopter

The MSR campaign includes Ingenuity-class helicopters, both of which will collect the samples with the help of a tiny robotic arm and move them to the SRL, in case the Perseverance rover runs into problems.

Mars Ascent Vehicle (MAV) edit

Mars Ascent Vehicle[159]
 
Mars Ascent Vehicle mockup on display.
FunctionMars Orbital launch vehicle
ManufacturerNASA's Marshall Space Flight Center/Lockheed Martin/Northrop Grumman[160][161]
Country of originUnited States
Size
Height2.26 m (7.4 ft)
Diameter0.5 m (1.6 ft)
Mass450 kg (990 lb)
Stages2
Capacity
Payload to LAO
Altitude500 km (310 mi)
Mass500 g (18 oz)
Launch history
StatusUnder Development
Launch sitesVector mid-air after release from Sample Retrieval Lander, Three Forks, Jezero Crater
Total launches1 (planned)
UTC date of spacecraft launch2030 (planned)
Type of passengers/cargoOrbiting Sample Container with 30–43 tubes, Radio Beacon (hosted)
First stage
Powered by1 optimized Star 20 (Altair 3)
Burn time75 s
PropellantCTPB
Second stage
Powered by1 optimized Star 15G
Burn time20 s
PropellantHTPB
[edit on Wikidata]

Mars Ascent Vehicle (MAV) is a two-stage, solid-fueled rocket that will deliver the collected samples from the surface of Mars to the Earth Return Orbiter. Early in 2022, Lockheed Martin was awarded a contract to partner with NASA's Marshall Space Flight Center in developing the MAV and engines from Northrop Grumman.[162] It is planned to be catapulted upward as high as 4.5 m (15 ft) above the lander – or 6.5 m (21 ft) above the Martian surface, into the air just before it ignites, at a rate of 5 m (16 ft) per second, to remove the odds of liftoff issues such as slipping or tilting the SRL with the rocket's sheer weight and exhaust at liftoff. The front would be tossed a bit harder than the back, causing the rocket to point upward, toward the Martian sky. Thus, the Vertically Ejected Controlled Tip-off Release (VECTOR) system adds a slight rotation during launch, pitching the rocket up and away from the surface.[163] MAV would enter a 380-kilometre (240 mi) orbit.[164] It will remain stowed inside a cylinder on the SRL and will have a thermal protective coating. The rocket's first stage (SRM-1) would burn for 75 seconds. The SRM1 engine can gimbal, but most gimballing solid rocket motor nozzles are designed in a way that can't handle the extreme cold MAV will experience, so the Northrop Grumman team had to come up with something that could: a state-of-the-art trapped ball nozzle featuring a supersonic split line.[citation needed] After SRM1 burnout, the MAV will remain in a coast period for approximately 400 seconds. During this time, the MPA aerodynamic fairing and entire first stage will separate from the vehicle. After stage separation, the second stage will initiate a spin up via side mounted small scale RCS thrusters. The entire second stage will be unguided and spin-stabilized at a rate of approximately 175 RPM. Having achieved the target spin rate, the second stage (SRM-2) will ignite and burn for approximately 18-20 seconds, raising the periapsis and circularizing the orbit.[165] The second stage is planned to be spin-stabilized to save weight in lieu of active guidance, while the Mars samples will result in an unknown payload mass distribution.[164] Spin stabilization allows the rocket to be lighter, so it won't have to carry active control all the way to orbit. Following SRM2 burnout, the second stage will coast for up to 10 minutes while residual thrust from the SRM2 occurs. Side-mounted small de-spin motors will then fire, reducing the spin rate to less than 40 RPM. Once the target orbit has been achieved, the MAV will command the MPA to eject the Orbiting Sample Container (OS). The spent second stage of the MAV will remain in orbit, broadcasting a hosted radio beacon signal for up to 25 days. This will aid in the capture of the OS by the ERO.[159]

MAV is scheduled to be launched in 2028 onboard the SRL lander.[5]

Components of the Sample Return Landers
 
Concept launch set-up
 
Interior design of MAV, First Extraterrestrial Staging Rocket
 
MAV exterior design
 
MAV flight plan
 
Mars Sample Return 2020–2033 Timeline

Sample return edit

Earth Return Orbiter (ERO) edit

ERO is an ESA-developed spacecraft.[166][167] It includes the NASA-built Capture and Containment and Return System (CCRS) and Electra UHF Communications Package. It will rendezvous with the samples delivered by MAV in low Mars orbit (LMO). The ERO orbiter is planned to weigh ~7,000 kg (15,000 lb) (largest Mars Orbiter) and have solar arrays resulting in a wingspan of more than 38 m (125 ft). These solar panels are some of the largest ever launched into space.[168]

ERO is scheduled to launch on an Ariane 6 rocket in 2027 and arrive at Mars in 2029, using ion propulsion and a separate chemical propulsion element to gradually reach the proper orbit of 325 km (202 mi) and then rendezvous with the orbiting sample.[169] The MAV's second stage's radio beacon will give controllers the information they need to get the ESA Earth Return Orbiter close enough to the Orbiting Sample to see it through reflective light and capture it for return to earth. To do this, the ERO would use high-performance cameras to detect the Orbiting Sample at over 1,000 km (620 mi) distance. Once "locked on" the ERO would track it continuously using cameras and LiDARs throughout the rendezvous phase. Once aligned with the sample container, the Capture, Containment, and Return System would power on, open its capture lid, and turn on its capture sensors. ESA's orbiter would then push itself toward the sample container at about 1 to 2 inches (2.5 to 5 centimeters) per second to overtake and "swallow" it. After detecting that the sample container is safely inside, the Capture, Containment, and Return System would quickly close its lid. Thus, the orbiter will retrieve and seal the canisters in orbit and use a NASA-built robotic arm to place the sealed container into an Earth-entry capsule. The 600 kg (1,300 lb) CCRS would be responsible for thoroughly sterilizing the exterior of the Orbiting Sample and double sealing it inside the EES, creating a secondary containment barrier to keep the samples safely isolated and intact for maximum scientific return. It will raise its orbit, jettison the propulsion element (including ~500 kg (1,100 lb) of CCRS hardware, which is of no use after sterilizing samples), and return to Earth during the 2033 Mars-to-Earth transfer window.[168]

The ERO will measure the total radiation dose received throughout the entire flight. Results will help monitor the health of the spacecraft and provide important information on how to protect human explorers in future trips to Mars.[168]

Earth Entry Vehicle (EEV) edit

 
OSIRIS-REx Sample Return Capsule in Utah (The EEV will have a similar design with added structural hardening to withstand a non-parachuted landing)

The Capture/Containment and Return System (CCRS) would stow the sample in the EEV. The EEV would return to Earth and land passively, without a parachute. About a week before arrival at Earth, and only after successfully completing a full system safety check-out, the ERO spacecraft would be configured to perform the Earth return phase. When the orbiter is three days away from Earth, the EEV will be released from the main spacecraft and fly a precision entry trajectory to a predetermined landing site. Shortly after separation, the orbiter itself would perform a series of maneuvers to enter orbit around the Sun, never to return to Earth. The desert sand at the Utah Test and Training Range and shock absorbing materials in the vehicle are planned to protect the samples from impact forces.[170][171][167] The EEV is scheduled to land on Earth in 2033.[172]

Artist's concept of Mars sample return orbiter
 
Cross section of the Earth return orbiter
 
Earth Return Orbiter
 
Capture and containment system

Gallery edit

  • Potential sample-return landing site (14 April 2022)
  •  
  •  
Mars sample-return mission – Sampling Process
 
Context
 
MidView
 
CloseUp
 
Sample in drill
 
Sampling drill
 
Sample Tube 233
Mars sample-return mission – Sample Tubes
 
Exterior
 
Interior
 
CT Scan (animation)
 
Witness Sample Tube
Mars sample-return mission
Perseverance rover – Sample collection and storage
(animated video; 02:22; February 6, 2020)
 
Orbiting sample container (concept; 2020)
 
Inserting sample tubes into the rover
 
Cleaning sample tubes
Mars sample-return mission (2020; artist's impression)[173][174]
 
01. Perseverance rover obtaining samples
 
02. Perseverance rover storing samples
 
03. SRL 1 landing pattern
 
04. SRL unfolded
 
05. Mars Samples return helicopters deployed by SRL and fetching samples as a backup
 
06. SRL picking up samples and loading them on MAV for launch
 
07. Launching from Mars to low Martian Orbit
 
08. MAV in powered flight after release from vector
 
09. MAV in coast phase in Low Mars orbit after Main engine cutoff awaiting stage separation and second engine startup
 
10. Payload Separation thereby Releasing samples for later pickup by the Earth Return Orbiter

See also edit

Notes edit

  1. ^ Based on CacheCam Images[clarify]
  2. ^ The witness tubes not involving use of drill bits or using regolith drill bit are displayed by cachecam images
  3. ^ measured by volume stations
  4. ^ measured by volume stations

References edit

  1. ^ Chang, Kenneth (July 27, 2022). "NASA Will Send More Helicopters to Mars – Instead of sending another rover to help retrieve rock and dirt samples from the red planet and bring them to Earth, the agency will provide the helicopters as a backup option". The New York Times. Retrieved July 28, 2022.
  2. ^ Mars Sample Return: Bringing Mars Rock Samples Back to Earth, retrieved February 6, 2023
  3. ^ Berger, Eric (September 21, 2023). "Independent reviewers find NASA Mars Sample Return plans are seriously flawed". Ars Technica. Retrieved September 23, 2023.
  4. ^ Chang, Kenneth (July 28, 2020). "Bringing Mars Rocks to Earth: Our Greatest Interplanetary Circus Act – NASA and the European Space Agency plan to toss rocks from one spacecraft to another before the samples finally land on Earth in 2031". The New York Times. Retrieved July 28, 2020.
  5. ^ a b c d Foust, Jeff (March 27, 2022). "NASA to delay Mars Sample Return, switch to dual-lander approach". SpaceNews. Retrieved March 28, 2022.
  6. ^ "Future Planetary Exploration: New Mars Sample Return Plan". December 8, 2009.
  7. ^ "Mars sample return". www.esa.int. Retrieved January 3, 2022.
  8. ^ mars.nasa.gov. "Mars Sample Return Campaign". mars.nasa.gov. Retrieved June 15, 2022.
  9. ^ mars.nasa.gov. "NASA Mars Ascent Vehicle Continues Progress Toward Mars Sample Return". NASA Mars Exploration. Retrieved August 1, 2023.
  10. ^ Berger, Eric (June 23, 2023). "NASA's Mars Sample Return has a new price tag—and it's colossal". Ars Technica. Retrieved August 1, 2023.
  11. ^ Berger, Eric (July 13, 2023). "The Senate just lobbed a tactical nuke at NASA's Mars Sample Return program". Ars Technica. Retrieved August 1, 2023.
  12. ^ Smith, Marcia (November 13, 2023). "NASA "Pauses" Mars Sample Return Program While Assessing Options". spacepolicyonline.com. Retrieved November 18, 2023.
  13. ^ Berg, Matt (November 22, 2023). "Lawmakers 'mystified' after NASA scales back Mars collection program - The space agency's cut could "cost hundreds of jobs and a decade of lost science," the bipartisan group says". Politico. Archived from the original on November 22, 2023. Retrieved November 25, 2023.
  14. ^ a b c "NASA Invites Media to Mars Sample Return Update - NASA". Retrieved April 15, 2024.
  15. ^ "NASA says it's revising the Mars Sample Return mission due to cost, long wait time". ABC News. Retrieved April 15, 2024.
  16. ^ a b Chang, Kenneth (April 15, 2024). "NASA Seeks 'Hail Mary' for Its Mars Rocks Return Mission - The agency will seek new ideas for its Mars Sample Return program, expected to be billions of dollars over budget and years behind schedule". The New York Times. Archived from the original on April 16, 2024. Retrieved April 16, 2024.
  17. ^ "Mars Sample Return – Studies for a Fresh Look," R. Mattingly, S. Matousek and R. Gershman, 2002 IEEE Aerospace Conference, 2–493.
  18. ^ "Mars Ascent Vehicle – Concept Development," D. Stephenson, AIAA 2002–4318, 38th AIAA/ASME/SAE/ASEE Joint Propulsion Conference, July 7–10, 2002.
  19. ^ "Mars Sample Return, Updated to a Groundbreaking Approach," R. Mattingly, S. Matousek and F. Jordan, 2003 IEEE Aerospace Conference, 2–745.
  20. ^ "Planetary Protection Technology for Mars Sample Return," R. Gershman, M. Adams, R. Dillman and J. Fragola, paper number 1444, 2005 IEEE Aerospace Conference, March 2005.
  21. ^ "Continuing Evolution of Mars Sample Return," R. Mattingly, S. Matousek and F. Jordan, 2004 IEEE Aerospace Conference, p. 477.
  22. ^ "Technology Development Plans for the Mars Sample Return Mission," R. Mattingly, S. Hayati and G. Udomkesmalee, 2005 IEEE Aerospace Conference.
  23. ^ "Mars Base Technology Program Overview," C. Chu, S. Hayati, S Udomkesmalee and D Lavery, AIAA 2005–6744, AIAA Space 2005 Conference, August 30 to September 1, 2005.
  24. ^ Whitehead, J.C. (November–December 2005). "Trajectory Analysis and Staging Trades for Smaller Mars Ascent Vehicles". Journal of Spacecraft and Rockets. 42 (6): 1039–1046. Bibcode:2005JSpRo..42.1039W. doi:10.2514/1.10680.
  25. ^ "Mars Ascent Vehicle Key Elements of a Mars Sample Return Mission," D. Stephenson and H. Willenberg, 2006 IEEE Aerospace Conference paper number 1009.
  26. ^ Kornfeld, R., J. Parrish, and S. Sell (May–June 2007). "Mars Sample Return: Testing the Last Meter of Rendezvous and Sample Capture." Journal of Spacecraft and Rockets. 44 (3): 692–702.
  27. ^ "Space, science, and the bottom line," A. Witze, Nature. 448, p 978, August 30, 2007.
  28. ^ "Mars Sample Return Proposal Stirs Excitement, Controversy," L. David, Space News, July 23, 2007, p 19.
  29. ^ "Defining the Mars Ascent Problem for Sample Return," J. Whitehead, AIAA 2008–7768, AIAA Space 2008 Conference, San Diego Calif., September 2008.
  30. ^ "Mars Ascent Vehicle Technology Planning," J. Dankanich, 2009 IEEE Aerospace Conference, March 2009.
  31. ^ "Pump Fed Propulsion for Mars Ascent and Other Challenging Maneuvers," J. Whitehead, NASA Science Technology Conference, June 2007.
  32. ^ "Strategic Technology Development for Future Mars Missions (2013–2022)," S. Hayati et al., A white paper submitted to the National Research Council as input to the Planetary Decadal Survey, September 2009. https://mepag.jpl.nasa.gov/reports/decadal/SamadAHayati.pdf Mars Exploration Program Analysis Group, Retrieved November 11, 2022
  33. ^ . NASA. July 8, 2009. Archived from the original on October 28, 2009. Retrieved December 27, 2022.   This article incorporates text from this source, which is in the public domain.
  34. ^ Christensen, Phil (April 2010). "Planetary Science Decadal Survey: MSR Lander Mission". JPL. NASA. Retrieved August 24, 2012.   This article incorporates text from this source, which is in the public domain.
  35. ^ Mars Sample-Return May 18, 2008, at the Wayback Machine NASA Accessed May 26, 2008   This article incorporates text from this source, which is in the public domain.
  36. ^ "BBC – Science/Nature – Date set for Mars sample mission". July 10, 2008.
  37. ^ "Mars Sample Return: bridging robotic and human exploration". European Space Agency. July 21, 2008. Retrieved November 18, 2008.
  38. ^ a b "NASA Advisory Council Science Committee website," https://science.nasa.gov/science-committee, Retrieved July 4, 2023
  39. ^ "NASA Advisory Council Science Committee February 16–17, 2010 Meeting Report," https://smd-prod.s3.amazonaws.com/science-pink/s3fs-public/mnt/medialibrary/2010/08/31/SC-Minutes-Feb2010_Mtg-Final-100423-Signed.pdf#page=6, NASA Headquarters. Page 6. Retrieved July 4, 2023
  40. ^ a b "International cooperation called key to planet exploration". NBC News. August 22, 2012.
  41. ^ "Sample Return Propulsion Technology Development under NASA's ISPT Project," D. Anderson, J. Dankanich, D. Hahne, E. Pencil, T. Peterson, and M. Munk, 2011 IEEE Aerospace Conference, Paper number 1115, March 2011.
  42. ^ "Mars Sample Return Orbiter/Earth Return Vehicle Technology Needs and Mission Risk Assessment," J. Dankanich, L. Burke, and J. Hemminger, 2010 IEEE Aerospace Conference, Paper number 1483, March 2010.
  43. ^ "Mars Ascent Vehicle Test Requirements and Terrestrial Validation," D. Anderson, J. Dankanich, D. Hahne, E. Pencil, T. Peterson, and M. Munk, 2011 IEEE Aerospace Conference, Paper number 1115, March 2011.
  44. ^ "Mars Sample Return Campaign Status," E. Nilsen, C. Whetsel, R. Mattingly, and L. May 2012 IEEE Aerospace Conference, Paper number 1627, March 2012.
  45. ^ "Status of Sample Return Propulsion Technology Development under NASA's ISPT Program," D. Anderson, M. Munk, J. Dankanich, L. Glaab, E. Pencil, and T. Peterson, 2012 IEEE Aerospace Conference, March 2012.
  46. ^ a b "Mars Ascent Vehicle Development Status," J. Dankanich and E. Klein, 2012 IEEE Aerospace Conference, March 2012.
  47. ^ a b "Mars Ascent Vehicle (MAV): Designing for High Heritage and Low Risk," D. Ross, J. Russell, and B. Sutter, 2012 IEEE Aerospace Conference, March 2012.
  48. ^ "Mars Ascent Vehicle System Studies and Baseline Conceptual Design," M. Trinidad, E. Zabrensky, and A. Sengupta, 2012 IEEE Aerospace Conference, March 2012.
  49. ^ "Systems Engineering and Support Systems Technology Considerations of a Mars Ascent Vehicle," A. Sengupta, M. Pauken, A. Kennett, M. Trinidad, and E. Zabrensky, 2012 IEEE Aerospace Conference, March 2012.
  50. ^ "NOFBX Single Stage to Orbit Mars Ascent Vehicle," G. Mungas, D. Fisher, J. Vozoff, and M. Villa, 2012 IEEE Aerospace Conference, March 2012.
  51. ^ a b National Academy of Sciences, National Academies Press, http://www.nap.edu/download.php?record_id=13117 , Visions and Voyages for Planetary Science in the Decade 2013–2022, 2011; ISBN 978-0-309-22464-2. Retrieved December 30, 2022
  52. ^ "EXPLORING OUR SOLAR SYSTEM: THE ASTEROIDS ACT AS A KEY STEP". www.govinfo.gov.
  53. ^ "Will Tight Budgets Sink NASA Flagships?," Y. Bhattacharjee, Science, 334: 758–759 11 November 2011.
  54. ^ "Planetary Science is Busting Budgets," R. Kerr, Science, 337: 402–404, July 27, 2012.
  55. ^ "House Panel Wants NASA to Plan Mars Sample Return," Y. Bhattacharjee, Science, April 18, 2012.
  56. ^ "Concepts and Approaches for Mars Exploration, June 12–14, 2012, Houston, Texas," https://www.lpi.usra.edu/meetings/marsconcepts2012/, Universities Space Research Association website. Retrieved August 15, 2023
  57. ^ "Concepts and Approaches for Mars Exploration - Report of a Workshop at LPI, June 12–14, 2012," https://www.lpi.usra.edu/lpi/contribution_docs/LPI-001676.pdf, S. Mackwell et al, Universities Space Research Association website. Retrieved August 15, 2023
  58. ^ "Technology and Enabling Capabilities," https://www.lpi.usra.edu/meetings/marsconcepts2012/reports/1_technology_and_enabling_capabilities.pdf, M. Amato, B. Ehlmann, V. Hamilton, B. Mulac, Universities Space Research Association website. Retrieved August 15, 2023
  59. ^ "Launch and Transfer Systems Technology and Architecture Considerations for Mars Exploration," https://www.lpi.usra.edu/meetings/marsconcepts2012/pdf/4144.pdf, L. Craig, Universities Space Research Association website. Retrieved August 15, 2023
  60. ^ "High-Performance Mars Ascent Propulsion Technologies with Adaptability to ISRU and Human Exploration," https://www.lpi.usra.edu/meetings/marsconcepts2012/pdf/4222.pdf, M. Trinidad, J. Calvignac, A. Lo, Universities Space Research Association website. Retrieved August 15, 2023
  61. ^ a b "A Perspective on Mars Ascent for Scientists," https://www.lpi.usra.edu/meetings/marsconcepts2012/pdf/4290.pdf, J. Whitehead, Universities Space Research Association website. Retrieved August 15, 2023
  62. ^ "A Storable, Hybrid Mars Ascent Vehicle Technology Demonstrator for the 2020 Launch Opportunity," https://www.lpi.usra.edu/meetings/marsconcepts2012/pdf/4342.pdf, A. Chandler et al, Universities Space Research Association website. Retrieved August 15, 2023
  63. ^ "NOFBX™ Mars Ascent Vehicle: A Single Stage to Orbit Approach," https://www.lpi.usra.edu/meetings/marsconcepts2012/pdf/4353.pdf, J. Vozoff, D Fisher, G. Mungas, Universities Space Research Association website. Retrieved August 15, 2023
  64. ^ Leone, Dan (October 3, 2012). "Mars Planning Group Endorses Sample Return". SpaceNews. Retrieved March 1, 2022.
  65. ^ Mars Program Planning Group, September 25, 2012, (PDF). Archived from the original (PDF) on June 2, 2016. Retrieved December 27, 2022.
  66. ^ Wall, Mike (September 27, 2012). "Bringing Pieces of Mars to Earth: How NASA Will Do It". Space.com.
  67. ^ Mattingly, Richard (March 2010). (PDF). NASA. Archived from the original (PDF) on September 29, 2015.   This article incorporates text from this source, which is in the public domain.
  68. ^ Amos, Jonathan (July 6, 2018). "Fetch rover! Robot to retrieve Mars rocks". BBC.
  69. ^ Harwood, William (December 4, 2012). "NASA announces plans for new US$1.5 billion Mars rover". CNET. Retrieved August 15, 2023. Using spare parts and mission plans developed for NASA's Curiosity Mars rover, the space agency says it can build and launch the rover in 2020 and stay within current budget guidelines.
  70. ^ "Mars Sample Return Using Commercial Capabilities: Mission Architecture Overview," A. Gonzales, C. Stoker, L. Lemke, J. Bowles, L. Huynh, N. Faber, and M. Race, 2014 IEEE Aerospace Conference, March 2014.
  71. ^ "Mars Sample Return Using Commercial Capabilities: Propulsive Entry, Descent, and Landing," L. Lemke, A. Gonzales, and L. Huynh, 2014 IEEE Aerospace Conference, March 2014.
  72. ^ "Mars Sample Return: Mars Ascent Vehicle Mission & Technology Requirements," J. Bowles, L. Huynh, V. Hawke, and X. Jiang, NASA/TM-2013-216620, November 2013. https://ntrs.nasa.gov/api/citations/20140011316/downloads/20140011316.pdf NASA Technical Reports Server, Retrieved January 8, 2023
  73. ^ "The Mobile MAV Concept for Mars Sample Return," E. Klein, E. Nilsen, A. Nicholas, C. Whetsel, J. Parrish, R. Mattingly, and L. May 2014 IEEE Aerospace Conference, March 2014.
  74. ^ a b "History of Mars Ascent Vehicle Development Over the Last 20 Years," R. Shotwell, 2016 IEEE Aerospace Conference, March 2016.
  75. ^ "Technology Development and Design of Liquid Bipropellant Mars Ascent Vehicles," D. Vaughan, B. Nakazono, A. Karp, R. Shotwell, A. London, A. Mehra, and F. Mechentel, 2016 IEEE Aerospace Conference, March 2016.
  76. ^ "Drivers, Developments and Options Under Consideration for a Mars Ascent Vehicle," R. Shotwell, J. Benito, A. Karp, and J. Dankanich, 2016 IEEE Aerospace Conference, March 2016.
  77. ^ "A Mars Ascent Vehicle for Potential Mars Sample Return," R. Shotwell, J. Benito, A. Karp, and J. Dankanich, 2017 IEEE Aerospace Conference, March 2017.
  78. ^ "Break-the-Chain Technology for Potential Mars Sample Return," R. Gershman, Y. Bar-Cohen, M. Hendry, M. Stricker, D. Dobrynin, and A. Morrese, 2018 IEEE Aerospace Conference, March 2018.
  79. ^ Rincon, Paul (April 26, 2018). "Space agencies intent on mission to deliver Mars rocks to Earth". BBC.
  80. ^ "Video (02:22) – Bringing Mars Back To Earth". NASA. April 26, 2018. Archived from the original on December 22, 2021.   This article incorporates text from this source, which is in the public domain.
  81. ^ "Joint Statement of Intent between the National Aeronautics and Space Administration and the European Space Agency on Mars Sample Return," T. Zurbuchen and D. Parker, April 26, 2018. https://mepag.jpl.nasa.gov/announcements/2018-04-26%20NASA-ESA%20SOI%20(Signed).pdf, Mars Exploration Program Analysis Group, Retrieved January 28, 2023
  82. ^ 2nd International Mars Sample Return Conference, April 25–27, 2018. https://astrobiology.nasa.gov/events/2nd-international-mars-sample-return-conference/, Astrobiology at NASA, Retrieved January 28, 2023
  83. ^ "2018 International Mars Sample Return Conference Berlin." https://www.lpi.usra.edu/lpi/contribution_docs/LPI-002071.pdf, Lunar and Planetary Institute, Retrieved January 28, 2023
  84. ^ "Seeking Signs of Life on Mars: The Importance of Sedimentary Suites as Part of Mars Sample Return," iMOST Team (International MSR Objectives and Samples Team), MSR 2018 Berlin, https://www.lpi.usra.edu/lpi/contribution_docs/LPI-002071.pdf#page=103, Lunar and Planetary Institute, Retrieved 18 February 2023
  85. ^ "Mars Sample Return Architecture Overview," C. Edwards and S. Vijendran, MSR 2018 Berlin, https://www.lpi.usra.edu/lpi/contribution_docs/LPI-002071.pdf#page=74, Lunar and Planetary Institute, Retrieved February 12, 2023
  86. ^ "Commercial Capabilities to Accelerate Timeline and Decrease Cost for Return of Samples from Mars," P. Wooster, M. Marinova, and J. Brost, MSR 2018 Berlin, https://www.lpi.usra.edu/lpi/contribution_docs/LPI-002071.pdf#page=172, Lunar and Planetary Institute, Retrieved February 12, 2023
  87. ^ "Mars Ascent Vehicle Needs Technology Development with a Focus on High Propellant Fractions," J. Whitehead, MSR 2018 Berlin, https://www.lpi.usra.edu/lpi/contribution_docs/LPI-002071.pdf#page=168, Lunar and Planetary Institute, Retrieved February 12, 2023
  88. ^ Foust, Jeff (July 28, 2019). "Mars sample return mission plans begin to take shape". SpaceNews.
  89. ^ Cowart, Justin (August 13, 2019). "NASA, ESA Officials Outline Latest Mars Sample Return Plans". The Planetary Society.
  90. ^ "Mars Sample Return Lander Mission Concepts," B. Muirhead and A. Karp, 2019 IEEE Aerospace Conference, March 2019.
  91. ^ "Development Concepts for Mars Ascent Vehicle (MAV) Solid and Hybrid Vehicle Systems," L. McCollum et al., 2019 IEEE Aerospace Conference, March 2019.
  92. ^ "A Design for a Two-Stage Solid Mars Ascent Vehicle," A. Prince, T. Kibbey, and A. Karp, AIAA 2019–4149, AIAA Propulsion and Energy Forum, August 2019.
  93. ^ "Bold plan to retrieve Mars samples takes shape," D. Clery and P. Voosen, Science, 366: 932, November 22, 2019.
  94. ^ "Mars Sample Return Mission Concept Status," B. Muirhead, A. Nicholas, and J. Umland, 2020 IEEE Aerospace Conference, March 2020.
  95. ^ "Mars Ascent Vehicle Solid Propulsion Configuration," D. Yaghoubi and A. Schnell, 2020 IEEE Aerospace Conference, March 2020.
  96. ^ "Mars Ascent Vehicle Hybrid Propulsion Configuration," D. Yaghoubi and A. Schnell, 2020 IEEE Aerospace Conference, March 2020.
  97. ^ Clark, Stephen (April 20, 2020). "NASA narrows design for rocket to launch samples off of Mars". Spaceflight Now. Retrieved April 21, 2020.
  98. ^ "Integrated Design Results for the MSR DAC-0.0 Mars Ascent Vehicle," D. Yaghoubi and P. Ma, 2021 IEEE Aerospace Conference, March 2021.
  99. ^ "Mars Sample Return (MSR) Program: Final Report of the Independent Review Board (IRB)," https://www.nasa.gov/sites/default/files/atoms/files/nasa_esa_mars_sample_return_final_report_small.pdf#page=10, NASA reports website. Retrieved July 6, 2023
  100. ^ "Summary of NASA Responses to Mars Sample Return Independent Review Board Recommendations," https://www.nasa.gov/sites/default/files/atoms/files/nasa_esa_mars_sample_return_final_report_small.pdf#page=1, NASA reports website. Retrieved July 6, 2023
  101. ^ "Mars Sample Return (MSR) Program: Final Report of the Independent Review Board (IRB)," Notes below Chart 33, https://www.nasa.gov/sites/default/files/atoms/files/nasa_esa_mars_sample_return_final_report_small.pdf#page=42, NASA reports website. Retrieved July 6, 2023
  102. ^ "Mars Sample Return (MSR) Program: Final Report of the Independent Review Board (IRB)," Chart 42 and notes below it, https://www.nasa.gov/sites/default/files/atoms/files/nasa_esa_mars_sample_return_final_report_small.pdf#page=51, NASA reports website. Retrieved July 6, 2023
  103. ^ "Mars Sample Return (MSR) Program: Final Report of the Independent Review Board (IRB)," Chart 43 and notes below it, https://www.nasa.gov/sites/default/files/atoms/files/nasa_esa_mars_sample_return_final_report_small.pdf#page=52, NASA reports website. Retrieved July 6, 2023
  104. ^ "Mars Sample Return (MSR) Program: Final Report of the Independent Review Board (IRB)," Chart 57 and notes below it, https://www.nasa.gov/sites/default/files/atoms/files/nasa_esa_mars_sample_return_final_report_small.pdf#page=66, NASA reports website. Retrieved July 6, 2023
  105. ^ "NASA Planetary Science Advisory Committee website," https://science.nasa.gov/researchers/nac/science-advisory-committees/pac, Retrieved July 4, 2023
  106. ^ "NASA Advisory Council Science Committee April 14–15, 2021 Meeting Report," https://science.nasa.gov/science-red/s3fs-public/atoms/files/FINAL%20Science%20Cmte%20Meeting%20Minutes_Signed_April%202021.pdf#page=3, NASA Headquarters. Page 3. Retrieved July 4, 2023
  107. ^ "Integrated Design Results for the MSR SRC Mars Ascent Vehicle," D. Yaghoubi and S. Maynor, 2022 IEEE Aerospace Conference, March 2022.
  108. ^ "Planetary Science and Astrobiology Decadal Survey 2023-2032," https://www.nationalacademies.org/our-work/planetary-science-and-astrobiology-decadal-survey-2023-2032, National Academies of Sciences, Engineering, and Medicine. Retrieved February 26, 2023
  109. ^ "Origins, Worlds, and Life. A Decadal Strategy for Planetary Science and Astrobiology 2023–2032," https://nap.nationalacademies.org/catalog/26522/origins-worlds-and-life-a-decadal-strategy-for-planetary-science, https://doi.org/10.17226/26522, National Academies of Sciences, Engineering, and Medicine, Space Studies Board, National Academies Press, 2022; ISBN 978-0-309-47578-5. See pages 22-7 to 22-9. Retrieved February 26, 2023
  110. ^ "Why Mars Sample Return is a Mission Campaign of Compelling Importance to Planetary Science and Exploration," https://mepag.jpl.nasa.gov/reports/decadal2023-2032/MSR%20science%20white%20paper-final4.pdf, MEPAG website. Retrieved July 5, 2023
  111. ^ "Mars Sample Return Campaign Concept Architecture," https://mepag.jpl.nasa.gov/reports/decadal2023-2032/Decadal%20White%20Paper%20MuirheadBrianK.pdf, MEPAG website. Retrieved July 5, 2023
  112. ^ "The Challenge of Launching Geology Samples off of Mars is Easily Underestimated, Due to Tempting Misconceptions," https://mepag.jpl.nasa.gov/reports/decadal2023-2032/WhiteheadMisconceptionsMAV2020Oct11.pdf, MEPAG website. Retrieved July 4, 2023
  113. ^ "Mars Ascent Vehicle needs a Sustained Development Effort, Regardless of Sample Return Mission Timelines," https://mepag.jpl.nasa.gov/reports/decadal2023-2032/WhiteheadSustainMAV2020Oct11.pdf, MEPAG website. Retrieved July 4, 2023
  114. ^ "Technology Development Can Lead to Smaller Mars Ascent Vehicles, for Multiple Affordable Sample Returns," https://mepag.jpl.nasa.gov/reports/decadal2023-2032/WhiteheadSmallerMAV2020Oct11.pdf, MEPAG website. Retrieved July 4, 2023
  115. ^ "Decadal Survey on Planetary Science and Astrobiology: Steering Group Seventh Meeting Revised Final Agenda," https://www.nationalacademies.org/documents/embed/link/LF2255DA3DD1C41C0A42D3BEF0989ACAECE3053A6A9B/file/DE1EC51702FEF69877C024F38B3437AA2CD7C9F72218?noSaveAs=1, National Academies of Sciences, Engineering, and Medicine. Retrieved July 6, 2023
  116. ^ Foust, Jeff (July 27, 2022) "NASA and ESA remove rover from Mars Sample Return plans," https://spacenews.com/nasa-and-esa-remove-rover-from-mars-sample-return-plans/ Space News. Retrieved December 21, 2023
  117. ^ "Mars choppers displace fetch rover in sample-return plan," J. Foust, Space News, August 2022, p. 6-7.
  118. ^ "Martian aviator," an interview with Ben Pipenberg, P. Marks, Aerospace America, January 2023, p. 14-19.
  119. ^ “Mars Rocks Await a Ride to Earth -- Can NASA Deliver?,” A. Witze, Nature. 616, p. 230-231, April 13, 2023.
  120. ^ a b David, Leopnard (January 15, 2024). "NASA's troubled Mars sample-return mission has scientists seeing red - Projected multibillion-dollar overruns have some calling the agency's plan a 'dumpster fire.'". Space.com. Archived from the original on January 16, 2024. Retrieved January 16, 2024.
  121. ^ "Welcome to 'Octavia E. Butler Landing'". NASA. March 5, 2021. Retrieved March 5, 2021.
  122. ^ Voosen, Paul (July 31, 2021). "Mars rover's sampling campaign begins". Science. 373 (6554). AAAS: 477. Bibcode:2021Sci...373..477V. doi:10.1126/science.373.6554.477. PMID 34326215. S2CID 236514399. Retrieved August 1, 2021.
  123. ^ mars.nasa.gov. "On the Eve of Perseverance's First Sample". mars.nasa.gov. Retrieved August 12, 2021.
  124. ^ Voosem, Paul (June 21, 2021). "NASA's Perseverance rover to drill first samples of martian rock". Science. AAAS. Retrieved August 1, 2021.
  125. ^ mars.nasa.gov. "Assessing Perseverance's First Sample Attempt". mars.nasa.gov. Retrieved August 12, 2021.
  126. ^ mars.nasa.gov (September 2, 2021). "Nasa's perseverance rover successfully cores its first rock". mars.nasa.gov. Retrieved September 10, 2021.
  127. ^ mars.nasa.gov (September 6, 2021). "Nasa's perseverance rover collects first Mars rock sample". mars.nasa.gov. Retrieved September 10, 2021.
  128. ^ mars.nasa.gov. "Perseverance Rover Mars Rock Samples". NASA Mars Exploration. Retrieved December 25, 2023.
  129. ^ "Nobody Tell Elmo About Issole". nasa.gov. Retrieved February 11, 2022.
  130. ^ mars.nasa.gov. "NASA's Perseverance Plans Next Sample Attempt". NASA’s Mars Exploration Program. Retrieved August 27, 2021.
  131. ^ "Sample Caching Dry Run, 1st sample tube cached". Twitter. Retrieved August 27, 2021.
  132. ^ mars.nasa.gov. "Perseverance Sample Tube 266". NASA’s Mars Exploration Program. Retrieved September 9, 2021.
  133. ^ @NASAPersevere (July 8, 2021). "Lots of first-time activities before I start drilling. I recently ran one sample tube through inspection, sealing a..." (Tweet). Retrieved August 27, 2021 – via Twitter.
  134. ^ "Witness Tube in Perseverance Sample Caching System". NASA Jet Propulsion Laboratory (JPL). Retrieved September 9, 2021.
  135. ^ mars.nasa.gov. "Perseverance's Drive to Citadelle". NASA's Mars Exploration Program. Retrieved September 6, 2021.
  136. ^ mars.nasa.gov. "Kicking off the Sampling Sol Path at Citadelle". mars.nasa.gov. Retrieved September 6, 2021.
  137. ^ Fox, Karen; Johnson, Alana; Agle, AG (September 2, 2021). "NASA's Perseverance Rover Successfully Cores Its First Rock". NASA. Retrieved September 3, 2021.
  138. ^ Chang, Kenneth (September 3, 2021). "On Mars, NASA's Perseverance Rover Drilled the Rocks It Came For – After an earlier drilling attempt failed to collect anything, the rover appeared to gather its first sample. But mission managers need to take another look before sealing the tube". The New York Times. Retrieved September 3, 2021.
  139. ^ Chang, Kenneth (September 7, 2021). "NASA's Perseverance Rover Stashes First Mars Rock Sample – The rock, sealed in a tube, is the first of many the robotic explorer will collect to one day send back to Earth for scientists to study". The New York Times. Retrieved September 8, 2021.
  140. ^ mars.nasa.gov. "A Historic Moment – Perseverance Collects, Seals, and Stores its First Two Rock Samples". mars.nasa.gov. Retrieved December 18, 2021.
  141. ^ a b @NASAPersevere (November 24, 2021). "A rock so nice, I sampled it twice! Just capped and sealed my fifth sample tube, with another piece from this inter..." (Tweet). Retrieved December 18, 2021 – via Twitter.
  142. ^ mars.nasa.gov. "Assessing Perseverance's Seventh Sample Collection". mars.nasa.gov. Retrieved March 8, 2022.
  143. ^ mars.nasa.gov. "Pebbles Before Mountains". mars.nasa.gov. Retrieved March 8, 2022.
  144. ^ mars.nasa.gov. "Ejecting Mars' Pebbles". mars.nasa.gov. Retrieved March 8, 2022.
  145. ^ a b mars.nasa.gov. "NASA's Perseverance Rover Deposits First Sample on Mars Surface". NASA Mars Exploration. Retrieved December 22, 2022.  This article incorporates text from this source, which is in the public domain.
  146. ^ @PaulHammond51 (August 7, 2022). "@chiragp87233561 Be careful with names. The witness tube was not sampled at 'Skinner Ridge'. Skinner Ridge is the n..." (Tweet). Retrieved November 4, 2022 – via Twitter.
  147. ^ mars.nasa.gov. "Sealing Sample 14 – NASA". mars.nasa.gov. Retrieved November 24, 2022.
  148. ^ Stephanie Connell. "Perseverance Activities at Amalik Outcrop – NASA". mars.nasa.gov. Retrieved November 24, 2022.
  149. ^ mars.nasa.gov. "Perseverance Rover Mars Rock Samples". NASA Mars Exploration. Retrieved June 15, 2022.
  150. ^ "MARS 2020 INITIAL REPORTS Crater Floor Campaign" (PDF).
  151. ^ "MARS 2020 INITIAL REPORTS Volume 2 Delta Front Campaign February 15, 2023" (PDF).
  152. ^ "MARS 2020 INITIAL REPORTS Volume 1 Crater Floor Campaign August 11, 2022" (PDF).
  153. ^ "Mars 2020 Returned Sample Science Archive". pds-geosciences.wustl.edu. Retrieved October 6, 2022.
  154. ^ "I had a list I was working on, combined it with the NASA website chart". Twitter. Retrieved October 24, 2022.
  155. ^ @NASAPersevere (December 23, 2022). "Mars does get windy, but not like on Earth. The atmosphere here is much less dense: about 1/100th that of Earth's. Winds around here can pick up *speed,* but they don't pick up a lot of *stuff.* Think fast, but not strong" (Tweet). Retrieved February 7, 2023 – via Twitter.
  156. ^ Foust, Jeff (December 18, 2022). "Perseverance prepares to deposit Mars sample cache". SpaceNews. Retrieved December 22, 2022.
  157. ^ mars.nasa.gov. "NASA's Perseverance Rover to Begin Building Martian Sample Depot". NASA Mars Exploration. Retrieved December 22, 2022.
  158. ^ mars.nasa.gov. "Sample Retrieval Lander – NASA". mars.nasa.gov. Retrieved January 8, 2023.
  159. ^ a b mars.nasa.gov. "Mars Ascent Vehicle – NASA". mars.nasa.gov. Retrieved January 8, 2023.
  160. ^ Gebhardt, Chris (June 2, 2022). "How Lockheed Martin, NASA will send a rocket to Mars to launch samples off the planet to a waiting European Orbiter". NASASpaceFlight.com. Retrieved January 9, 2023.
  161. ^ Gebhardt, Chris (June 4, 2021). "Mars Ascent Vehicle from Northrop Grumman takes shape for Mars Sample Return mission". NASASpaceFlight.com. Retrieved January 9, 2023.
  162. ^ "NASA Selects Developer for Rocket to Retrieve First Samples from Mars". NASA Press Release 22-015, February 7, 2022. February 7, 2022. Retrieved July 2, 2022.
  163. ^ "NASA Begins Testing Robotics to Bring First Samples Back From Mars". NASA Jet Propulsion Laboratory (JPL). December 13, 2021. Retrieved August 2, 2022.
  164. ^ a b Yaghoubi, Darius; Maynor, Shawn. "Integrated Design Results for the MSR SRC Mars Ascent Vehicle" (PDF). NASA Technical Reports Server. Retrieved April 26, 2022.
  165. ^ "identify this object – What are these two little valve stem-like projections from the Northrop Grumman STAR 15G upper stage rocket motor? Why doesn't the STAR 20 have them?". Space Exploration Stack Exchange. Retrieved December 22, 2022.
  166. ^ "Airbus to bring first Mars samples to Earth: ESA contract award | Airbus". www.airbus.com. October 28, 2021. Retrieved December 14, 2021.
  167. ^ a b (PDF). September 29, 2015. Archived from the original (PDF) on September 29, 2015. Retrieved December 25, 2022.
  168. ^ a b c mars.nasa.gov. "Earth Return Orbiter - ESA - NASA". mars.nasa.gov. Retrieved August 1, 2023.
  169. ^ "Earth Return Orbiter – the first round-trip to Mars". ESA. April 7, 2023. Retrieved April 8, 2023.
  170. ^ Kellas, Sotiris (March 2017). "Passive earth entry vehicle landing test". 2017 IEEE Aerospace Conference. Big Sky, MT, USA: IEEE. pp. 1–10. doi:10.1109/AERO.2017.7943744. hdl:2060/20170002221. ISBN 978-1-5090-1613-6. S2CID 24286971.
  171. ^ . August 31, 2017. Archived from the original on August 31, 2017. Retrieved December 25, 2022.
  172. ^ Gebhardt, Chris; Barker, Nathan (June 4, 2021). "Mars Ascent Vehicle from Northrop Grumman takes shape for Mars Sample Return mission". NASASpaceFlight.com. Retrieved August 27, 2021.
  173. ^ Kahn, Amina (February 10, 2020). "NASA gives JPL green light for mission to bring a piece of Mars back to Earth". Los Angeles Times. Retrieved February 11, 2020.
  174. ^ "Mission to Mars – Mars Sample Return". NASA. 2020. Retrieved February 11, 2020.   This article incorporates text from this source, which is in the public domain.

External links edit

  • Mars Sample return media reel produced by NASA and JPL (video)

January 01, 1970
nasa, mars, sample, return, this, article, require, copy, editing, grammar, style, cohesion, tone, spelling, assist, editing, december, 2023, learn, when, remove, this, message, proposed, flagship, class, mars, sample, return, mission, collect, martian, rock, . This article may require copy editing for grammar style cohesion tone or spelling You can assist by editing it December 2023 Learn how and when to remove this message The NASA ESA Mars Sample Return is a proposed Flagship class Mars sample return MSR mission 3 to collect Martian rock and soil samples in 43 small cylindrical pencil sized titanium tubes and return them to Earth around 2033 4 NASA ESA MSR Patch Mars Sample Return Program 1 Artwork July 27 2022 source source source source source source source source track Mars Sample Return 2 Video November 17 2022 The NASA ESA plan approved in September 2022 is to return samples using three missions a sample collection mission Perseverance a sample retrieval mission Sample Retrieval Lander Mars Ascent Vehicle Sample Transfer Arm 2 Ingenuity class helicopters and a return mission Earth Return Orbiter 5 6 7 The mission hopes to resolve the question of whether Mars once harbored life Although the proposal is still in the design stage the Perseverance rover is currently gathering samples on Mars and the components of the sample retrieval lander are in testing phase on earth 8 9 After a project review critical of its cost and complexity 10 11 NASA announced that the project was paused as of 13 November 2023 12 On 22 November 2023 NASA was reported to have cut back on the Mars sample return mission due to a possible shortage of funds 13 In April 2024 in a NASA update via teleconference the NASA Administrator emphasized continuing the commitment to retrieving the samples However under the then current mission profile the cost of 11 billion was infeasible therefore NASA would turn to industry and the Jet Propulsion Laboratory to form a new more fiscally feasible mission profile to retrieve the samples with responses expected by fall 2024 14 15 16 Contents 1 History 1 1 2001 to 2004 1 2 2005 to 2008 1 3 2009 to 2011 1 4 2012 to 2013 1 5 2014 to 2017 1 6 2018 to 2022 1 7 2023 to 2024 2 Sample collection 2 1 Mars 2020 Perseverance rover 3 List of samples cached 4 Three Forks Sample Depot 5 Sample retrieval 5 1 Sample Retrieval Lander 5 2 Mars Sample Recovery Helicopters 5 3 Mars Ascent Vehicle MAV 6 Sample return 6 1 Earth Return Orbiter ERO 6 2 Earth Entry Vehicle EEV 7 Gallery 8 See also 9 Notes 10 References 11 External linksHistory editSee also Mars sample return mission History 2001 to 2004 edit In the summer of 2001 the Jet Propulsion Laboratory JPL requested mission concepts and proposals from industry led teams Boeing Lockheed Martin and TRW 17 The science requirements included at least 500 grams 18 oz of samples rover mobility to obtain samples at least 1 kilometre 0 62 mi from the landing spot and drilling to obtain one sample from a depth of 2 metres 6 ft 7 in That following winter JPL made similar requests of certain university aerospace engineering departments MIT and the University of Michigan Also in 2001 a separate set of industry studies was done for the Mars ascent vehicle MAV due to the uniqueness and key role of the MAV for MSR 18 Figure 11 in this reference summarized the need for MAV flight testing at a high altitude over Earth based on Lockheed Martin s analysis that the risk of mission failure is extremely high if launch vehicle components are only tested separately In 2003 JPL reported that the mission concepts from 2001 had been deemed too costly which led to the study of a more affordable plan accepted by two groups of scientists a new MSR Science Steering Group and the Mars Exploration Program Analysis Group MEPAG 19 Instead of a rover and deep drilling a scoop on the lander would dig 20 centimetres 7 9 in deep and place multiple samples together into one container After five years of technology development the MAV would be flight tested twice above Earth before the mission PDR Preliminary Design Review in 2009 Based on the simplified mission plan assuming a launch from Earth in 2013 and two weeks on Mars for a 2016 return technology development was initiated for ensuring with high reliability that potential Mars microbes would not contaminate Earth and also that the Mars samples would not be contaminated with Earth origin biological materials 20 The sample container would be clean on the outside before departing from Mars with installation onto the MAV inside an Earth clean MAV garage In 2004 JPL published an update on the 2003 plan 21 MSR would use the new large sky crane landing system in development for the Mars Science Laboratory rover later named Curiosity A MSR Technology Board was formed and it was noted that the use of a rover might return to the MSR plan in light of success with the Spirit and Opportunity rovers that arrived early in 2004 A 285 kilogram 628 lb ascent rocket would carry 0 5 kilogram 1 1 lb of samples inside a 5 kilogram 11 lb payload the Orbiting Sample OS The MAV would transmit enough telemetry to reconstruct events in case of failure on the way up to Mars orbit 2005 to 2008 edit As of 2005 a rover had returned to the MSR plan with a rock core drill in light of results from the Mars Exploration Rover discoveries 22 Focused technology development would start before the end of 2005 for mission PDR in 2009 followed by launch from Earth in 2013 Related technologies in development included potential advances for Mars arrival navigation and descent propulsion and implementing pump fed liquid launch vehicle technology on a scale small enough for a MAV 23 In late 2005 a peer reviewed analysis showed that ascent trajectories to Mars orbit would differ depending on liquid versus solid propulsion largely because small solid rocket motors burn faster requiring a steeper ascent path to avoid excess atmospheric drag while slower burning liquid propulsion might take advantage of more efficient paths to orbit 24 Early in 2006 the Marshall Space Flight Center noted the possibility that a science rover would cache the samples on Mars then subsequently a mini rover would be sent along with the MAV on a sample return lander in which case either the mini rover or the science rover would deliver the samples to the lander for loading onto the MAV 25 A two stage 250 kilogram 550 lb solid propellant MAV would be gas ejected from a launch tube with its 5 kilogram 11 lb payload a 16 centimetre 6 3 in diameter spherical package containing the samples The second stage would send telemetry and its steering thrusters would use hydrazine fuel with additives The authors expected the MAV to need multiple flight tests at a high altitude over Earth A peer reviewed publication in 2007 described testing of autonomous sample capture for Mars orbit rendezvous 26 Free floating tests were done on board a NASA aircraft using a parabolic zero g flight path In 2007 Alan Stern then NASA s Associate Administrator for Science was strongly in favor of completing MSR sooner and he asked JPL to include sample caching on the Mars Science Laboratory mission later named Curiosity 27 A team at the Ames Research Center was designing a hockey puck sized sample caching device to be installed as an extra payload on MSL 28 A review analysis in 2008 compared Mars ascent to lunar ascent noting that the MAV would be not only technically daunting but also a cultural challenge for the planetary community given that lunar ascent has been done using known technology and that science missions typically rely on proven propulsion for course corrections and orbit insertion maneuvers similar to what Earth satellites do routinely 29 2009 to 2011 edit Early in 2009 the In Space Propulsion Technology project office at the NASA Glenn Research Center GRC presented a ranking of six MAV options concluding that a 285 kilogram 628 lb two stage solid rocket with continuous telemetry would be best for delivering a 5 kilogram 11 lb sample package to Mars orbit 30 A single stage pump fed bipropellant MAV 31 was noted to be less heavy and was ranked second Later in 2009 the chief technologist of the Mars Exploration Directorate at JPL referred to a 2008 workshop on MSR technologies at the Lunar and Planetary Institute and wrote that particularly difficult technology challenges included the MAV sample acquisition and handling and back planetary protection then further commented that The MAV in particular stands out as the system with highest development risk pointing to the need for an early start leading to flight testing before preliminary design review PDR of the lander that would deliver the MAV 32 In October 2009 NASA and ESA established the Mars Exploration Joint Initiative to proceed with the ExoMars program whose ultimate aim is the return of samples from Mars in the 2020s 33 34 ExoMars s first mission was planned to launch in 2018 35 36 with unspecified missions to return samples in the 2020 2022 time frame 37 As reported to the NASA Advisory Council Science Committee NAC SC 38 early in 2010 MEPAG estimated that MSR will cost 8 10B and it is obvious that NASA and ESA can t fund this amount by themselves 39 The cancellation of the caching rover MAX C in 2011 and later NASA withdrawal from ExoMars due to budget limitations ended the mission 40 The pull out was described as traumatic for the science community 40 In 2010 2011 the NASA In Space Propulsion Technology ISPT program at the Glenn Research Center received proposals and funded industry partners for MAV design studies with contract options to begin technology development while also considering propulsion needs for Earth return spacecraft 41 Inserting the spacecraft into Mars orbit then returning to Earth was noted to need a high total of velocity changes leading to a conclusion that solar electric propulsion could reduce mission risk by improving mass margins compared to the previously assumed use of chemical propulsion along with aerobraking at Mars 42 The ISPT team also studied scenarios for MAV flight testing over Earth and recommended two flight tests prior to MSR mission PDR considering the historical low probability of initial success for new launch vehicles 43 The NASA ESA potential mission schedule anticipated launches from Earth in 2018 2022 and 2024 to send respectively a sample caching rover a sample return orbiter and a sample retrieval lander for a 2027 Earth arrival with MAV development starting in 2014 after two years of technology development identified by the MAV design studies 44 The ISPT program summarized a year of propulsion technology progress for improving Mars arrival Mars ascent and Earth return stating that the first flight test of a MAV engineering model would need to occur in 2018 to meet the 2024 launch date for the sample retrieval lander 45 The 2011 MAV industry studies were done by Lockheed Martin teamed with ATK Northrop Grumman and Firestar Technologies to deliver a 5 kg 11 lb 16 cm 6 3 inch diameter sample sphere to Mars orbit 46 The Lockheed Martin ATK team focused on a solid propellant first stage with either solid or liquid propellant for the upper stage estimated MAV mass in the range 250 to 300 kg 550 to 660 lb and identified technologies for development to reduce mass 47 Northrop Grumman the former TRW similarly estimated a mass below 300 kg using pressure fed liquid bipropellants for both stages 48 and had plans for further progress 49 Firestar Technologies described a single stage MAV design having liquid fuel and oxidizer blended together in one main propellant tank 50 In early 2011 the US National Research Council s Planetary Science Decadal Survey which laid out mission planning priorities for the period 2013 2022 declared an MSR campaign its highest priority Flagship Mission for that period 51 52 In particular it endorsed the proposed Mars Astrobiology Explorer Cacher MAX C mission in a descoped less ambitious form This mission plan was officially cancelled in April 2011 The plan cancelled in 2011 for budget reasons had been for NASA and ESA to each build a rover to send together in 2018 53 2012 to 2013 edit In 2012 prospects for MSR were slowed further by a 38 percent cut in NASA s Mars program budget for fiscal year 2013 leading to controversy among scientists over whether Mars exploration could thrive on a series of small rover missions 54 A Mars Program Planning Group MPPG was convened as one response to budget cuts 55 In mid 2012 eight weeks before Curiosity arrived on Mars the Lunar and Planetary Institute hosted a NASA sponsored three day workshop 56 to gather expertise and ideas from a wide range of professionals and students as input to help NASA reformulate the Mars Exploration Program responsive to the latest Planetary Decadal Survey 51 that prioritized MSR A summary report noted that the workshop was held in response to recent deep budget cuts 390 submissions were received 185 people attended and agreed that credible steps toward MSR could be done with reduced funding 57 The MAX C rover ultimately implemented as Mars 2020 Perseverance was considered beyond financial reach at that time so the report noted that progress toward MSR could include an orbiter mission to test autonomous rendezvous or a Phoenix class lander to demonstrate pinpoint landing while delivering a MAV as a technology demonstration The workshop consisted largely of three breakout group discussions for Technology and Enabling Capabilities Science and Mission Concepts and Human Exploration and Precursors Wide ranging discussions were documented by the Technology Panel 58 which suggested investments for improved drilling and small is beautiful rovers with an emphasis on creative mass lowering capabilities The panel stated that MAV functional technology is not new but the Mars environment would pose challenges and referred to MAV technologies as a risk for most sample return scenarios of any cost range MAV technology was addressed in numerous written submissions 59 60 61 62 63 to the workshop one of which described Mars ascent as beyond proven technology velocity and acceleration in combination for small rockets and a huge challenge for the social system referring to a Catch 22 dilemma in which there is no tolerance for new technology if sample return is on the near term horizon and no MAV funding if sample return is on the far horizon 61 In September 2012 NASA announced its intention to further study MSR strategies as outlined by the MPPG including a multiple launch scenario a single launch scenario and a multiple rover scenario for a mission beginning as early as 2018 64 65 66 67 A fetch rover would retrieve the sample caches and deliver them to a Mars ascent vehicle MAV In July 2018 NASA contracted Airbus to produce a fetch rover concept 68 As of late 2012 It was determined that the MAX C rover concept to collect samples could be implemented for a launch in 2020 Mars 2020 within available funding using spare parts and mission plans developed for NASA s Curiosity Mars rover 69 In 2013 the NASA Ames Research Center proposed that a SpaceX Falcon Heavy could deliver two tons of useful payload to the Mars surface including an Earth return spacecraft that would be launched from Mars by a one ton single stage MAV using liquid bipropellants fed by turbopumps 70 71 72 The successful landing of the Curiosity rover directly on its wheels August 2012 motivated JPL to take a fresh look at carrying the MAV on the back of a rover 73 A fully guided 300 kg MAV like Lockheed s 2011 two stage solid 46 47 would avoid the need for a round trip fetch rover A smaller 150 kg MAV would permit one rover to also include sample collection while using MSL heritage to reduce mission cost and development time placing most development risk on the MAV The 150 kg MAV would be made lightweight by spinning it up before stage separation although the lack of telemetry data from the spin stabilized unguided upper stage was noted as a disadvantage JPL later presented more details of the 150 kg solid propellant mini MAV concept of 2012 in a summary of selected past efforts 74 The absence of telemetry data during the 1999 loss of the Mars Polar Lander had put an emphasis on critical event communications subsequently applied to MSR Then after the MSL landing in 2012 requirements had been revisited with a goal to reduce MAV mass Single fault tolerance and continuous telemetry data to Mars orbit were questioned For the 500 grams 1 1 lb of samples a 3 6 kg 7 9 lb payload was deemed possible instead of 5 kg 11 lb The 2012 mini MAV concept had single string avionics in addition to the spin stabilized upper stage without telemetry 2014 to 2017 edit In 2014 2015 JPL analyzed many options for Mars ascent including solid hybrid and liquid propellants for payloads ranging from 6 5 kg to 25 kg 75 Four MAV concepts using solid propellant had two stages while one or two stages were considered for hybrid and liquid propellants Seven options were scored for ten attributes figures of merit A single stage hybrid received the highest overall score including the most points for reducing cost and separately for reducing complexity with the fewest points for technology readiness Second overall was a single stage liquid bipropellant MAV using electric pumps A pressure fed bipropellant design was third with the most points for technology readiness Solid propellant options had lower scores partly due to receiving very few points for flexibility JPL and NASA Langley Research Center cautioned that the high thrust and short burn times of solid rocket motors would result in early burnout at a low altitude with substantial atmosphere remaining to coast through at high Mach numbers raising stability and control concerns 74 76 With concurrence from the Mars Program Director a decision was made in January 2016 to focus limited technology development funds on advancing a hybrid propellant MAV liquid oxidizer with solid fuel 77 Starting in 2015 a new effort for planetary protection moved the backward planetary protection function from the surface of Mars to the sample Return Orbiter to break the chain in flight 78 Concepts for brazing bagging and plasma sterilization were studied and tested with a primary focus on brazing as of 2016 2018 to 2022 edit In April 2018 a letter of intent was signed by NASA and ESA that may provide a basis for a Mars sample return mission 79 80 The agreement 81 was dated during the 2nd International Mars Sample Return Conference in Berlin Germany 82 The conference program was archived along with 125 technical submissions that covered sample science anticipated findings site selection collection curation analysis and mission implementation Mars arrival rovers rock drills sample transfer robotics Mars ascent autonomous orbit rendezvous interplanetary propulsion Earth arrival planetary protection 83 In one of many presentations an international science team noted that collecting sedimentary rock samples would be required to search for ancient life 84 A joint NASA ESA presentation described the baseline mission architecture including sample collection by the Mars 2020 Rover derived from the MAX C concept a Sample Retrieval Lander and an Earth Return Orbiter 85 An alternative proposal was to use a SpaceX Falcon Heavy to decrease mission cost while delivering more mass to Mars and returning more samples 86 Another submission to the Berlin conference noted that mission cost could be reduced by advancing MAV technology to enable a significantly smaller MAV for a given sample payload 87 In July 2019 a mission architecture was proposed 88 89 In 2019 JPL authors summarized sample retrieval including a sample fetch rover options for fitting 20 or 30 sample tubes into a 12 kilogram 26 lb payload on a 400 kilogram 880 lb single stage to orbit SSTO MAV that would use hybrid propellants a liquid oxidizer with a solid wax fuel which had been prioritized for propulsion technology development since 2016 90 Meanwhile the Marshall Space Flight Center MSFC presented a comparison of solid and hybrid propulsion for the MAV 91 Later in 2019 MSFC and JPL had collaborated on designing a two stage solid propellant MAV and noted that an unguided spinning upper stage could reduce mass but this approach was abandoned at the time due to the potential for orbital variations 92 Early in 2020 JPL updated the overall mission plan for an orbiting sample package the size of a basketball 93 containing 30 tubes showing solid and hybrid MAV options in the range 400 to 500 kilograms 880 to 1 100 lb 94 Adding details MSFC presented designs for both the solid and hybrid MAV designs for a target mass of 400 kilograms 880 lb at Mars liftoff to deliver 20 or 30 sample tubes in a 14 to 16 kilogram 31 to 35 lb payload package 95 96 In April 2020 an updated version of the mission was presented 97 The decision to adopt a two stage solid rocket MAV was followed by Design Analysis Cycle 0 0 in the spring of 2020 which refined the MAV to a 525 kilogram 1 157 lb design having guidance for both stages leading to reconsideration of an unguided spin stabilized second stage to save mass 98 In October 2020 the MSR Independent Review Board IRB released its report 99 recommending overall that the MSR program proceed then in November NASA responded to detailed IRB recommendations 100 The IRB noted that MSR would have eight first time challenges including the first launch from another planet autonomous orbital rendezvous and robotic sample handling with sealing to break the chain 101 The IRB cautioned that the MAV will be unlike any previous launch vehicle and experience shows that the smaller a launch vehicle the more likely it is to end up heavier than designed 102 Referring to the unguided upper stage of the MAV the IRB stated the importance of telemetry for critical events to allow useful reconstruction of a fault during second stage flight 103 The IRB indicated that the most probable mission cost would be 3 8 4 4B 104 As reported to the NAC SC 38 in April 2021 the Planetary Science Advisory Committee PAC 105 was very concerned about the high cost of MSR and wanted to be sure that astrobiology considerations would be included in plans for returned sample laboratories 106 Early in 2022 MSFC presented the guided unguided MAV design for a 125 kilogram 276 lb mass reduction and documented remaining challenges including aerodynamic complexities during the first stage burn and coast to altitude a desire to locate hydrazine steering thrusters farther from the center of mass and stage separation without tip off rotation 107 While stage separation and subsequent spin up would be flight tested the authors noted that it would be ideal to flight test an entire flight like MAV but there would be a large cost In April 2022 the United States National Academies released the Planetary Science Decadal Survey report for 2023 2032 a review of plans and priorities for the upcoming ten years after many committee meetings starting in 2020 with consideration of over 500 independently submitted white papers more than 100 regarding Mars including comments on science and technology for sample return 108 The published document noted NASA s 2017 plan for a focused and rapid sample return campaign with essential participation from ESA then recommended The highest scientific priority of NASA s robotic exploration efforts this decade should be completion of Mars Sample Return as soon as is practicably possible 109 Decadal white papers emphasized the importance of MSR for science 110 included a description of implementing MSR 111 and noted that the MAV has been underestimated despite needing flight performance beyond the state of the art for small rockets 112 needs a sustained development effort 113 and that technology development for a smaller MAV has the potential to reduce MSR mission cost 114 Decadal Survey committee meetings hosted numerous invited speakers notably a presentation from the MSR IRB 115 As of March 2022 separate landers were planned for the fetch rover and the MAV because together they would be too large and heavy for a single lander then a cost saving plan as of July was to send only one lander with the MAV and rely on the Perseverance rover to pass sample tubes to the MAV in the absence of a fetch rover 5 116 Two new lightweight helicopters on the MAV lander would serve as a backup for moving the samples on Mars 117 2023 to 2024 edit At the start of 2023 it was revealed that a Mars Sample Fetch Helicopter had been envisioned since at least 2021 by the team at AeroVironment that created Ingenuity to fly in the thin atmosphere of Mars 118 In a public budget meeting in March NASA noted the high cost of MSR and had begun to assemble a second independent review board to assess the design schedule and required funding 119 In September 2023 NASA convened a second independent review board for the Mars Sample Return mission 14 120 In January 2024 a related proposed NASA plan had been challenged due to budget and scheduling considerations and a newer overhaul plan undertaken 120 On April 15 2024 NASA Administrator Bill Nelson and Science Mission Director Nicola Fox announced the organization s response to the September 2023 independent review board s investigation notably the finding that Mars Sample Return at its current design and cost originally estimated at 7 billion with Earth re entry by 2033 would now cost more than an unacceptable 11 billion and end in Earth re entry no sooner than 2040 16 In response Nelson and Fox stated that NASA would make requests to industry the next day to come up with alternatives that would likely utilize more proven mission architectures with longer heritages and comply with the board s recommendations with responses preferred by fall 2024 They also said they would spend 310 million on the program for fiscal year 2024 14 Sample collection editThe Mars 2020 mission landed the Perseverance rover which is storing samples to be returned to Earth later Mars 2020 Perseverance rover edit nbsp Perseverance rover cored rock sample collection at 1000 sols December 12 2023 nbsp Mapping Perseverance s samples collected to date The 10 duplicate samples to be left behind at Three Forks Sample Depot are framed in green colour nbsp Facsimiles of Perseverance s sample tubes at JPL in Southern California The Mars 2020 mission landed the Perseverance rover in Jezero crater in February 2021 It collected multiple samples and packed them into cylinders for later return Jezero appears to be an ancient lakebed suitable for ground sampling 121 122 123 At the beginning of August 2021 Perseverance made its first attempt to collect a ground sample by drilling out a finger size core of Martian rock 124 This attempt did not succeed A drill hole was produced as indicated by instrument readings and documented by a photograph of the drill hole However the sample container turned out to be empty indicating that the rock sampled was not robust enough to produce a solid core 125 nbsp Perseverance s sampling bitsFar left One pointed regolith drillMiddle Six rock drillsRight Two shorter abrasion tools A second target rock judged to have a better chance to yield a sufficiently robust sample was sampled at the end of August and the beginning of September 2021 After abrading the rock cleaning away dust by puffs of pressurized nitrogen and inspecting the resulting rock surface a hole was drilled on September 1 A rock sample appeared to be in the tube but it was not immediately placed in a container A new procedure of inspecting the tube optically was performed 126 On September 6 the process was completed and the first sample placed in a container 127 In support of the NASA ESA Mars Sample Return rock regolith Martian soil and atmosphere samples are being cached by Perseverance As of October 2023 27 out of 43 sample tubes have been filled 128 including 8 igneous rock samples 12 sedimentary rock sample tubes a Silica cemented carbonate rock sample tube 129 two regolith sample tubes an atmosphere sample tube 130 and three witness tubes 131 Before launch 5 of the 43 tubes were designated witness tubes and filled with materials that would capture particulates in the ambient environment of Mars Out of 43 tubes 3 witness sample tubes will not be returned to Earth and will remain on rover as the sample canister will only have 30 tube slots Further 10 of the 43 tubes are left as backups at the Three Forks Sample Depot 132 From December 21 2022 Perseverance started a campaign to deposit 10 of its collected samples at the backup depot Three Forks This work was completed on January 28 2023 List of samples cached editSample Tube Status Left at Three Forks Sample Depot Remain stowed in the Rover Sample Details Sampling Attempt Date Tube No Seal No Ferrule Prefix note 1 Ferrule No Contents Sample Name and Image during Caching note 2 Sample Depot Deposit Date Spot and Image Rock Name Core Length note 3 Estimated Martian Atmosphere Headspace Gas note 4 Location Notes 1 June 22 2021 Sol 121 SN061 SN147 10464848 7 SN090 133 Witness Tube Empty nbsp WB 1 N A N A 2 2 x 10 6 mol North Seitah Unit 134 This was taken as a dry run in preparation for later sampling attempts and did not aim to sample a rock During final pre launch activities this witness tube was activated the inner seal was punctured to begin accumulation and placed in the Bit Carousel This tube will therefore have accumulated contaminants for the entire duration of exposure from a few months before launch through cruise and EDL until it was sealed on the surface of Mars Given its long exposure it is likely that the inner surfaces of WB1 will be saturated with organic contaminants i e they will be in adsorption equilibrium with their immediate surroundings in the rover and or the entire spacecraft prior to landing WB1 is therefore expected to have higher concentrations of contaminants and potentially different contaminants than the sample tubes 2 August 6 2021 Sol 164 SN233 SN025 10464848 7 SN062 Atmospheric Gas nbsp Roubion failed attempt of caching rock sample nbsp January 4 2023 Sol 667 at Three Forks Sample Spot 4 Roubion18 25 40 N 77 27 06 E 18 42767 N 77 45167 E 18 42767 77 45167 N A 4 9x10 6 mol Polygon Valley Cratered Floor Fractured Rough Unit 135 Attempted to sample a rock consisting of Basaltic lava flow or sandstone or Microgabbro but did not succeed as they didn t reach the bit carousel and the caching system stored and sealed an empty tube However in this process it collected atmospheric samples 3 September 6 2021 Sol 195 SN266 SN170 10464848 6 SN099 136 Basalt or possibly basaltic sandstone Rock Sample nbsp Montdenier nbsp January 10 2023 Sol 672 at Three Forks Sample Spot 6 Rochette 18 25 51 N 77 26 40 E 18 43074 N 77 44433 E 18 43074 77 44433 5 98 cm 2 35 in 1 2x10 6 mol Arturby Ridge Citadelle South Seitah Unit Successful sample 137 138 139 4 September 8 2021 Sol 196 SN267 SN170 10464848 6 SN074 wbr 140 Basalt or possibly basaltic sandstone Rock Sample nbsp Montagnac Rochette 18 25 51 N 77 26 40 E 18 43074 N 77 44433 E 18 43074 77 44433 6 14 cm 2 42 in 1 3x10 6 mol Arturby Ridge Citadelle South Seitah Unit Sampled from same rock as previous sample 5 November 15 2021 Sol 263 SN246 SN194 10464848 5 SN107 141 Olivine cumulate Rock Sample nbsp Salette Brac18 26 02 N 77 26 35 E 18 43398 N 77 44305 E 18 43398 77 44305 6 28 cm 2 47 in 1 1 x10 6 mol Brac Outcrop South Seitah Unit 6 November 24 2021 Sol 271 SN284 SN219 10464848 6 SN189 141 Olivine cumulate Rock Sample nbsp Coulettes nbsp January 6 2023 Sol 668 at Three Forks Sample Spot 5 Brac18 26 02 N 77 26 35 E 18 43398 N 77 44305 E 18 43398 77 44305 3 30 cm 1 30 in 2 5 x10 6 mol Brac Outcrop South Seitah Unit 7 December 22 2021 Sol 299 SN206 SN184 10464848 7 SN064 Olivine cumulate Rock Sample nbsp Robine Issole18 25 58 N 77 26 29 E 18 43264 N 77 44134 E 18 43264 77 44134 6 08 cm 2 39 in 1 0 x10 6 mol Issole South Seitah Unit 8 December 29 2021 Sol 306 SN261 SN053 10464848 6 SN062 Olivine cumulate Rock Sample nbsp Pauls Abandoned sample from this site due to Core Bit Dropoff nbsp December 21 2022 Sol 653 at Three Forks Sample Spot 1 Issole18 25 58 N 77 26 29 E 18 43264 N 77 44134 E 18 43264 77 44134 N A N A Issole South Seitah Unit Pebble sized debris from the first sample fell into the bit carousel during transfer of the coring bit which blocked the successful caching of the sample 142 It was decided to abandon this sample and do a second sampling attempt again Subsequent tests and measures cleared remaining samples in tube and debris in caching system 143 144 The tube was reused for second sample attempt which was successful It was the first sample tube to be deposited at a Sample Depot in this case the depot is Three Forks 145 9 January 31 2022 Sol 338 nbsp Malay During Caching 3 07 cm 1 21 in 2 7 x10 6 mol 10 March 7 2022 Sol 372 SN262 SN172 10464848 6 SN129 Basaltic andesite Rock Sample nbsp Ha ahoni aka Hahonih Sid18 27 09 N 77 26 38 E 18 45242 N 77 44386 E 18 45242 77 44386 6 50 cm 2 56 in 0 98 x10 6mol Ch al outcrop 100 m 330 ft east of Octavia E Butler Landing Seitah Unit 11 March 13 2022 Sol 377 SN202 SN168 10464848 4 SN074 Basaltic andesite Rock Sample nbsp Atsa aka Atsah nbsp January 20 2023 Sol 682 at Three Forks Sample Spot 9 Sid18 27 09 N 77 26 38 E 18 45242 N 77 44386 E 18 45242 77 44386 6 00 cm 2 36 in 1 3 x10 6 mol Ch al outcrop 100 m 330 ft east of Octavia E Butler Landing Seitah Unit 12 July 7 2022 Sol 490 SN186 SN188 10464848 4 SN101 Clastic Sedimentary Rock Sample nbsp Swift Run Skinner Ridge18 24 22 N 77 27 32 E 18 40617 N 77 45893 E 18 40617 77 45893 6 69 cm 2 63 in 1 23 x 10 6 mol Skinner Ridge Delta Front First Deltaic and First sedimentary sample cached by Perseverance 13 July 12 2022 Sol 495 SN272 SN192 10464848 6 SN068 Clastic Sedimentary Rock Sample nbsp Skyland nbsp January 18 2023 Sol 680 at Three Forks Sample Spot 8 Skinner Ridge18 24 22 N 77 27 32 E 18 40617 N 77 45893 E 18 40617 77 45893 5 85 cm 2 30 in 1 7 x 10 6 mol Skinner Ridge Delta Front 14 July 16 2022 Sol 499 SN205 SN119 10464848 6 SN170 Witness Tube Empty nbsp WB2 N A N A 2 7 x 10 6 mol Hogwallow Flats 146 Delta Front This may have been done to clean out any leftover debris during the previous sampling attempts On sol 495 a string like piece of foreign object debris FOD similar to materials released during EDL was observed in the workspace images On sol 499 this object was no longer observed presumably because it blew out of the scene This observation suggests the possibility of FOD in tubes sealed in this general area 15 July 27 2022 Sol 510 SN172 SN157 10464848 7 SN099 Fine grained well sorted sedimentary rock sample sulphate bearing coarse mudstone nbsp Hazeltop Wildcat Ridge18 24 21 N 77 27 31 E 18 40589 N 77 45863 E 18 40589 77 45863 5 97 cm 2 35 in 1 63 x 10 6 mol Wildcat Ridge Delta Front 16 August 3 2022 Sol 517 SN259 SN177 10464848 5 SN110 Fine grained well sorted sedimentary rock sample sulphate bearing coarse mudstone nbsp Bearwallow nbsp January 13 2023 Sol 675 at Three Forks Sample Spot 7 Wildcat Ridge18 24 21 N 77 27 31 E 18 40589 N 77 45863 E 18 40589 77 45863 6 24 cm 2 46 in 1 43 x 10 6 mol Wildcat Ridge Delta Front 17 October 2 2022 Sol 575 SN264 SN068 10464848 5 SN085 Fine grained well sorted sedimentary rock olivine bearing coarse mudstone nbsp Shuyak Amalik outcrop77 24 05 N 18 27 03 E 77 40144 N 18 45073 E 77 40144 18 45073 5 55 cm 2 19 in 1 73 x 10 6 mol Amalik outcrop Delta Front 18 October 6 2022 Sol 579 November 16 2022 Sol 589 SN184 SN587 10464848 4 SN030 Fine grained well sorted sedimentary rock olivine bearing coarse mudstone nbsp Mageik nbsp December 23 2022 Sol 655 at Three Forks Sample Spot 2 Amalik outcrop77 24 05 N 18 27 03 E 77 40144 N 18 45073 E 77 40144 18 45073 7 36 cm 2 90 in 0 63 x 10 6 mol Amalik outcrop Delta Front The anomaly first appeared on Oct 5 after the successful coring of the mission s 14th sample called Mageik when the seal assigned to cap the rock core filled sample tube did not release as expected from its dispenser The process of sealing a sample happens in the rover s Sampling and Caching System During sealing a small robotic arm moves the rock core filled tube to one of seven dispensers and presses its open end against a waiting seal On the 17 previous occasions when a sample tube had been sealed during the mission the seal was pressed fully into the tube That allowed the seal to be extracted from the dispenser and the arm to move the seal tube combination to a different station where they are pressed together creating a hermetic seal However when the sample handling system attempted to dispense a seal in the tube of the Mageik sample the seal encountered too much resistance and did not come free The sampling system automatically detected the lack of seal and stored the unsealed tube safely so the tube and sample hardware remain in a stable configuration One of the possible causes of the seal s nondeployment may be that Martian dust adhered to a location on the tube s interior surface where the dust could impede successful coupling and extraction To ensure a hermetic seal the tolerances between tube and seal are by necessity extremely small 0 00008 inches 0 002 mm The rover s CacheCam captured images showing light deposits of dust on the tube s lip but the camera s imaging capabilities along the tube s inner surface are quite limited Sealing which was tried again and again was finally completed on November 16 2022 Sol 589 successfully 147 19 October 14 2022 Sol 586 SN188 SN153 10464848 5 SN073 Witness Tube Empty nbsp WB3 nbsp January 28 2023 Sol 690 at Three Forks Sample Spot 10 N A N A 2 31 x 10 6 mol The witness tubes do not collect samples but are opened near the sampling location to witness the Martian environment The witness tubes go through the motions of sample collection without collecting rock or soil samples and are sealed and cached like Martian samples Witness tubes aim to ensure that any potential Earth contaminants are detected during sample collection This is to provide the validity of the samples once returned to Earth for analysis During the processing of the WTA two faults occurred On sol 584 there was a fault during the simulated coring which resulted in only 5 of the normally 7 spindle percuss motions being performed and no percuss to ingest motion was executed While anomaly recovery was being undertaken the tube remained in the corer and exposed to the Martian environment about 10 times longer than normal WTA sample exposure time A second fault occurred after the sealing of the tube on sol 586 and left the hermetically sealed WTA sitting in the sealing station at an elevated temperature up to 40 C until sol 591 The witness tube was successfully sealed on October 14 2022 Sol 587 and placed into storage on October 19 2022 Sol 592 148 20 November 24 2022 Sol 627 November 29 2022 Sol 631 SN242 SN151 10464848 5 SN113 Fine grained moderately sorted sedimentary rock sulphate bearing coarse sandstone nbsp Kukaklek Hidden Harbor77 23 57 N 18 27 13 E 77 39911 N 18 45364 E 77 39911 18 45364 4 97 cm 1 96 in 1 78 x 10 6 mol Hidden Harbor Delta Front First Sample from an abrasion patch abraded earlier on the rock It was sampled on November 29 2022 Sol 631 21 December 2 2022 Sol 634 SN059 SN098 10464848 5 SN063 Regolith Sand Sample likely containing mixed sedimentary and igneous grains nbsp Atmo Mountain Observation Mountain77 24 04 N 18 27 05 E 77 40122 N 18 45131 E 77 40122 18 45131 5 30 cm 2 09 in 1 87 x 10 6 mol Observation Mountain Delta Front First Regolith Sample 22 November 7 2022 Sol 639 SN173 SN191 10464848 6 SN106 Regolith Sand Sample likely containing mixed sedimentary and igneous grains nbsp Crosswind Lake nbsp December 29 2022 Sol 661 at Three Forks Sample Spot 3 Observation Mountain77 24 04 N 18 27 05 E 77 40122 N 18 45131 E 77 40122 18 45131 5 30 cm 2 09 in 1 88 x 10 6 mol Observation Mountain Delta Front 23 March 30 2023 Sol 749 SN214 SN066 1064848 5 SN150 Sedimentary Rock Sample nbsp Melyn Berea Outcrop77 23 02 N 18 28 13 E 77 383946 N 18 470216 E 77 383946 18 470216 6 04 cm 2 38 in Berea Tenby Upper Fan First Sample taken after completion of sample depot and the first taken under the new mission campaign 24 May 23 2023 Sol 802 SN094 10464848 3 Conglomerate Sedimentary Rock Sample N A Abandoned sample from this site due to small sample collection Onahu outcrop77 22 07 N 18 26 00 E 77 368526 N 18 433455 E 77 368526 18 433455 1 30 cm 0 51 in Non Cached N A Onahu Upper Fan The first attempt yielded a sample that was unfortunately too small and the second attempt was unsuccessful and caching would have resulted in another empty Roubion atmospheric sample tube A conglomerate rock is of special interest to the Science Team because they are made up of many clasts of rocks These distinct clasts become cemented together over time to form the conglomerate Importantly these clasts were likely transported to Jezero crater from much farther away Analyzing the distinct clasts and cements captured in a sample of the conglomerate would give insights into where these materials were sourced how far they traveled and what the martian environment was like both when the clasts first formed and when the conglomerate rock formed 25 June 4 2023 Sol 813 N A Abandoned after failed attempt of collecting rock sample N A N A 26 June 23 2023 Sol 832 Otis Peak Emerald Lake77 22 05 N 18 28 59 E 77 368179 N 18 482989 E 77 368179 18 482989 5 77 cm 2 27 in Emerald Lake Upper Fan 27 September 15 2023 Sol 914 SN258 SN451 10464848 4 SN196 Pilot Mountain Dream Lake 6 00 cm 2 36 in Dream Lake Upper Fan 28 September 23 2023 Sol 922 Sedimentary Rock Sample Pelican Point Hans Amundsen Memorial Workspace 6 10 cm 2 40 in Hans Amundsen Memorial Workspace Margin Unit 29 October 21 2023 Sol 949 Sedimentary Rock Sample Lefroy Bay Turquoise Bay 4 70 cm 1 85 in Turquoise Bay Margin Unit 30 March 11 2024 Sol 1087 Silica cemented Carbonate Comet Geyser Bunsen Peak 5 78 cm 2 28 in Bunsen Peak Margin Unit Sources 149 150 151 152 153 154 Sample and Depot Overview Samples Tubes Cached 63 43 27 Samples Tubes Left at Three Forks Sample Depot 100 10 Type Of Cached Samples Samples By Type Witness 3 11 11 Atmospheric 1 3 70 Igneous 8 29 63 Sedimentary 12 44 44 Regolith 2 7 40 Silica cemented Carbonate 1 3 70 Drilled Holes nbsp All Drilled Holes On Mars By Perseverance except Atsa sample Scrollable image Sample Depot at Three Forks nbsp Mars Sample Depot at 3 forksThree Forks Sample Depot editAfter nearly a Martian year of NASA s Perseverance Mars rover s science and sample caching operations for MSR campaign the rover is currently tasked to deposit ten samples that it has cached from beginning at Three Forks Sample Depot as NASA aims to eventually return them to Earth starting from December 19 2022 This depot will serve as a backup spot in case Perseverance cannot deliver its samples Perseverance is depositing the samples at a relatively flat terrain known as Three Forks so that NASA and ESA could recover them in its successive missions in the MSR campaign It is even selected as the backup landing spot for the Sample Retrieval Lander It is a relatively benign place It is as flat and smooth as a table top nbsp Testing a Sample Drop in the Mars Yard with VSTB OPTIMISM Rover Perseverance s complex Sampling and Caching System takes almost an hour to retrieve the metal tube from inside the rover s belly view it one last time with its internal Cachecam and drop the sample 0 89 m 2 ft 11 in onto a carefully selected patch of Martian surface 145 nbsp Mars Perseverance rover wind lifts a massive dust cloud June 18 2021 The tubes will not be piled up at a single spot Instead each tube drop location will have an area of operation 5 5 m 18 ft in diameter To that end the tubes will be deposited on the surface in an intricate zigzag pattern of 10 spots for 10 tubes with each sample 5 m 16 ft to 15 m 49 ft apart from one another near the proposed Sample retrieval lander s landing site There are various reasons for this plan most significantly the design of the sample recovery helicopters They are designed to interact with only one tube at a time Alongside they will perform takeoffs and landings and driving in that spot To ensure a helicopter could retrieve samples without any problem the plan is to be executed properly and would span over more than two months nbsp Perseverance Views Dust Devils Swirling Across Jezero Crater Before and after Perseverance drops each tube mission controllers will review a multitude of images from the rover s SHERLOC WATSON camera Images by the SHERLOC WATSON camera are also used to check for surety that the tube had not rolled into the path of the rover s wheels They also look to ensure the tube had not landed in such a way that it was standing on its end each tube has a flat end piece called a glove to make it easier to be picked up by future missions That occurred less than 5 of the time during testing with Perseverance s Earthly twin OPTIMISM in JPL s Mars Yard In case it does happen on Mars the mission has written a series of commands for Perseverance to carefully knock the tube over with part of the turret at the end of its robotic arm nbsp A Map of Perseverance s Sample Depots These SHERLOC WATSON camera images will also give the Mars Sample Return team the precise data necessary to locate the tubes in the event of the samples becoming covered by dust or sand before they are collected Mars does get windy but not like on Earth as the atmosphere on Mars is 100 times less dense than that of Earth s atmosphere so winds on Mars can pick up speed the fastest are Dust devils but they don t pick up a lot of dust particles Martian wind can certainly lift fine dust and leave it on surfaces but even if significant dust is accumulated these images the depositing pattern will help to recover them back 155 A lucky encounter with a dust devil could remove dust over the samples as in case with the solar panels of Spirit rover and Opportunity rover Once this whole task of depositing all the 10 samples is completed Perseverance will carry on with its mission traversing to the Crater floor and scaling Delta s summit The rover be traversing along the edge of the crater and probably caching more tubes then whilst following the plan of taking single sample at one rock Till now several pairs of samples were taken and one samples from pair will be placed at the depot and the other pair will stay on board the rover 156 157 Sample retrieval editThe Mars Sample Return mission earlier in its design process consisted of the ESA Sample Fetch Rover and its associated second lander alongside the Mars ascent vehicle and its lander that will take the samples to it from where the samples will be launched back to Earth But after consideration and cost overruns it was decided that given Perseverance s expected longevity the extant rover will be the primary means of transporting samples to the Sample Retrieval Lander SRL Sample Retrieval Lander edit The sample retrieval mission involves launching a 5 solar array sample return lander in 2028 with the Mars Ascent Vehicle and two sample recovery helicopters as a backup for Perseverance The SRL lander is about the size of an average two car garage weighing 3 375 kg 7 441 lb tentatively planned to be 7 7 m 25 ft wide and 2 1 m 6 9 ft high when fully deployed The payload mass of the lander is double that of the Perseverance rover that is 563 kg 1 241 lb The lander needs to be close to the Perseverance rover to facilitate the transfer of Mars samples It must land within 60 m 200 ft of its target site much closer than previous Mars rovers and landers Thus it will have a secondary battery to power the lander to land on Mars The lander would take advantage of an enhanced version of NASA s successful Terrain Relative Navigation that helped land Perseverance safely The new Enhanced Lander Vision System would among other improvements add a second camera an altimeter and better capabilities to use propulsion for precision landing It is planned to land near at Three Forks in 2029 nbsp ESA Sample Transfer Arm The Mars 2020 rover and helicopters will transport the samples to the SRL lander SRL s ESA built 2 40 m 7 9 ft long Sample Transfer Arm will be used to extract the samples and load them into the Sample Return Capsule in the Ascent Vehicle 5 158 Mars Sample Recovery Helicopters edit Main article Mars Sample Recovery Helicopter The MSR campaign includes Ingenuity class helicopters both of which will collect the samples with the help of a tiny robotic arm and move them to the SRL in case the Perseverance rover runs into problems Mars Ascent Vehicle MAV edit Mars Ascent Vehicle 159 nbsp Mars Ascent Vehicle mockup on display FunctionMars Orbital launch vehicleManufacturerNASA s Marshall Space Flight Center Lockheed Martin Northrop Grumman 160 161 Country of originUnited StatesSizeHeight2 26 m 7 4 ft Diameter0 5 m 1 6 ft Mass450 kg 990 lb Stages2CapacityPayload to LAOAltitude500 km 310 mi Mass500 g 18 oz Launch historyStatusUnder DevelopmentLaunch sitesVector mid air after release from Sample Retrieval Lander Three Forks Jezero CraterTotal launches1 planned UTC date of spacecraft launch2030 planned Type of passengers cargoOrbiting Sample Container with 30 43 tubes Radio Beacon hosted First stagePowered by1 optimized Star 20 Altair 3 Burn time75 sPropellantCTPBSecond stagePowered by1 optimized Star 15GBurn time20 sPropellantHTPB edit on Wikidata Mars Ascent Vehicle MAV is a two stage solid fueled rocket that will deliver the collected samples from the surface of Mars to the Earth Return Orbiter Early in 2022 Lockheed Martin was awarded a contract to partner with NASA s Marshall Space Flight Center in developing the MAV and engines from Northrop Grumman 162 It is planned to be catapulted upward as high as 4 5 m 15 ft above the lander or 6 5 m 21 ft above the Martian surface into the air just before it ignites at a rate of 5 m 16 ft per second to remove the odds of liftoff issues such as slipping or tilting the SRL with the rocket s sheer weight and exhaust at liftoff The front would be tossed a bit harder than the back causing the rocket to point upward toward the Martian sky Thus the Vertically Ejected Controlled Tip off Release VECTOR system adds a slight rotation during launch pitching the rocket up and away from the surface 163 MAV would enter a 380 kilometre 240 mi orbit 164 It will remain stowed inside a cylinder on the SRL and will have a thermal protective coating The rocket s first stage SRM 1 would burn for 75 seconds The SRM1 engine can gimbal but most gimballing solid rocket motor nozzles are designed in a way that can t handle the extreme cold MAV will experience so the Northrop Grumman team had to come up with something that could a state of the art trapped ball nozzle featuring a supersonic split line citation needed After SRM1 burnout the MAV will remain in a coast period for approximately 400 seconds During this time the MPA aerodynamic fairing and entire first stage will separate from the vehicle After stage separation the second stage will initiate a spin up via side mounted small scale RCS thrusters The entire second stage will be unguided and spin stabilized at a rate of approximately 175 RPM Having achieved the target spin rate the second stage SRM 2 will ignite and burn for approximately 18 20 seconds raising the periapsis and circularizing the orbit 165 The second stage is planned to be spin stabilized to save weight in lieu of active guidance while the Mars samples will result in an unknown payload mass distribution 164 Spin stabilization allows the rocket to be lighter so it won t have to carry active control all the way to orbit Following SRM2 burnout the second stage will coast for up to 10 minutes while residual thrust from the SRM2 occurs Side mounted small de spin motors will then fire reducing the spin rate to less than 40 RPM Once the target orbit has been achieved the MAV will command the MPA to eject the Orbiting Sample Container OS The spent second stage of the MAV will remain in orbit broadcasting a hosted radio beacon signal for up to 25 days This will aid in the capture of the OS by the ERO 159 MAV is scheduled to be launched in 2028 onboard the SRL lander 5 Components of the Sample Return Landers nbsp Concept launch set up nbsp Interior design of MAV First Extraterrestrial Staging Rocket nbsp MAV exterior design nbsp MAV flight plan nbsp Mars Sample Return 2020 2033 TimelineSample return editEarth Return Orbiter ERO edit ERO is an ESA developed spacecraft 166 167 It includes the NASA built Capture and Containment and Return System CCRS and Electra UHF Communications Package It will rendezvous with the samples delivered by MAV in low Mars orbit LMO The ERO orbiter is planned to weigh 7 000 kg 15 000 lb largest Mars Orbiter and have solar arrays resulting in a wingspan of more than 38 m 125 ft These solar panels are some of the largest ever launched into space 168 ERO is scheduled to launch on an Ariane 6 rocket in 2027 and arrive at Mars in 2029 using ion propulsion and a separate chemical propulsion element to gradually reach the proper orbit of 325 km 202 mi and then rendezvous with the orbiting sample 169 The MAV s second stage s radio beacon will give controllers the information they need to get the ESA Earth Return Orbiter close enough to the Orbiting Sample to see it through reflective light and capture it for return to earth To do this the ERO would use high performance cameras to detect the Orbiting Sample at over 1 000 km 620 mi distance Once locked on the ERO would track it continuously using cameras and LiDARs throughout the rendezvous phase Once aligned with the sample container the Capture Containment and Return System would power on open its capture lid and turn on its capture sensors ESA s orbiter would then push itself toward the sample container at about 1 to 2 inches 2 5 to 5 centimeters per second to overtake and swallow it After detecting that the sample container is safely inside the Capture Containment and Return System would quickly close its lid Thus the orbiter will retrieve and seal the canisters in orbit and use a NASA built robotic arm to place the sealed container into an Earth entry capsule The 600 kg 1 300 lb CCRS would be responsible for thoroughly sterilizing the exterior of the Orbiting Sample and double sealing it inside the EES creating a secondary containment barrier to keep the samples safely isolated and intact for maximum scientific return It will raise its orbit jettison the propulsion element including 500 kg 1 100 lb of CCRS hardware which is of no use after sterilizing samples and return to Earth during the 2033 Mars to Earth transfer window 168 The ERO will measure the total radiation dose received throughout the entire flight Results will help monitor the health of the spacecraft and provide important information on how to protect human explorers in future trips to Mars 168 Earth Entry Vehicle EEV edit nbsp OSIRIS REx Sample Return Capsule in Utah The EEV will have a similar design with added structural hardening to withstand a non parachuted landing The Capture Containment and Return System CCRS would stow the sample in the EEV The EEV would return to Earth and land passively without a parachute About a week before arrival at Earth and only after successfully completing a full system safety check out the ERO spacecraft would be configured to perform the Earth return phase When the orbiter is three days away from Earth the EEV will be released from the main spacecraft and fly a precision entry trajectory to a predetermined landing site Shortly after separation the orbiter itself would perform a series of maneuvers to enter orbit around the Sun never to return to Earth The desert sand at the Utah Test and Training Range and shock absorbing materials in the vehicle are planned to protect the samples from impact forces 170 171 167 The EEV is scheduled to land on Earth in 2033 172 Artist s concept of Mars sample return orbiter nbsp Cross section of the Earth return orbiter nbsp Earth Return Orbiter nbsp Capture and containment systemGallery editPotential sample return landing site 14 April 2022 nbsp nbsp Mars sample return mission Sampling Process nbsp Context nbsp MidView nbsp CloseUp nbsp Sample in drill nbsp Sampling drill nbsp Sample Tube 233 Mars sample return mission Sample Tubes nbsp Exterior nbsp Interior nbsp CT Scan animation nbsp Witness Sample Tube Mars sample return mission source source source source source source source Perseverance rover Sample collection and storage animated video 02 22 February 6 2020 nbsp Orbiting sample container concept 2020 nbsp Inserting sample tubes into the rover nbsp Cleaning sample tubes Mars sample return mission 2020 artist s impression 173 174 nbsp 01 Perseverance rover obtaining samples nbsp 02 Perseverance rover storing samples nbsp 03 SRL 1 landing pattern nbsp 04 SRL unfolded nbsp 05 Mars Samples return helicopters deployed by SRL and fetching samples as a backup nbsp 06 SRL picking up samples and loading them on MAV for launch nbsp 07 Launching from Mars to low Martian Orbit nbsp 08 MAV in powered flight after release from vector nbsp 09 MAV in coast phase in Low Mars orbit after Main engine cutoff awaiting stage separation and second engine startup nbsp 10 Payload Separation thereby Releasing samples for later pickup by the Earth Return OrbiterSee also edit nbsp Spaceflight portal Timeline of Solar System explorationNotes edit Based on CacheCam Images clarify The witness tubes not involving use of drill bits or using regolith drill bit are displayed by cachecam images measured by volume stations measured by volume stationsReferences edit Chang Kenneth July 27 2022 NASA Will Send More Helicopters to Mars Instead of sending another rover to help retrieve rock and dirt samples from the red planet and bring them to Earth the agency will provide the helicopters as a backup option The New York Times Retrieved July 28 2022 Mars Sample Return Bringing Mars Rock Samples Back to Earth retrieved February 6 2023 Berger Eric September 21 2023 Independent reviewers find NASA Mars Sample Return plans are seriously flawed Ars Technica Retrieved September 23 2023 Chang Kenneth July 28 2020 Bringing Mars Rocks to Earth Our Greatest Interplanetary Circus Act NASA and the European Space Agency plan to toss rocks from one spacecraft to another before the samples finally land on Earth in 2031 The New York Times Retrieved July 28 2020 a b c d Foust Jeff March 27 2022 NASA to delay Mars Sample Return switch to dual lander approach SpaceNews Retrieved March 28 2022 Future Planetary Exploration New Mars Sample Return Plan December 8 2009 Mars sample return www esa int Retrieved January 3 2022 mars nasa gov Mars Sample Return Campaign mars nasa gov Retrieved June 15 2022 mars nasa gov NASA Mars Ascent Vehicle Continues Progress Toward Mars Sample Return NASA Mars Exploration Retrieved August 1 2023 Berger Eric June 23 2023 NASA s Mars Sample Return has a new price tag and it s colossal Ars Technica Retrieved August 1 2023 Berger Eric July 13 2023 The Senate just lobbed a tactical nuke at NASA s Mars Sample Return program Ars Technica Retrieved August 1 2023 Smith Marcia November 13 2023 NASA Pauses Mars Sample Return Program While Assessing Options spacepolicyonline com Retrieved November 18 2023 Berg Matt November 22 2023 Lawmakers mystified after NASA scales back Mars collection program The space agency s cut could cost hundreds of jobs and a decade of lost science the bipartisan group says Politico Archived from the original on November 22 2023 Retrieved November 25 2023 a b c NASA Invites Media to Mars Sample Return Update NASA Retrieved April 15 2024 NASA says it s revising the Mars Sample Return mission due to cost long wait time ABC News Retrieved April 15 2024 a b Chang Kenneth April 15 2024 NASA Seeks Hail Mary for Its Mars Rocks Return Mission The agency will seek new ideas for its Mars Sample Return program expected to be billions of dollars over budget and years behind schedule The New York Times Archived from the original on April 16 2024 Retrieved April 16 2024 Mars Sample Return Studies for a Fresh Look R Mattingly S Matousek and R Gershman 2002 IEEE Aerospace Conference 2 493 Mars Ascent Vehicle Concept Development D Stephenson AIAA 2002 4318 38th AIAA ASME SAE ASEE Joint Propulsion Conference July 7 10 2002 Mars Sample Return Updated to a Groundbreaking Approach R Mattingly S Matousek and F Jordan 2003 IEEE Aerospace Conference 2 745 Planetary Protection Technology for Mars Sample Return R Gershman M Adams R Dillman and J Fragola paper number 1444 2005 IEEE Aerospace Conference March 2005 Continuing Evolution of Mars Sample Return R Mattingly S Matousek and F Jordan 2004 IEEE Aerospace Conference p 477 Technology Development Plans for the Mars Sample Return Mission R Mattingly S Hayati and G Udomkesmalee 2005 IEEE Aerospace Conference Mars Base Technology Program Overview C Chu S Hayati S Udomkesmalee and D Lavery AIAA 2005 6744 AIAA Space 2005 Conference August 30 to September 1 2005 Whitehead J C November December 2005 Trajectory Analysis and Staging Trades for Smaller Mars Ascent Vehicles Journal of Spacecraft and Rockets 42 6 1039 1046 Bibcode 2005JSpRo 42 1039W doi 10 2514 1 10680 Mars Ascent Vehicle Key Elements of a Mars Sample Return Mission D Stephenson and H Willenberg 2006 IEEE Aerospace Conference paper number 1009 Kornfeld R J Parrish and S Sell May June 2007 Mars Sample Return Testing the Last Meter of Rendezvous and Sample Capture Journal of Spacecraft and Rockets 44 3 692 702 Space science and the bottom line A Witze Nature 448 p 978 August 30 2007 Mars Sample Return Proposal Stirs Excitement Controversy L David Space News July 23 2007 p 19 Defining the Mars Ascent Problem for Sample Return J Whitehead AIAA 2008 7768 AIAA Space 2008 Conference San Diego Calif September 2008 Mars Ascent Vehicle Technology Planning J Dankanich 2009 IEEE Aerospace Conference March 2009 Pump Fed Propulsion for Mars Ascent and Other Challenging Maneuvers J Whitehead NASA Science Technology Conference June 2007 Strategic Technology Development for Future Mars Missions 2013 2022 S Hayati et al A white paper submitted to the National Research Council as input to the Planetary Decadal Survey September 2009 https mepag jpl nasa gov reports decadal SamadAHayati pdf Mars Exploration Program Analysis Group Retrieved November 11 2022 NASA and ESA Establish a Mars Exploration Joint Initiative NASA July 8 2009 Archived from the original on October 28 2009 Retrieved December 27 2022 nbsp This article incorporates text from this source which is in the public domain Christensen Phil April 2010 Planetary Science Decadal Survey MSR Lander Mission JPL NASA Retrieved August 24 2012 nbsp This article incorporates text from this source which is in the public domain Mars Sample Return Archived May 18 2008 at the Wayback Machine NASA Accessed May 26 2008 nbsp This article incorporates text from this source which is in the public domain BBC Science Nature Date set for Mars sample mission July 10 2008 Mars Sample Return bridging robotic and human exploration European Space Agency July 21 2008 Retrieved November 18 2008 a b NASA Advisory Council Science Committee website https science nasa gov science committee Retrieved July 4 2023 NASA Advisory Council Science Committee February 16 17 2010 Meeting Report https smd prod s3 amazonaws com science pink s3fs public mnt medialibrary 2010 08 31 SC Minutes Feb2010 Mtg Final 100423 Signed pdf page 6 NASA Headquarters Page 6 Retrieved July 4 2023 a b International cooperation called key to planet exploration NBC News August 22 2012 Sample Return Propulsion Technology Development under NASA s ISPT Project D Anderson J Dankanich D Hahne E Pencil T Peterson and M Munk 2011 IEEE Aerospace Conference Paper number 1115 March 2011 Mars Sample Return Orbiter Earth Return Vehicle Technology Needs and Mission Risk Assessment J Dankanich L Burke and J Hemminger 2010 IEEE Aerospace Conference Paper number 1483 March 2010 Mars Ascent Vehicle Test Requirements and Terrestrial Validation D Anderson J Dankanich D Hahne E Pencil T Peterson and M Munk 2011 IEEE Aerospace Conference Paper number 1115 March 2011 Mars Sample Return Campaign Status E Nilsen C Whetsel R Mattingly and L May 2012 IEEE Aerospace Conference Paper number 1627 March 2012 Status of Sample Return Propulsion Technology Development under NASA s ISPT Program D Anderson M Munk J Dankanich L Glaab E Pencil and T Peterson 2012 IEEE Aerospace Conference March 2012 a b Mars Ascent Vehicle Development Status J Dankanich and E Klein 2012 IEEE Aerospace Conference March 2012 a b Mars Ascent Vehicle MAV Designing for High Heritage and Low Risk D Ross J Russell and B Sutter 2012 IEEE Aerospace Conference March 2012 Mars Ascent Vehicle System Studies and Baseline Conceptual Design M Trinidad E Zabrensky and A Sengupta 2012 IEEE Aerospace Conference March 2012 Systems Engineering and Support Systems Technology Considerations of a Mars Ascent Vehicle A Sengupta M Pauken A Kennett M Trinidad and E Zabrensky 2012 IEEE Aerospace Conference March 2012 NOFBX Single Stage to Orbit Mars Ascent Vehicle G Mungas D Fisher J Vozoff and M Villa 2012 IEEE Aerospace Conference March 2012 a b National Academy of Sciences National Academies Press http www nap edu download php record id 13117 Visions and Voyages for Planetary Science in the Decade 2013 2022 2011 ISBN 978 0 309 22464 2 Retrieved December 30 2022 EXPLORING OUR SOLAR SYSTEM THE ASTEROIDS ACT AS A KEY STEP www govinfo gov Will Tight Budgets Sink NASA Flagships Y Bhattacharjee Science 334 758 759 11 November 2011 Planetary Science is Busting Budgets R Kerr Science 337 402 404 July 27 2012 House Panel Wants NASA to Plan Mars Sample Return Y Bhattacharjee Science April 18 2012 Concepts and Approaches for Mars Exploration June 12 14 2012 Houston Texas https www lpi usra edu meetings marsconcepts2012 Universities Space Research Association website Retrieved August 15 2023 Concepts and Approaches for Mars Exploration Report of a Workshop at LPI June 12 14 2012 https www lpi usra edu lpi contribution docs LPI 001676 pdf S Mackwell et al Universities Space Research Association website Retrieved August 15 2023 Technology and Enabling Capabilities https www lpi usra edu meetings marsconcepts2012 reports 1 technology and enabling capabilities pdf M Amato B Ehlmann V Hamilton B Mulac Universities Space Research Association website Retrieved August 15 2023 Launch and Transfer Systems Technology and Architecture Considerations for Mars Exploration https www lpi usra edu meetings marsconcepts2012 pdf 4144 pdf L Craig Universities Space Research Association website Retrieved August 15 2023 High Performance Mars Ascent Propulsion Technologies with Adaptability to ISRU and Human Exploration https www lpi usra edu meetings marsconcepts2012 pdf 4222 pdf M Trinidad J Calvignac A Lo Universities Space Research Association website Retrieved August 15 2023 a b A Perspective on Mars Ascent for Scientists https www lpi usra edu meetings marsconcepts2012 pdf 4290 pdf J Whitehead Universities Space Research Association website Retrieved August 15 2023 A Storable Hybrid Mars Ascent Vehicle Technology Demonstrator for the 2020 Launch Opportunity https www lpi usra edu meetings marsconcepts2012 pdf 4342 pdf A Chandler et al Universities Space Research Association website Retrieved August 15 2023 NOFBX Mars Ascent Vehicle A Single Stage to Orbit Approach https www lpi usra edu meetings marsconcepts2012 pdf 4353 pdf J Vozoff D Fisher G Mungas Universities Space Research Association website Retrieved August 15 2023 Leone Dan October 3 2012 Mars Planning Group Endorses Sample Return SpaceNews Retrieved March 1 2022 Mars Program Planning Group September 25 2012 Summary of the Final Report PDF Archived from the original PDF on June 2 2016 Retrieved December 27 2022 Wall Mike September 27 2012 Bringing Pieces of Mars to Earth How NASA Will Do It Space com Mattingly Richard March 2010 Mission Concept Study Planetary Science Decadal Survey MSR Orbiter Mission Including Mars Returned Sample Handling PDF NASA Archived from the original PDF on September 29 2015 nbsp This article incorporates text from this source which is in the public domain Amos Jonathan July 6 2018 Fetch rover Robot to retrieve Mars rocks BBC Harwood William December 4 2012 NASA announces plans for new US 1 5 billion Mars rover CNET Retrieved August 15 2023 Using spare parts and mission plans developed for NASA s Curiosity Mars rover the space agency says it can build and launch the rover in 2020 and stay within current budget guidelines Mars Sample Return Using Commercial Capabilities Mission Architecture Overview A Gonzales C Stoker L Lemke J Bowles L Huynh N Faber and M Race 2014 IEEE Aerospace Conference March 2014 Mars Sample Return Using Commercial Capabilities Propulsive Entry Descent and Landing L Lemke A Gonzales and L Huynh 2014 IEEE Aerospace Conference March 2014 Mars Sample Return Mars Ascent Vehicle Mission amp Technology Requirements J Bowles L Huynh V Hawke and X Jiang NASA TM 2013 216620 November 2013 https ntrs nasa gov api citations 20140011316 downloads 20140011316 pdf NASA Technical Reports Server Retrieved January 8 2023 The Mobile MAV Concept for Mars Sample Return E Klein E Nilsen A Nicholas C Whetsel J Parrish R Mattingly and L May 2014 IEEE Aerospace Conference March 2014 a b History of Mars Ascent Vehicle Development Over the Last 20 Years R Shotwell 2016 IEEE Aerospace Conference March 2016 Technology Development and Design of Liquid Bipropellant Mars Ascent Vehicles D Vaughan B Nakazono A Karp R Shotwell A London A Mehra and F Mechentel 2016 IEEE Aerospace Conference March 2016 Drivers Developments and Options Under Consideration for a Mars Ascent Vehicle R Shotwell J Benito A Karp and J Dankanich 2016 IEEE Aerospace Conference March 2016 A Mars Ascent Vehicle for Potential Mars Sample Return R Shotwell J Benito A Karp and J Dankanich 2017 IEEE Aerospace Conference March 2017 Break the Chain Technology for Potential Mars Sample Return R Gershman Y Bar Cohen M Hendry M Stricker D Dobrynin and A Morrese 2018 IEEE Aerospace Conference March 2018 Rincon Paul April 26 2018 Space agencies intent on mission to deliver Mars rocks to Earth BBC Video 02 22 Bringing Mars Back To Earth NASA April 26 2018 Archived from the original on December 22 2021 nbsp This article incorporates text from this source which is in the public domain Joint Statement of Intent between the National Aeronautics and Space Administration and the European Space Agency on Mars Sample Return T Zurbuchen and D Parker April 26 2018 https mepag jpl nasa gov announcements 2018 04 26 20NASA ESA 20SOI 20 Signed pdf Mars Exploration Program Analysis Group Retrieved January 28 2023 2nd International Mars Sample Return Conference April 25 27 2018 https astrobiology nasa gov events 2nd international mars sample return conference Astrobiology at NASA Retrieved January 28 2023 2018 International Mars Sample Return Conference Berlin https www lpi usra edu lpi contribution docs LPI 002071 pdf Lunar and Planetary Institute Retrieved January 28 2023 Seeking Signs of Life on Mars The Importance of Sedimentary Suites as Part of Mars Sample Return iMOST Team International MSR Objectives and Samples Team MSR 2018 Berlin https www lpi usra edu lpi contribution docs LPI 002071 pdf page 103 Lunar and Planetary Institute Retrieved 18 February 2023 Mars Sample Return Architecture Overview C Edwards and S Vijendran MSR 2018 Berlin https www lpi usra edu lpi contribution docs LPI 002071 pdf page 74 Lunar and Planetary Institute Retrieved February 12 2023 Commercial Capabilities to Accelerate Timeline and Decrease Cost for Return of Samples from Mars P Wooster M Marinova and J Brost MSR 2018 Berlin https www lpi usra edu lpi contribution docs LPI 002071 pdf page 172 Lunar and Planetary Institute Retrieved February 12 2023 Mars Ascent Vehicle Needs Technology Development with a Focus on High Propellant Fractions J Whitehead MSR 2018 Berlin https www lpi usra edu lpi contribution docs LPI 002071 pdf page 168 Lunar and Planetary Institute Retrieved February 12 2023 Foust Jeff July 28 2019 Mars sample return mission plans begin to take shape SpaceNews Cowart Justin August 13 2019 NASA ESA Officials Outline Latest Mars Sample Return Plans The Planetary Society Mars Sample Return Lander Mission Concepts B Muirhead and A Karp 2019 IEEE Aerospace Conference March 2019 Development Concepts for Mars Ascent Vehicle MAV Solid and Hybrid Vehicle Systems L McCollum et al 2019 IEEE Aerospace Conference March 2019 A Design for a Two Stage Solid Mars Ascent Vehicle A Prince T Kibbey and A Karp AIAA 2019 4149 AIAA Propulsion and Energy Forum August 2019 Bold plan to retrieve Mars samples takes shape D Clery and P Voosen Science 366 932 November 22 2019 Mars Sample Return Mission Concept Status B Muirhead A Nicholas and J Umland 2020 IEEE Aerospace Conference March 2020 Mars Ascent Vehicle Solid Propulsion Configuration D Yaghoubi and A Schnell 2020 IEEE Aerospace Conference March 2020 Mars Ascent Vehicle Hybrid Propulsion Configuration D Yaghoubi and A Schnell 2020 IEEE Aerospace Conference March 2020 Clark Stephen April 20 2020 NASA narrows design for rocket to launch samples off of Mars Spaceflight Now Retrieved April 21 2020 Integrated Design Results for the MSR DAC 0 0 Mars Ascent Vehicle D Yaghoubi and P Ma 2021 IEEE Aerospace Conference March 2021 Mars Sample Return MSR Program Final Report of the Independent Review Board IRB https www nasa gov sites default files atoms files nasa esa mars sample return final report small pdf page 10 NASA reports website Retrieved July 6 2023 Summary of NASA Responses to Mars Sample Return Independent Review Board Recommendations https www nasa gov sites default files atoms files nasa esa mars sample return final report small pdf page 1 NASA reports website Retrieved July 6 2023 Mars Sample Return MSR Program Final Report of the Independent Review Board IRB Notes below Chart 33 https www nasa gov sites default files atoms files nasa esa mars sample return final report small pdf page 42 NASA reports website Retrieved July 6 2023 Mars Sample Return MSR Program Final Report of the Independent Review Board IRB Chart 42 and notes below it https www nasa gov sites default files atoms files nasa esa mars sample return final report small pdf page 51 NASA reports website Retrieved July 6 2023 Mars Sample Return MSR Program Final Report of the Independent Review Board IRB Chart 43 and notes below it https www nasa gov sites default files atoms files nasa esa mars sample return final report small pdf page 52 NASA reports website Retrieved July 6 2023 Mars Sample Return MSR Program Final Report of the Independent Review Board IRB Chart 57 and notes below it https www nasa gov sites default files atoms files nasa esa mars sample return final report small pdf page 66 NASA reports website Retrieved July 6 2023 NASA Planetary Science Advisory Committee website https science nasa gov researchers nac science advisory committees pac Retrieved July 4 2023 NASA Advisory Council Science Committee April 14 15 2021 Meeting Report https science nasa gov science red s3fs public atoms files FINAL 20Science 20Cmte 20Meeting 20Minutes Signed April 202021 pdf page 3 NASA Headquarters Page 3 Retrieved July 4 2023 Integrated Design Results for the MSR SRC Mars Ascent Vehicle D Yaghoubi and S Maynor 2022 IEEE Aerospace Conference March 2022 Planetary Science and Astrobiology Decadal Survey 2023 2032 https www nationalacademies org our work planetary science and astrobiology decadal survey 2023 2032 National Academies of Sciences Engineering and Medicine Retrieved February 26 2023 Origins Worlds and Life A Decadal Strategy for Planetary Science and Astrobiology 2023 2032 https nap nationalacademies org catalog 26522 origins worlds and life a decadal strategy for planetary science https doi org 10 17226 26522 National Academies of Sciences Engineering and Medicine Space Studies Board National Academies Press 2022 ISBN 978 0 309 47578 5 See pages 22 7 to 22 9 Retrieved February 26 2023 Why Mars Sample Return is a Mission Campaign of Compelling Importance to Planetary Science and Exploration https mepag jpl nasa gov reports decadal2023 2032 MSR 20science 20white 20paper final4 pdf MEPAG website Retrieved July 5 2023 Mars Sample Return Campaign Concept Architecture https mepag jpl nasa gov reports decadal2023 2032 Decadal 20White 20Paper 20MuirheadBrianK pdf MEPAG website Retrieved July 5 2023 The Challenge of Launching Geology Samples off of Mars is Easily Underestimated Due to Tempting Misconceptions https mepag jpl nasa gov reports decadal2023 2032 WhiteheadMisconceptionsMAV2020Oct11 pdf MEPAG website Retrieved July 4 2023 Mars Ascent Vehicle needs a Sustained Development Effort Regardless of Sample Return Mission Timelines https mepag jpl nasa gov reports decadal2023 2032 WhiteheadSustainMAV2020Oct11 pdf MEPAG website Retrieved July 4 2023 Technology Development Can Lead to Smaller Mars Ascent Vehicles for Multiple Affordable Sample Returns https mepag jpl nasa gov reports decadal2023 2032 WhiteheadSmallerMAV2020Oct11 pdf MEPAG website Retrieved July 4 2023 Decadal Survey on Planetary Science and Astrobiology Steering Group Seventh Meeting Revised Final Agenda https www nationalacademies org documents embed link LF2255DA3DD1C41C0A42D3BEF0989ACAECE3053A6A9B file DE1EC51702FEF69877C024F38B3437AA2CD7C9F72218 noSaveAs 1 National Academies of Sciences Engineering and Medicine Retrieved July 6 2023 Foust Jeff July 27 2022 NASA and ESA remove rover from Mars Sample Return plans https spacenews com nasa and esa remove rover from mars sample return plans Space News Retrieved December 21 2023 Mars choppers displace fetch rover in sample return plan J Foust Space News August 2022 p 6 7 Martian aviator an interview with Ben Pipenberg P Marks Aerospace America January 2023 p 14 19 Mars Rocks Await a Ride to Earth Can NASA Deliver A Witze Nature 616 p 230 231 April 13 2023 a b David Leopnard January 15 2024 NASA s troubled Mars sample return mission has scientists seeing red Projected multibillion dollar overruns have some calling the agency s plan a dumpster fire Space com Archived from the original on January 16 2024 Retrieved January 16 2024 Welcome to Octavia E Butler Landing NASA March 5 2021 Retrieved March 5 2021 Voosen Paul July 31 2021 Mars rover s sampling campaign begins Science 373 6554 AAAS 477 Bibcode 2021Sci 373 477V doi 10 1126 science 373 6554 477 PMID 34326215 S2CID 236514399 Retrieved August 1 2021 mars nasa gov On the Eve of Perseverance s First Sample mars nasa gov Retrieved August 12 2021 Voosem Paul June 21 2021 NASA s Perseverance rover to drill first samples of martian rock Science AAAS Retrieved August 1 2021 mars nasa gov Assessing Perseverance s First Sample Attempt mars nasa gov Retrieved August 12 2021 mars nasa gov September 2 2021 Nasa s perseverance rover successfully cores its first rock mars nasa gov Retrieved September 10 2021 mars nasa gov September 6 2021 Nasa s perseverance rover collects first Mars rock sample mars nasa gov Retrieved September 10 2021 mars nasa gov Perseverance Rover Mars Rock Samples NASA Mars Exploration Retrieved December 25 2023 Nobody Tell Elmo About Issole nasa gov Retrieved February 11 2022 mars nasa gov NASA s Perseverance Plans Next Sample Attempt NASA s Mars Exploration Program Retrieved August 27 2021 Sample Caching Dry Run 1st sample tube cached Twitter Retrieved August 27 2021 mars nasa gov Perseverance Sample Tube 266 NASA s Mars Exploration Program Retrieved September 9 2021 NASAPersevere July 8 2021 Lots of first time activities before I start drilling I recently ran one sample tube through inspection sealing a Tweet Retrieved August 27 2021 via Twitter Witness Tube in Perseverance Sample Caching System NASA Jet Propulsion Laboratory JPL Retrieved September 9 2021 mars nasa gov Perseverance s Drive to Citadelle NASA s Mars Exploration Program Retrieved September 6 2021 mars nasa gov Kicking off the Sampling Sol Path at Citadelle mars nasa gov Retrieved September 6 2021 Fox Karen Johnson Alana Agle AG September 2 2021 NASA s Perseverance Rover Successfully Cores Its First Rock NASA Retrieved September 3 2021 Chang Kenneth September 3 2021 On Mars NASA s Perseverance Rover Drilled the Rocks It Came For After an earlier drilling attempt failed to collect anything the rover appeared to gather its first sample But mission managers need to take another look before sealing the tube The New York Times Retrieved September 3 2021 Chang Kenneth September 7 2021 NASA s Perseverance Rover Stashes First Mars Rock Sample The rock sealed in a tube is the first of many the robotic explorer will collect to one day send back to Earth for scientists to study The New York Times Retrieved September 8 2021 mars nasa gov A Historic Moment Perseverance Collects Seals and Stores its First Two Rock Samples mars nasa gov Retrieved December 18 2021 a b NASAPersevere November 24 2021 A rock so nice I sampled it twice Just capped and sealed my fifth sample tube with another piece from this inter Tweet Retrieved December 18 2021 via Twitter mars nasa gov Assessing Perseverance s Seventh Sample Collection mars nasa gov Retrieved March 8 2022 mars nasa gov Pebbles Before Mountains mars nasa gov Retrieved March 8 2022 mars nasa gov Ejecting Mars Pebbles mars nasa gov Retrieved March 8 2022 a b mars nasa gov NASA s Perseverance Rover Deposits First Sample on Mars Surface NASA Mars Exploration Retrieved December 22 2022 nbsp This article incorporates text from this source which is in the public domain PaulHammond51 August 7 2022 chiragp87233561 Be careful with names The witness tube was not sampled at Skinner Ridge Skinner Ridge is the n Tweet Retrieved November 4 2022 via Twitter mars nasa gov Sealing Sample 14 NASA mars nasa gov Retrieved November 24 2022 Stephanie Connell Perseverance Activities at Amalik Outcrop NASA mars nasa gov Retrieved November 24 2022 mars nasa gov Perseverance Rover Mars Rock Samples NASA Mars Exploration Retrieved June 15 2022 MARS 2020 INITIAL REPORTS Crater Floor Campaign PDF MARS 2020 INITIAL REPORTS Volume 2 Delta Front Campaign February 15 2023 PDF MARS 2020 INITIAL REPORTS Volume 1 Crater Floor Campaign August 11 2022 PDF Mars 2020 Returned Sample Science Archive pds geosciences wustl edu Retrieved October 6 2022 I had a list I was working on combined it with the NASA website chart Twitter Retrieved October 24 2022 NASAPersevere December 23 2022 Mars does get windy but not like on Earth The atmosphere here is much less dense about 1 100th that of Earth s Winds around here can pick up speed but they don t pick up a lot of stuff Think fast but not strong Tweet Retrieved February 7 2023 via Twitter Foust Jeff December 18 2022 Perseverance prepares to deposit Mars sample cache SpaceNews Retrieved December 22 2022 mars nasa gov NASA s Perseverance Rover to Begin Building Martian Sample Depot NASA Mars Exploration Retrieved December 22 2022 mars nasa gov Sample Retrieval Lander NASA mars nasa gov Retrieved January 8 2023 a b mars nasa gov Mars Ascent Vehicle NASA mars nasa gov Retrieved January 8 2023 Gebhardt Chris June 2 2022 How Lockheed Martin NASA will send a rocket to Mars to launch samples off the planet to a waiting European Orbiter NASASpaceFlight com Retrieved January 9 2023 Gebhardt Chris June 4 2021 Mars Ascent Vehicle from Northrop Grumman takes shape for Mars Sample Return mission NASASpaceFlight com Retrieved January 9 2023 NASA Selects Developer for Rocket to Retrieve First Samples from Mars NASA Press Release 22 015 February 7 2022 February 7 2022 Retrieved July 2 2022 NASA Begins Testing Robotics to Bring First Samples Back From Mars NASA Jet Propulsion Laboratory JPL December 13 2021 Retrieved August 2 2022 a b Yaghoubi Darius Maynor Shawn Integrated Design Results for the MSR SRC Mars Ascent Vehicle PDF NASA Technical Reports Server Retrieved April 26 2022 identify this object What are these two little valve stem like projections from the Northrop Grumman STAR 15G upper stage rocket motor Why doesn t the STAR 20 have them Space Exploration Stack Exchange Retrieved December 22 2022 Airbus to bring first Mars samples to Earth ESA contract award Airbus www airbus com October 28 2021 Retrieved December 14 2021 a b Mission Concept Study Planetary Science Decadal Survey MSR Orbiter Mission Including Mars Returned Sample Handling PDF September 29 2015 Archived from the original PDF on September 29 2015 Retrieved December 25 2022 a b c mars nasa gov Earth Return Orbiter ESA NASA mars nasa gov Retrieved August 1 2023 Earth Return Orbiter the first round trip to Mars ESA April 7 2023 Retrieved April 8 2023 Kellas Sotiris March 2017 Passive earth entry vehicle landing test 2017 IEEE Aerospace Conference Big Sky MT USA IEEE pp 1 10 doi 10 1109 AERO 2017 7943744 hdl 2060 20170002221 ISBN 978 1 5090 1613 6 S2CID 24286971 Post NASA Eyes Sample Return Capability for Post 2020 Mars Orbiter Denver Museum of Nature amp Science August 31 2017 Archived from the original on August 31 2017 Retrieved December 25 2022 Gebhardt Chris Barker Nathan June 4 2021 Mars Ascent Vehicle from Northrop Grumman takes shape for Mars Sample Return mission NASASpaceFlight com Retrieved August 27 2021 Kahn Amina February 10 2020 NASA gives JPL green light for mission to bring a piece of Mars back to Earth Los Angeles Times Retrieved February 11 2020 Mission to Mars Mars Sample Return NASA 2020 Retrieved February 11 2020 nbsp This article incorporates text from this source which is in the public domain External links editMars Sample return media reel produced by NASA and JPL video Retrieved from https en wikipedia org w index php title NASA ESA Mars Sample Return amp oldid 1221738180, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.