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Laser Interferometer Space Antenna

May 12, 2024

The Laser Interferometer Space Antenna (LISA) is a planned space probe to detect and accurately measure gravitational waves[2]—tiny ripples in the fabric of spacetime—from astronomical sources.[3] LISA will be the first dedicated space-based gravitational-wave observatory. It aims to measure gravitational waves directly by using laser interferometry. The LISA concept has a constellation of three spacecraft arranged in an equilateral triangle with sides 2.5 million kilometres long, flying along an Earth-like heliocentric orbit. The distance between the satellites is precisely monitored to detect a passing gravitational wave.[2]

Laser Interferometer Space Antenna
Artist's conception of LISA spacecraft
Mission typeGravitational waves observation
OperatorESA
Websitewww.lisamission.org
Start of mission
Launch date2035 (planned)[1]
RocketAriane 6
Launch siteKourou ELA-4
ContractorArianespace
Orbital parameters
Reference systemHeliocentric
Semi-major axis1 AU
Period1 year
Epochplanned
← ATHENA
 

The LISA project started out as a joint effort between NASA and the European Space Agency (ESA). However, in 2011, NASA announced that it would be unable to continue its LISA partnership with the European Space Agency[4] due to funding limitations.[5] The project is a recognized CERN experiment (RE8).[6][7] A scaled-down design initially known as the New Gravitational-wave Observatory (NGO) was proposed as one of three large projects in ESA's long-term plans.[8] In 2013, ESA selected 'The Gravitational Universe' as the theme for one of its three large projects in the 2030s[9][10] whereby it committed to launch a space-based gravitational-wave observatory.

In January 2017, LISA was proposed as a candidate mission.[11] On June 20, 2017, the suggested mission received its clearance goal for the 2030s, and was approved as one of the main research missions of ESA.[12][13]

On 25 January 2024, the LISA Mission was formally adopted by ESA. This adoption recognises that the mission concept and technology are advanced enough that building the spacecraft and its instruments can commence.[14]

The LISA mission is designed for direct observation of gravitational waves, which are distortions of spacetime travelling at the speed of light. Passing gravitational waves alternately squeeze and stretch space itself by a tiny amount. Gravitational waves are caused by energetic events in the universe and, unlike any other radiation, can pass unhindered by intervening mass. Launching LISA will add a new sense to scientists' perception of the universe and enable them to study phenomena that are invisible in normal light.[15][16]

Potential sources for signals are merging massive black holes at the centre of galaxies,[17] massive black holes orbited by small compact objects, known as extreme mass ratio inspirals,[18] binaries of compact stars,[19] and possibly other sources of cosmological origin, such as a cosmological phase transition shortly after the Big Bang,[20] and speculative astrophysical objects like cosmic strings and domain boundaries.[21]

Mission description edit

 
LISA spacecraft orbitography and interferometer – yearly-periodic revolution in heliocentric orbit.

The LISA mission's primary objective is to detect and measure gravitational waves produced by compact binary systems and mergers of supermassive black holes. LISA will observe gravitational waves by measuring differential changes in the length of its arms, as sensed by laser interferometry.[22] Each of the three LISA spacecraft contains two telescopes, two lasers and two test masses (each a 46 mm, roughly 2 kg, gold-coated cube of gold/platinum), arranged in two optical assemblies pointed at the other two spacecraft.[11] These form Michelson-like interferometers, each centred on one of the spacecraft, with the test masses defining the ends of the arms.[23] The entire arrangement, which is ten times larger than the orbit of the Moon, will be placed in solar orbit at the same distance from the Sun as the Earth, but trailing the Earth by 20 degrees, and with the orbital planes of the three spacecraft inclined relative to the ecliptic by about 0.33 degree, which results in the plane of the triangular spacecraft formation being tilted 60 degrees from the plane of the ecliptic.[22] The mean linear distance between the formation and the Earth will be 50 million kilometres.[24]

To eliminate non-gravitational forces such as light pressure and solar wind on the test masses, each spacecraft is constructed as a zero-drag satellite. The test mass floats free inside, effectively in free-fall, while the spacecraft around it absorbs all these local non-gravitational forces. Then, using capacitive sensing to determine the spacecraft's position relative to the mass, very precise thrusters adjust the spacecraft so that it follows, keeping itself centered around the mass.[25]

Arm length edit

The longer the arms, the more sensitive the detector is to long-period gravitational waves, but its sensitivity to wavelengths shorter than the arms is reduced (2,500,000 km is 8.3 lightseconds, or 0.12 Hz [compare to LIGO's peak sensitivity around 500 Hz]). As the satellites are free-flying, the spacing is easily adjusted before launch, with upper bounds being imposed by the sizes of the telescopes required at each end of the interferometer (which are constrained by the size of the launch vehicle's payload fairing) and the stability of the constellation orbit (larger constellations are more sensitive to the gravitational effects of other planets, limiting the mission lifetime). Another length-dependent factor which must be compensated for is the "point-ahead angle" between the incoming and outgoing laser beams; the telescope must receive its incoming beam from where its partner was a few seconds ago, but send its outgoing beam to where its partner will be a few seconds from now.

The original 2008 LISA proposal had arms 5 million kilometres (5 Gm) long.[26] When downscoped to eLISA in 2013, arms of 1 million kilometres were proposed.[27] The approved 2017 LISA proposal has arms 2.5 million kilometres (2.5 Gm) long.[28][11]

Detection principle edit

 
View of amplified effects of a + polarized gravitational wave (stylized) on LISA laser beams / arms paths.

Like most modern gravitational wave-observatories, LISA is based on laser interferometry. Its three satellites form a giant Michelson interferometer in which two "transponder" satellites play the role of reflectors and one "master" satellite the roles of source and observer. When a gravitational wave passes the interferometer, the lengths of the two LISA arms vary due to spacetime distortions caused by the wave. Practically, LISA measures a relative phase shift between one local laser and one distant laser by light interference. Comparison between the observed laser beam frequency (in return beam) and the local laser beam frequency (sent beam) encodes the wave parameters. The principle of laser-interferometric inter-satellite ranging measurements was successfully implemented in the Laser Ranging Interferometer onboard GRACE Follow-On.[29]

Unlike terrestrial gravitational-wave observatories, LISA cannot keep its arms "locked" in position at a fixed length. Instead, the distances between satellites vary significantly over each year's orbit, and the detector must keep track of the constantly changing distance, counting the millions of wavelengths by which the distance changes each second. Then, the signals are separated in the frequency domain: changes with periods of less than a day are signals of interest, while changes with periods of a month or more are irrelevant.

This difference means that LISA cannot use high-finesse Fabry–Pérot resonant arm cavities and signal recycling systems like terrestrial detectors, limiting its length-measurement accuracy. But with arms almost a million times longer, the motions to be detected are correspondingly larger.

LISA Pathfinder edit

Main article: LISA Pathfinder

An ESA test mission called LISA Pathfinder (LPF) was launched in 2015 to test the technology necessary to put a test mass in (almost) perfect free fall conditions.[30] LPF consists of a single spacecraft with one of the LISA interferometer arms shortened to about 38 cm (15 in), so that it fits inside a single spacecraft. The spacecraft reached its operational location in heliocentric orbit at the Lagrange point L1 on 22 January 2016, where it underwent payload commissioning.[31] Scientific research started on March 8, 2016.[32] The goal of LPF was to demonstrate a noise level 10 times worse than needed for LISA. However, LPF exceeded this goal by a large margin, approaching the LISA requirement noise levels.[33]

Science goals edit

 
Detector noise curves for LISA and eLISA as a function of frequency. They lie in between the bands for ground-based detectors like Advanced LIGO (aLIGO) and pulsar timing arrays such as the European Pulsar Timing Array (EPTA). The characteristic strain of potential astrophysical sources are also shown. To be detectable the characteristic strain of a signal must be above the noise curve.[34]

Gravitational-wave astronomy seeks to use direct measurements of gravitational waves to study astrophysical systems and to test Einstein's theory of gravity. Indirect evidence of gravitational waves was derived from observations of the decreasing orbital periods of several binary pulsars, such as the Hulse–Taylor pulsar.[35] In February 2016, the Advanced LIGO project announced that it had directly detected gravitational waves from a black hole merger.[36][37][38]

Observing gravitational waves requires two things: a strong source of gravitational waves—such as the merger of two black holes—and extremely high detection sensitivity. A LISA-like instrument should be able to measure relative displacements with a resolution of 20 picometres—less than the diameter of a helium atom—over a distance of a million kilometres, yielding a strain sensitivity of better than 1 part in 1020 in the low-frequency band about a millihertz.

A LISA-like detector is sensitive to the low-frequency band of the gravitational-wave spectrum, which contains many astrophysically interesting sources.[39] Such a detector would observe signals from binary stars within our galaxy (the Milky Way);[40][41] signals from binary supermassive black holes in other galaxies;[42] and extreme-mass-ratio inspirals and bursts produced by a stellar-mass compact object orbiting a supermassive black hole.[43][44] There are also more speculative signals such as signals from cosmological phase transitions, cosmic strings and primordial gravitational waves generated during cosmological inflation.[45]

Galactic compact binaries edit

LISA will be able to detect the nearly monochromatic gravitational waves emanating of close binaries consisting of two compact stellar objects (white dwarfs, neutron stars, and black holes) in the Milky Way. At low frequencies these are actually expected to be so numerous that they form a source of (foreground) noise for LISA data analysis. At higher frequencies LISA is expected to detect and resolve around 25,000 galactic compact binaries. Studying the distribution of the masses, periods, and locations of this population, will teach us about the formation and evolution of binary systems in the galaxy. Furthermore, LISA will be able to resolve 10 binaries currently known from electromagnetic observations (and find ≈500 more with electromagnetic counterparts within one square degree). Joint study of these systems will allow inference on other dissipation mechanisms in these systems, e.g. through tidal interactions.[11] One of the currently known binaries that LISA will be able to resolve is the white dwarf binary ZTF J1539+5027 with a period of 6.91 minutes, the second shortest period binary white dwarf pair discovered to date.[46][47]

Massive black hole mergers edit

LISA will be able to detect the gravitational waves from the merger of a pair of massive black holes with a chirp mass between 104 and 107 solar masses all the way back to their earliest formation at redshift around z ≈ 10. The most conservative population models expect at least a few such events to happen each year. For mergers closer by (z < 3), it will be able to determine the spins of the components, which carry information about the past evolution of the components (e.g. whether they have grown primarily through accretion or mergers). For mergers around the peak of star formation (z ≈ 2) LISA will be able to locate mergers within 100 square degrees on the night sky at least 24 hours before the actual merger, allowing electromagnetic telescopes to search for counterparts, with the potential of witnessing the formation of a quasar after a merger.[11]

Extreme mass ratio inspirals edit

Main article: Extreme mass ratio inspiral

Extreme mass ratio inspirals (EMRIs) consist of a stellar compact object (<60 solar masses) on a slowly decaying orbit around a massive black hole of around 105 solar masses. For the ideal case of a prograde orbit around a (nearly) maximally spinning black hole, LISA will be able to detect these events up to z=4. EMRIs are interesting because they are slowly evolving, spending around 105 orbits and between a few months and a few years in the LISA sensitivity band before merging. This allows very accurate (up to an error of 1 in 104) measurements of the properties of the system, including the mass and spin of the central object and the mass and orbital elements (eccentricity and inclination) of the smaller object. EMRIs are expected to occur regularly in the centers of most galaxies and in dense star clusters. Conservative population estimates predict at least one detectable event per year for LISA.[11]

Intermediate mass black hole binaries edit

LISA will also be able to detect the gravitational waves emanating from black hole binary mergers where the lighter black hole is in the intermediate black hole range (between 102 and 104 solar masses). In the case of both components being intermediate black holes between 600 and 104 solar masses, LISA will be able to detect events up to redshifts around 1. In the case of an intermediate mass black hole spiralling into a massive black hole (between 104 and 106 solar masses) events will be detectable up to at least z=3. Since little is known about the population of intermediate mass black holes, there is no good estimate of the event rates for these events.[11]

Multi-band gravitational wave astronomy edit

Following the announcement of the first gravitational wave detection, GW150914, it was realized that a similar event would be detectable by LISA well before the merger.[48] Based on the LIGO estimated event rates, it is expected that LISA will detect and resolve about 100 binaries that would merge a few weeks to months later in the LIGO detection band. LISA will be able to accurately predict the time of merger ahead of time and locate the event with 1 square degree on the sky. This will greatly aid the possibilities for searches for electromagnetic counterpart events.[11]

Fundamental black hole physics edit

Gravitational wave signals from black holes could provide hints at a more fundamental theory of gravity.[11] LISA will be able to test possible modifications of Einstein's general theory of relativity, motivated by dark energy or dark matter.[49] These could manifest, for example, through modifications of the propagation of gravitational waves, or through the possibility of hairy black holes.[49]

Probe expansion of the universe edit

LISA will be able to independently measure the redshift and distance of events occurring relatively close by (z < 0.1) through the detection of massive black hole mergers and EMRIs. Consequently, it can make an independent measurement of the Hubble parameter H0 that does not depend on the use of the cosmic distance ladder. The accuracy of such a determination is limited by the sample size and therefore the mission duration. With a mission lifetime of 4 years one expects to be able to determine H0 with an absolute error of 0.01 (km/s)/Mpc. At larger ranges LISA events can (stochastically) be linked to electromagnetic counterparts, to further constrain the expansion curve of the universe.[11]

Gravitational wave background edit

LISA will be sensitive to the stochastic gravitational wave background generated in the early universe through various channels, including inflation, first-order cosmological phase transitions related to spontaneous symmetry breaking, and cosmic strings.[11]

Exotic sources edit

LISA will also search for currently unknown (and unmodelled) sources of gravitational waves. The history of astrophysics has shown that whenever a new frequency range/medium of detection is available new unexpected sources show up. This could for example include kinks and cusps in cosmic strings.[11]

Memory effects edit

LISA will be sensitive to the permanent displacement induced on probe masses by gravitational waves, known as gravitational memory effect. [50]

Other gravitational-wave experiments edit

 
Simplified operation of a gravitational wave observatory
Figure 1: A beamsplitter (green line) splits coherent light (from the white box) into two beams which reflect off the mirrors (cyan oblongs); only one outgoing and reflected beam in each arm is shown, and separated for clarity. The reflected beams recombine and an interference pattern is detected (purple circle).
Figure 2: A gravitational wave passing over the left arm (yellow) changes its length and thus the interference pattern.

Previous searches for gravitational waves in space were conducted for short periods by planetary missions that had other primary science objectives (such as Cassini–Huygens), using microwave Doppler tracking to monitor fluctuations in the Earth–spacecraft distance. By contrast, LISA is a dedicated mission that will use laser interferometry to achieve a much higher sensitivity.[citation needed] Other gravitational wave antennas, such as LIGO, Virgo, and GEO600, are already in operation on Earth, but their sensitivity at low frequencies is limited by the largest practical arm lengths, by seismic noise, and by interference from nearby moving masses. Conversely, NANOGrav measures frequencies too low for LISA. The different types of gravitational wave measurement systems — LISA, NANOGrav and ground-based detectors — are complementary rather than competitive, much like astronomical observatories in different electromagnetic bands (e.g., ultraviolet and infrared).[51]

History edit

The first design studies for a gravitational-wave detector to be flown in space were performed in the 1980s under the name LAGOS (Laser Antena for Gravitational radiation Observation in Space). LISA was first proposed as a mission to ESA in the early 1990s. First as a candidate for the M3-cycle, and later as 'cornerstone mission' for the 'Horizon 2000 plus' program. As the decade progressed, the design was refined to a triangular configuration of three spacecraft with three 5-million-kilometre arms. This mission was pitched as a joint mission between ESA and NASA in 1997.[52][53]

In the 2000s the joint ESA/NASA LISA mission was identified as a candidate for the 'L1' slot in ESA's Cosmic Vision 2015–2025 programme. However, due to budget cuts, NASA announced in early 2011 that it would not be contributing to any of ESA's L-class missions. ESA nonetheless decided to push the program forward, and instructed the L1 candidate missions to present reduced cost versions that could be flown within ESA's budget. A reduced version of LISA was designed with only two 1-million-kilometre arms under the name NGO (New/Next Gravitational wave Observatory). Despite NGO being ranked highest in terms of scientific potential, ESA decided to fly Jupiter Icy Moons Explorer (JUICE) as its L1 mission. One of the main concerns was that the LISA Pathfinder mission had been experiencing technical delays, making it uncertain if the technology would be ready for the projected L1 launch date.[52][53]

Soon afterwards, ESA announced it would be selecting themes for its Large class L2 and L3 mission slots. A theme called "the Gravitational Universe" was formulated with the reduced NGO rechristened eLISA as a straw-man mission.[54] In November 2013, ESA announced that it selected "the Gravitational Universe" for its L3 mission slot (expected launch in 2034).[55] Following the successful detection of gravitational waves by the LIGO, ground-based detectors in September 2015, NASA expressed interest in rejoining the mission as a junior partner. In response to an ESA call for mission proposals for the `Gravitational Universe' themed L3 mission,[56] a mission proposal for a detector with three 2.5-million-kilometre arms again called LISA was submitted in January 2017.[11]

As of January 2024, LISA is expected to launch in 2035 on an Ariane 6,[1] two years earlier than previously announced.[57]

See also edit

 
Wikimedia Commons has media related to Laser Interferometer Space Antenna.

References edit

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External links edit

  • "eLISA Consortium portal". Retrieved 2013-11-13.
  • "ESA LISA homepage". Retrieved 2010-08-13.
  • "LISA Pathfinder mission". Retrieved 2013-05-22.
  • . Archived from the original on 2010-07-21. Retrieved 2010-08-13.
  • "NASA LISA homepage". Retrieved 2010-08-13.

May 12, 2024
laser, interferometer, space, antenna, lisa, planned, space, probe, detect, accurately, measure, gravitational, waves, tiny, ripples, fabric, spacetime, from, astronomical, sources, lisa, will, first, dedicated, space, based, gravitational, wave, observatory, . The Laser Interferometer Space Antenna LISA is a planned space probe to detect and accurately measure gravitational waves 2 tiny ripples in the fabric of spacetime from astronomical sources 3 LISA will be the first dedicated space based gravitational wave observatory It aims to measure gravitational waves directly by using laser interferometry The LISA concept has a constellation of three spacecraft arranged in an equilateral triangle with sides 2 5 million kilometres long flying along an Earth like heliocentric orbit The distance between the satellites is precisely monitored to detect a passing gravitational wave 2 Laser Interferometer Space AntennaArtist s conception of LISA spacecraftMission typeGravitational waves observationOperatorESAWebsitewww wbr lisamission wbr orgStart of missionLaunch date2035 planned 1 RocketAriane 6Launch siteKourou ELA 4ContractorArianespaceOrbital parametersReference systemHeliocentricSemi major axis1 AUPeriod1 yearEpochplannedCosmic Vision ATHENA The LISA project started out as a joint effort between NASA and the European Space Agency ESA However in 2011 NASA announced that it would be unable to continue its LISA partnership with the European Space Agency 4 due to funding limitations 5 The project is a recognized CERN experiment RE8 6 7 A scaled down design initially known as the New Gravitational wave Observatory NGO was proposed as one of three large projects in ESA s long term plans 8 In 2013 ESA selected The Gravitational Universe as the theme for one of its three large projects in the 2030s 9 10 whereby it committed to launch a space based gravitational wave observatory In January 2017 LISA was proposed as a candidate mission 11 On June 20 2017 the suggested mission received its clearance goal for the 2030s and was approved as one of the main research missions of ESA 12 13 On 25 January 2024 the LISA Mission was formally adopted by ESA This adoption recognises that the mission concept and technology are advanced enough that building the spacecraft and its instruments can commence 14 The LISA mission is designed for direct observation of gravitational waves which are distortions of spacetime travelling at the speed of light Passing gravitational waves alternately squeeze and stretch space itself by a tiny amount Gravitational waves are caused by energetic events in the universe and unlike any other radiation can pass unhindered by intervening mass Launching LISA will add a new sense to scientists perception of the universe and enable them to study phenomena that are invisible in normal light 15 16 Potential sources for signals are merging massive black holes at the centre of galaxies 17 massive black holes orbited by small compact objects known as extreme mass ratio inspirals 18 binaries of compact stars 19 and possibly other sources of cosmological origin such as a cosmological phase transition shortly after the Big Bang 20 and speculative astrophysical objects like cosmic strings and domain boundaries 21 Contents 1 Mission description 1 1 Arm length 2 Detection principle 3 LISA Pathfinder 4 Science goals 4 1 Galactic compact binaries 4 2 Massive black hole mergers 4 3 Extreme mass ratio inspirals 4 4 Intermediate mass black hole binaries 4 5 Multi band gravitational wave astronomy 4 6 Fundamental black hole physics 4 7 Probe expansion of the universe 4 8 Gravitational wave background 4 9 Exotic sources 4 10 Memory effects 5 Other gravitational wave experiments 6 History 7 See also 8 References 9 External linksMission description edit nbsp LISA spacecraft orbitography and interferometer yearly periodic revolution in heliocentric orbit The LISA mission s primary objective is to detect and measure gravitational waves produced by compact binary systems and mergers of supermassive black holes LISA will observe gravitational waves by measuring differential changes in the length of its arms as sensed by laser interferometry 22 Each of the three LISA spacecraft contains two telescopes two lasers and two test masses each a 46 mm roughly 2 kg gold coated cube of gold platinum arranged in two optical assemblies pointed at the other two spacecraft 11 These form Michelson like interferometers each centred on one of the spacecraft with the test masses defining the ends of the arms 23 The entire arrangement which is ten times larger than the orbit of the Moon will be placed in solar orbit at the same distance from the Sun as the Earth but trailing the Earth by 20 degrees and with the orbital planes of the three spacecraft inclined relative to the ecliptic by about 0 33 degree which results in the plane of the triangular spacecraft formation being tilted 60 degrees from the plane of the ecliptic 22 The mean linear distance between the formation and the Earth will be 50 million kilometres 24 To eliminate non gravitational forces such as light pressure and solar wind on the test masses each spacecraft is constructed as a zero drag satellite The test mass floats free inside effectively in free fall while the spacecraft around it absorbs all these local non gravitational forces Then using capacitive sensing to determine the spacecraft s position relative to the mass very precise thrusters adjust the spacecraft so that it follows keeping itself centered around the mass 25 Arm length edit The longer the arms the more sensitive the detector is to long period gravitational waves but its sensitivity to wavelengths shorter than the arms is reduced 2 500 000 km is 8 3 lightseconds or 0 12 Hz compare to LIGO s peak sensitivity around 500 Hz As the satellites are free flying the spacing is easily adjusted before launch with upper bounds being imposed by the sizes of the telescopes required at each end of the interferometer which are constrained by the size of the launch vehicle s payload fairing and the stability of the constellation orbit larger constellations are more sensitive to the gravitational effects of other planets limiting the mission lifetime Another length dependent factor which must be compensated for is the point ahead angle between the incoming and outgoing laser beams the telescope must receive its incoming beam from where its partner was a few seconds ago but send its outgoing beam to where its partner will be a few seconds from now The original 2008 LISA proposal had arms 5 million kilometres 5 Gm long 26 When downscoped to eLISA in 2013 arms of 1 million kilometres were proposed 27 The approved 2017 LISA proposal has arms 2 5 million kilometres 2 5 Gm long 28 11 Detection principle edit nbsp View of amplified effects of a polarized gravitational wave stylized on LISA laser beams arms paths Like most modern gravitational wave observatories LISA is based on laser interferometry Its three satellites form a giant Michelson interferometer in which two transponder satellites play the role of reflectors and one master satellite the roles of source and observer When a gravitational wave passes the interferometer the lengths of the two LISA arms vary due to spacetime distortions caused by the wave Practically LISA measures a relative phase shift between one local laser and one distant laser by light interference Comparison between the observed laser beam frequency in return beam and the local laser beam frequency sent beam encodes the wave parameters The principle of laser interferometric inter satellite ranging measurements was successfully implemented in the Laser Ranging Interferometer onboard GRACE Follow On 29 Unlike terrestrial gravitational wave observatories LISA cannot keep its arms locked in position at a fixed length Instead the distances between satellites vary significantly over each year s orbit and the detector must keep track of the constantly changing distance counting the millions of wavelengths by which the distance changes each second Then the signals are separated in the frequency domain changes with periods of less than a day are signals of interest while changes with periods of a month or more are irrelevant This difference means that LISA cannot use high finesse Fabry Perot resonant arm cavities and signal recycling systems like terrestrial detectors limiting its length measurement accuracy But with arms almost a million times longer the motions to be detected are correspondingly larger LISA Pathfinder editMain article LISA Pathfinder An ESA test mission called LISA Pathfinder LPF was launched in 2015 to test the technology necessary to put a test mass in almost perfect free fall conditions 30 LPF consists of a single spacecraft with one of the LISA interferometer arms shortened to about 38 cm 15 in so that it fits inside a single spacecraft The spacecraft reached its operational location in heliocentric orbit at the Lagrange point L1 on 22 January 2016 where it underwent payload commissioning 31 Scientific research started on March 8 2016 32 The goal of LPF was to demonstrate a noise level 10 times worse than needed for LISA However LPF exceeded this goal by a large margin approaching the LISA requirement noise levels 33 Science goals edit nbsp Detector noise curves for LISA and eLISA as a function of frequency They lie in between the bands for ground based detectors like Advanced LIGO aLIGO and pulsar timing arrays such as the European Pulsar Timing Array EPTA The characteristic strain of potential astrophysical sources are also shown To be detectable the characteristic strain of a signal must be above the noise curve 34 Gravitational wave astronomy seeks to use direct measurements of gravitational waves to study astrophysical systems and to test Einstein s theory of gravity Indirect evidence of gravitational waves was derived from observations of the decreasing orbital periods of several binary pulsars such as the Hulse Taylor pulsar 35 In February 2016 the Advanced LIGO project announced that it had directly detected gravitational waves from a black hole merger 36 37 38 Observing gravitational waves requires two things a strong source of gravitational waves such as the merger of two black holes and extremely high detection sensitivity A LISA like instrument should be able to measure relative displacements with a resolution of 20 picometres less than the diameter of a helium atom over a distance of a million kilometres yielding a strain sensitivity of better than 1 part in 1020 in the low frequency band about a millihertz A LISA like detector is sensitive to the low frequency band of the gravitational wave spectrum which contains many astrophysically interesting sources 39 Such a detector would observe signals from binary stars within our galaxy the Milky Way 40 41 signals from binary supermassive black holes in other galaxies 42 and extreme mass ratio inspirals and bursts produced by a stellar mass compact object orbiting a supermassive black hole 43 44 There are also more speculative signals such as signals from cosmological phase transitions cosmic strings and primordial gravitational waves generated during cosmological inflation 45 Galactic compact binaries edit LISA will be able to detect the nearly monochromatic gravitational waves emanating of close binaries consisting of two compact stellar objects white dwarfs neutron stars and black holes in the Milky Way At low frequencies these are actually expected to be so numerous that they form a source of foreground noise for LISA data analysis At higher frequencies LISA is expected to detect and resolve around 25 000 galactic compact binaries Studying the distribution of the masses periods and locations of this population will teach us about the formation and evolution of binary systems in the galaxy Furthermore LISA will be able to resolve 10 binaries currently known from electromagnetic observations and find 500 more with electromagnetic counterparts within one square degree Joint study of these systems will allow inference on other dissipation mechanisms in these systems e g through tidal interactions 11 One of the currently known binaries that LISA will be able to resolve is the white dwarf binary ZTF J1539 5027 with a period of 6 91 minutes the second shortest period binary white dwarf pair discovered to date 46 47 Massive black hole mergers edit LISA will be able to detect the gravitational waves from the merger of a pair of massive black holes with a chirp mass between 104 and 107 solar masses all the way back to their earliest formation at redshift around z 10 The most conservative population models expect at least a few such events to happen each year For mergers closer by z lt 3 it will be able to determine the spins of the components which carry information about the past evolution of the components e g whether they have grown primarily through accretion or mergers For mergers around the peak of star formation z 2 LISA will be able to locate mergers within 100 square degrees on the night sky at least 24 hours before the actual merger allowing electromagnetic telescopes to search for counterparts with the potential of witnessing the formation of a quasar after a merger 11 Extreme mass ratio inspirals edit Main article Extreme mass ratio inspiral Extreme mass ratio inspirals EMRIs consist of a stellar compact object lt 60 solar masses on a slowly decaying orbit around a massive black hole of around 105 solar masses For the ideal case of a prograde orbit around a nearly maximally spinning black hole LISA will be able to detect these events up to z 4 EMRIs are interesting because they are slowly evolving spending around 105 orbits and between a few months and a few years in the LISA sensitivity band before merging This allows very accurate up to an error of 1 in 104 measurements of the properties of the system including the mass and spin of the central object and the mass and orbital elements eccentricity and inclination of the smaller object EMRIs are expected to occur regularly in the centers of most galaxies and in dense star clusters Conservative population estimates predict at least one detectable event per year for LISA 11 Intermediate mass black hole binaries edit LISA will also be able to detect the gravitational waves emanating from black hole binary mergers where the lighter black hole is in the intermediate black hole range between 102 and 104 solar masses In the case of both components being intermediate black holes between 600 and 104 solar masses LISA will be able to detect events up to redshifts around 1 In the case of an intermediate mass black hole spiralling into a massive black hole between 104 and 106 solar masses events will be detectable up to at least z 3 Since little is known about the population of intermediate mass black holes there is no good estimate of the event rates for these events 11 Multi band gravitational wave astronomy edit Following the announcement of the first gravitational wave detection GW150914 it was realized that a similar event would be detectable by LISA well before the merger 48 Based on the LIGO estimated event rates it is expected that LISA will detect and resolve about 100 binaries that would merge a few weeks to months later in the LIGO detection band LISA will be able to accurately predict the time of merger ahead of time and locate the event with 1 square degree on the sky This will greatly aid the possibilities for searches for electromagnetic counterpart events 11 Fundamental black hole physics edit Gravitational wave signals from black holes could provide hints at a more fundamental theory of gravity 11 LISA will be able to test possible modifications of Einstein s general theory of relativity motivated by dark energy or dark matter 49 These could manifest for example through modifications of the propagation of gravitational waves or through the possibility of hairy black holes 49 Probe expansion of the universe edit LISA will be able to independently measure the redshift and distance of events occurring relatively close by z lt 0 1 through the detection of massive black hole mergers and EMRIs Consequently it can make an independent measurement of the Hubble parameter H0 that does not depend on the use of the cosmic distance ladder The accuracy of such a determination is limited by the sample size and therefore the mission duration With a mission lifetime of 4 years one expects to be able to determine H0 with an absolute error of 0 01 km s Mpc At larger ranges LISA events can stochastically be linked to electromagnetic counterparts to further constrain the expansion curve of the universe 11 Gravitational wave background edit LISA will be sensitive to the stochastic gravitational wave background generated in the early universe through various channels including inflation first order cosmological phase transitions related to spontaneous symmetry breaking and cosmic strings 11 Exotic sources edit LISA will also search for currently unknown and unmodelled sources of gravitational waves The history of astrophysics has shown that whenever a new frequency range medium of detection is available new unexpected sources show up This could for example include kinks and cusps in cosmic strings 11 Memory effects edit LISA will be sensitive to the permanent displacement induced on probe masses by gravitational waves known as gravitational memory effect 50 Other gravitational wave experiments edit nbsp Simplified operation of a gravitational wave observatory Figure 1 A beamsplitter green line splits coherent light from the white box into two beams which reflect off the mirrors cyan oblongs only one outgoing and reflected beam in each arm is shown and separated for clarity The reflected beams recombine and an interference pattern is detected purple circle Figure 2 A gravitational wave passing over the left arm yellow changes its length and thus the interference pattern Previous searches for gravitational waves in space were conducted for short periods by planetary missions that had other primary science objectives such as Cassini Huygens using microwave Doppler tracking to monitor fluctuations in the Earth spacecraft distance By contrast LISA is a dedicated mission that will use laser interferometry to achieve a much higher sensitivity citation needed Other gravitational wave antennas such as LIGO Virgo and GEO600 are already in operation on Earth but their sensitivity at low frequencies is limited by the largest practical arm lengths by seismic noise and by interference from nearby moving masses Conversely NANOGrav measures frequencies too low for LISA The different types of gravitational wave measurement systems LISA NANOGrav and ground based detectors are complementary rather than competitive much like astronomical observatories in different electromagnetic bands e g ultraviolet and infrared 51 History editThe first design studies for a gravitational wave detector to be flown in space were performed in the 1980s under the name LAGOS Laser Antena for Gravitational radiation Observation in Space LISA was first proposed as a mission to ESA in the early 1990s First as a candidate for the M3 cycle and later as cornerstone mission for the Horizon 2000 plus program As the decade progressed the design was refined to a triangular configuration of three spacecraft with three 5 million kilometre arms This mission was pitched as a joint mission between ESA and NASA in 1997 52 53 In the 2000s the joint ESA NASA LISA mission was identified as a candidate for the L1 slot in ESA s Cosmic Vision 2015 2025 programme However due to budget cuts NASA announced in early 2011 that it would not be contributing to any of ESA s L class missions ESA nonetheless decided to push the program forward and instructed the L1 candidate missions to present reduced cost versions that could be flown within ESA s budget A reduced version of LISA was designed with only two 1 million kilometre arms under the name NGO New Next Gravitational wave Observatory Despite NGO being ranked highest in terms of scientific potential ESA decided to fly Jupiter Icy Moons Explorer JUICE as its L1 mission One of the main concerns was that the LISA Pathfinder mission had been experiencing technical delays making it uncertain if the technology would be ready for the projected L1 launch date 52 53 Soon afterwards ESA announced it would be selecting themes for its Large class L2 and L3 mission slots A theme called the Gravitational Universe was formulated with the reduced NGO rechristened eLISA as a straw man mission 54 In November 2013 ESA announced that it selected the Gravitational Universe for its L3 mission slot expected launch in 2034 55 Following the successful detection of gravitational waves by the LIGO ground based detectors in September 2015 NASA expressed interest in rejoining the mission as a junior partner In response to an ESA call for mission proposals for the Gravitational Universe themed L3 mission 56 a mission proposal for a detector with three 2 5 million kilometre arms again called LISA was submitted in January 2017 11 As of January 2024 LISA is expected to launch in 2035 on an Ariane 6 1 two years earlier than previously announced 57 See also edit nbsp Wikimedia Commons has media related to Laser Interferometer Space Antenna Beyond Einstein program NASA Big Bang Observer proposed LISA successor Cosmic Vision program ESA Deci hertz Interferometer Gravitational wave Observatory DECIGO proposed Japanese space based gravitational wave observatoryReferences edit a b Capturing the ripples of spacetime LISA gets go ahead ESA 25 January 2024 Retrieved 25 January 2024 a b eLISA The First Gravitational Wave Observatory in Space eLISA Consortium Archived from the original on 5 December 2013 Retrieved 12 November 2013 eLISA Partners and Contacts eLISA Consortium Archived from the original on 5 December 2013 Retrieved 12 November 2013 LISA on the NASA website NASA Retrieved 12 November 2013 President s FY12 Budget Request NASA US Federal Government Archived from the original on 2011 03 03 Retrieved 4 Mar 2011 Recognized Experiments at CERN The CERN Scientific Committees CERN Archived from the original on 13 June 2019 Retrieved 21 January 2020 RE8 LISA The Laser Interferometer Space Antenna The CERN Experimental Programme CERN Retrieved 21 January 2020 Amaro Seoane Pau Aoudia Sofiane Babak Stanislav Binetruy Pierre Berti Emanuele Bohe Alejandro Caprini Chiara Colpi Monica Cornish Neil J Danzmann Karsten Dufaux Jean Francois Gair Jonathan Jennrich Oliver Jetzer Philippe Klein Antoine Lang Ryan N Lobo Alberto Littenberg Tyson McWilliams Sean T Nelemans Gijs Petiteau Antoine Porter Edward K Schutz Bernard F Sesana Alberto Stebbins Robin Sumner Tim Vallisneri Michele Vitale Stefano Volonteri Marta Ward Henry 21 June 2012 Low frequency gravitational wave science with eLISA NGO Classical and Quantum Gravity 29 12 124016 arXiv 1202 0839 Bibcode 2012CQGra 29l4016A doi 10 1088 0264 9381 29 12 124016 S2CID 54822413 Selected The Gravitational Universe ESA decides on next Large Mission Concepts Archived 2016 10 03 at the Wayback Machine ESA s new vision to study the invisible universe ESA Retrieved 29 November 2013 a b c d e f g h i j k l m LISA Laser Interferometer Space Antenna PDF LISA Consortium 20 January 2017 Retrieved 14 January 2018 Europe selects grand gravity mission BBC News 20 June 2017 Gravitational wave mission selected planet hunting mission moves forward 20 June 2017 Retrieved 20 June 2017 Capturing the ripples of spacetime LISA gets go ahead ESA European Space Agency Retrieved 29 January 2024 eLISA Science Context 2028 eLISA Consortium Archived from the original on 21 October 2014 Retrieved 15 November 2013 Gravitational Wave Detetectors Get Ready to Hunt for the Big Bang Scientific American 17 September 2013 See sect 5 2 in Amaro Seoane Pau Aoudia Sofiane Babak Stanislav Binetruy Pierre Berti Emanuele Bohe Alejandro Caprini Chiara Colpi Monica Cornish Neil J Danzmann Karsten Dufaux Jean Francois Gair Jonathan Jennrich Oliver Jetzer Philippe Klein Antoine Lang Ryan N Lobo Alberto Littenberg Tyson McWilliams Sean T Nelemans Gijs Petiteau Antoine Porter Edward K Schutz Bernard F Sesana Alberto Stebbins Robin Sumner Tim Vallisneri Michele Vitale Stefano Volonteri Marta Ward Henry 17 Jan 2012 ELISA Astrophysics and cosmology in the millihertz regime GW Notes 6 4 arXiv 1201 3621 Bibcode 2013GWN 6 4A See sect 4 3 in Amaro Seoane Pau Aoudia Sofiane Babak Stanislav Binetruy Pierre Berti Emanuele Bohe Alejandro Caprini Chiara Colpi Monica Cornish Neil J Danzmann Karsten Dufaux Jean Francois Gair Jonathan Jennrich Oliver Jetzer Philippe Klein Antoine Lang Ryan N Lobo Alberto Littenberg Tyson McWilliams Sean T Nelemans Gijs Petiteau Antoine Porter Edward K Schutz Bernard F Sesana Alberto Stebbins Robin Sumner Tim Vallisneri Michele Vitale Stefano Volonteri Marta Ward Henry 17 Jan 2012 ELISA Astrophysics and cosmology in the millihertz regime GW Notes 6 4 arXiv 1201 3621 Bibcode 2013GWN 6 4A See sect 3 3 in Amaro Seoane Pau Aoudia Sofiane Babak Stanislav Binetruy Pierre Berti Emanuele Bohe Alejandro Caprini Chiara Colpi Monica Cornish Neil J Danzmann Karsten Dufaux Jean Francois Gair Jonathan Jennrich Oliver Jetzer Philippe Klein Antoine Lang Ryan N Lobo Alberto Littenberg Tyson McWilliams Sean T Nelemans Gijs Petiteau Antoine Porter Edward K Schutz Bernard F Sesana Alberto Stebbins Robin Sumner Tim Vallisneri Michele Vitale Stefano Volonteri Marta Ward Henry 17 Jan 2012 ELISA Astrophysics and cosmology in the millihertz regime GW Notes 6 4 arXiv 1201 3621 Bibcode 2013GWN 6 4A See sect 7 2 in Amaro Seoane Pau Aoudia Sofiane Babak Stanislav Binetruy Pierre Berti Emanuele Bohe Alejandro Caprini Chiara Colpi Monica Cornish Neil J Danzmann Karsten Dufaux Jean Francois Gair Jonathan Jennrich Oliver Jetzer Philippe Klein Antoine Lang Ryan N Lobo Alberto Littenberg Tyson McWilliams Sean T Nelemans Gijs Petiteau Antoine Porter Edward K Schutz Bernard F Sesana Alberto Stebbins Robin Sumner Tim Vallisneri Michele Vitale Stefano Volonteri Marta Ward Henry 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