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Near-Earth object

February 08, 2023

A near-Earth object (NEO) is any small Solar System body whose orbit brings it into proximity with Earth. By convention, a Solar System body is a NEO if its closest approach to the Sun (perihelion) is less than 1.3 astronomical units (AU).[2] If a NEO's orbit crosses the Earth's orbit, and the object is larger than 140 meters (460 ft) across, it is considered a potentially hazardous object (PHO).[3] Most known PHOs and NEOs are asteroids, but a small fraction are comets.[1]

Radar-imaging of (388188) 2006 DP14 by a DSN antenna
Very Large Telescope image of the very faint near-Earth asteroid 2009 FD as seen by the VLT telescope
Near-Earth comet 103P/Hartley as seen by NASA's Deep Impact probe

27,000+ known NEOs, divided into several orbital subgroups[1]

  Apollos: 15142 (55.35%)
  Amors: 9963 (36.42%)
  Atens: 2107 (7.70%)
  Comets: 117 (0.43%)
  Atiras: 27 (0.099%)
  ꞌAylóꞌchaxnims: 1 (0.004%)

There are over 30,503 known near-Earth asteroids (NEAs) and over a hundred known short-period near-Earth comets (NECs).[1] A number of solar-orbiting meteoroids were large enough to be tracked in space before striking the Earth. It is now widely accepted that collisions in the past have had a significant role in shaping the geological and biological history of the Earth.[4] Asteroids as small as 20 metres (66 ft) in diameter can cause significant damage to the local environment and human populations.[5] Larger asteroids penetrate the atmosphere to the surface of the Earth, producing craters if they impact a continent or tsunamis if they impact the sea. Interest in NEOs has increased since the 1980s because of greater awareness of this potential danger. Asteroid impact avoidance by deflection is possible in principle, and methods of mitigation are being researched.[6]

Two scales, the simple Torino scale and the more complex Palermo scale, rate the risk presented by an identified NEO based on the probability of it impacting the Earth and on how severe the consequences of such an impact would be. Some NEOs have had temporarily positive Torino or Palermo scale ratings after their discovery.

Since 1998, the United States, the European Union, and other nations are scanning the sky for NEOs in an effort called Spaceguard.[7] The initial US Congress mandate to NASA to catalog at least 90% of NEOs that are at least 1 kilometre (3,300 ft) in diameter, sufficient to cause a global catastrophe, was met by 2011.[8] In later years, the survey effort was expanded[9] to include smaller objects[10] which have the potential for large-scale, though not global, damage.

NEOs have low surface gravity, and many have Earth-like orbits that make them easy targets for spacecraft.[11][12] As of January 2019, five near-Earth comets[13][14][15] and five near-Earth asteroids have been visited by spacecraft.[16][17][18][19][20] A small sample of one NEO was returned to Earth in 2010, and similar missions are in progress.[19][20] Preliminary plans for commercial asteroid mining have been drafted by private startup companies, either through the use of robots or even by sending private commercial astronauts to act as space miners.[21]

Definitions

 
Plot of orbits of known potentially hazardous asteroids (size over 140 m (460 ft) and passing within 7.6×10^6 km (4.7×10^6 mi) of Earth's orbit) as of early 2013 (alternate image)

Near-Earth objects (NEOs) are by convention technically defined as all small Solar System bodies with orbits around the Sun that lie partly between 0.983 and 1.3 astronomical units (AU; Sun–Earth distance) away from the Sun.[22][23] NEOs are thus not necessarily currently near the Earth, but they can potentially approach the Earth relatively closely. The term is also sometimes used more flexibly, for example for objects in orbit around the Earth or for quasi-satellites,[24] which have a more complex orbital relationship with the Earth.

When a NEO is detected, like all other small Solar System bodies, its positions and brightness are submitted to the International Astronomical Union's (IAU's) Minor Planet Center (MPC) for cataloging. The MPC maintains separate lists of confirmed NEOs and potential NEOs.[25][26] The orbits of some NEOs intersect that of the Earth, so they pose a collision danger.[3] These are considered potentially hazardous objects (PHOs) if their estimated diameter is above 140 meters. The MPC maintains a separate list for the asteroids among PHOs, the potentially hazardous asteroids (PHAs).[27] NEOs are also catalogued by two separate units of the Jet Propulsion Laboratory (JPL) of the National Aeronautics and Space Administration (NASA): the Center for Near Earth Object Studies (CNEOS)[28] and the Solar System Dynamics Group.[29]

PHAs are defined based on two parameters relating to respectively their potential to approach the Earth dangerously closely and the estimated consequences that an impact would have if it occurs.[2] Objects with both an Earth minimum orbit intersection distance (MOID) of 0.05 AU or less and an absolute magnitude of 22.0 or brighter (a rough indicator of large size) are considered PHAs. Objects that either cannot approach closer to the Earth i.e. MOID greater than 0.05 AU (7,500,000 km; 4,600,000 mi), or which are fainter than H = 22.0 (about 140 m (460 ft) in diameter with assumed albedo of 14%), are not considered PHAs.[2] NASA's catalog of near-Earth objects includes the approach distances of asteroids and comets (expressed in lunar distances).[30]

History of human awareness of NEOs

 
1910 drawing of the path of Halley's Comet
 
The near Earth asteroid 433 Eros was visited by a probe in the 1990s

The first near-Earth objects to be observed by humans were comets. Their extraterrestrial nature was recognised and confirmed only after Tycho Brahe tried to measure the distance of a comet through its parallax in 1577 and the lower limit he obtained was well above the Earth diameter; the periodicity of some comets was first recognised in 1705, when Edmond Halley published his orbit calculations for the returning object now known as Halley's Comet.[31] The 1758–1759 return of Halley's Comet was the first comet appearance predicted.[32] It has been said that Lexell's comet of 1770 was the first discovered Near-Earth object.[33]

The first near-Earth asteroid to be discovered was 433 Eros in 1898.[34] The asteroid was subject to several extensive observation campaigns, primarily because measurements of its orbit enabled a precise determination of the then imperfectly known distance of the Earth from the Sun.[35]

In 1937, asteroid 69230 Hermes was discovered when it passed the Earth at twice the distance of the Moon.[36] Hermes was considered a threat because it was lost after its discovery; thus its orbit and potential for collision with Earth were not known precisely.[37] Hermes was only re-discovered in 2003, and it is now known to be no threat for at least the next century.[36]

On June 14, 1968, the 1.4 km diameter asteroid 1566 Icarus passed Earth at a distance of 0.042 AU (6,300,000 km), or 16 times the distance of the Moon.[38] During this approach, Icarus became the first minor planet to be observed using radar, with measurements obtained at the Haystack Observatory[39] and the Goldstone Tracking Station.[40] This was the first close approach predicted years in advance (Icarus had been discovered in 1949), and also earned significant public attention, due to alarmist news reports.[37] A year before the approach, MIT students launched Project Icarus, devising a plan to deflect the asteroid with rockets in case it was found to be on a collision course with Earth.[41] Project Icarus received wide media coverage, and inspired the 1979 disaster movie Meteor, in which the US and the USSR join forces to blow up an Earth-bound fragment of an asteroid hit by a comet.[42]

On March 23, 1989, the 300 m (980 ft) diameter Apollo asteroid 4581 Asclepius (1989 FC) missed the Earth by 700,000 km (430,000 mi). If the asteroid had impacted it would have created the largest explosion in recorded history, equivalent to 20,000 megatons of TNT. It attracted widespread attention because it was discovered only after the closest approach.[43]

In March 1998, early orbit calculations for recently discovered asteroid (35396) 1997 XF11 showed a potential 2028 close approach 0.00031 AU (46,000 km) from the Earth, well within the orbit of the Moon, but with a large error margin allowing for a direct hit. Further data allowed a revision of the 2028 approach distance to 0.0064 AU (960,000 km), with no chance of collision. By that time, inaccurate reports of a potential impact had caused a media storm.[37]

 
Known asteroids – as of January 2018
Video (0:55; July 23, 2018)

Risk

 
Asteroid 4179 Toutatis is a potentially hazardous object that passed within 4 lunar distances in September 2004 and currently has a minimum possible distance of 2.5 lunar distances.

From the late 1990s, a typical frame of reference in searches for NEOs has been the scientific concept of risk. The risk that any near-Earth object poses is viewed having regard to both the culture and the technology of human society. Through history, humans have associated NEOs with changing risks, based on religious, philosophical or scientific views, as well as humanity's technological or economical capability to deal with such risks.[6] Thus, NEOs have been seen as omens of natural disasters or wars; harmless spectacles in an unchanging universe; the source of era-changing cataclysms[6] or potentially poisonous fumes (during Earth's passage through the tail of Halley's Comet in 1910);[44] and finally as a possible cause of a crater-forming impact that could even cause extinction of humans and other life on Earth.[6]

The potential of catastrophic impacts by near-Earth comets was recognised as soon as the first orbit calculations provided an understanding of their orbits: in 1694, Edmond Halley presented a theory that Noah's flood in the Bible was caused by a comet impact.[45] Human perception of near-Earth asteroids as benign objects of fascination or killer objects with high risk to human society has ebbed and flowed during the short time that NEAs have been scientifically observed.[12] Scientists have recognised the threat of impacts that create craters much bigger than the impacting bodies and have indirect effects on an even wider area since the 1980s, after the confirmation of a theory that the Cretaceous–Paleogene extinction event (in which the non-avian dinosaurs died out) 65 million years ago was caused by a large asteroid impact.[6][46]

The awareness of the wider public of the impact risk rose after the observation of the impact of the fragments of Comet Shoemaker–Levy 9 into Jupiter in July 1994.[6][46] In 1998, the movies Deep Impact and Armageddon popularised the notion that near-Earth objects could cause catastrophic impacts.[46] Also at that time, a conspiracy theory arose about the supposed 2003 impact of the fictitious planet Nibiru, which persisted on the internet as the predicted impact date was moved to 2012 and then 2017.[47]

Risk scales

There are two schemes for the scientific classification of impact hazards from NEOs:

  • the simple Torino scale, which rates the risks of impacts in the next 100 years according to impact energy and impact probability, using integer numbers between 0 and 10;[48][49] and
  • the more complex Palermo Technical Impact Hazard Scale, which ascribes ratings that can be any positive or negative real number; these ratings depend on the background impact frequency, impact probability and time until possible impact.[50]

On both scales, risks of any concern are indicated by values above zero.[48][50]

Magnitude of risk

The annual background frequency used in the Palermo scale for impacts of energy greater than E megatonnes is estimated as:[50]

 

For instance, this formula implies that the expected value of the time from now until the next impact greater than 1 megatonne is 33 years, and that when it occurs, there is a 50% chance that it will be above 2.4 megatonnes. This formula is only valid over a certain range of E.

However, another paper[51] published in 2002 – the same year as the paper on that the Palermo scale is based – found a power law with different constants:

 

This formula gives considerably lower rates for a given E. For instance, it gives the rate for bolides of 10 megatonnes or more (like the Tunguska explosion) as 1 per thousand years, rather than 1 per 210 years as in the Palermo formula. However, the authors give a rather large uncertainty (once in 400 to 1800 years for 10 megatonnes), due in part to uncertainties in determining the energies of the atmospheric impacts that they used in their determination.

Highly rated risks

NASA maintains an automated system to evaluate the threat from known NEOs over the next 100 years, which generates the continuously updated Sentry Risk Table.[52] All or nearly all of the objects are highly likely to drop off the list eventually as more observations come in, reducing the uncertainties and enabling more accurate orbital predictions.[52][53]

In March 2002, (163132) 2002 CU11 became the first asteroid with a temporarily positive rating on the Torino Scale, with about a 1 in 9,300 chance of an impact in 2049.[54] Additional observations reduced the estimated risk to zero, and the asteroid was removed from the Sentry Risk Table in April 2002.[55] It is now known that within the next two centuries, 2002 CU11 will pass the Earth at a safe closest distance (perigee) of 0.00425 AU (636,000 km; 395,000 mi) on August 31, 2080.[56]

 
Radar image of asteroid 1950 DA

Asteroid 1950 DA was lost after its 1950 discovery, since its observations over just 17 days were insufficient to precisely determine its orbit; it was rediscovered on December 31, 2000. It has a diameter of about a kilometer (0.6 miles), and an impact would therefore be globally catastrophic. It was observed by radar during its close 2001 approach, allowing much more precise orbit calculations. Although this asteroid will not strike for at least 800 years and thus has no Torino scale rating, it was added to the Sentry list in April 2002 as the first object with a Palermo scale value greater than zero.[57][58] The then-calculated 1 in 300 maximum chance of impact and +0.17 Palermo scale value was roughly 50% greater than the background risk of impact by all similarly large objects until 2880.[59] Uncertainties in the orbit calculations were further reduced using additional radar observations in 2012, and this decreased the odds of an impact.[60] Taking all radar and optical observations through 2021 into account, the probability of impact in March 2880 is, as of June 2022, assessed at 1 in 34,000.[52] The corresponding Palermo scale value of −2.05 is still among the highest for all objects on the Sentry List Table.[52]

On December 24, 2004, 370 m (1,210 ft) asteroid 99942 Apophis (at the time known only by its provisional designation 2004 MN4) was assigned a 4 on the Torino scale, the highest rating given to date, as the information available at the time translated to a 2.7% chance of Earth impact on Friday, April 13, 2029. By December 28, 2004, additional observations had significantly reduced the uncertainty zone for the 2029 approach and it no longer included the Earth. The 2029 risk of impact consequently dropped to zero, but later potential impact dates were still rated 1 on the Torino scale. Further observations lowered the 2036 risk to a Torino rating of 0 in August 2006. In 2021 Apophis was removed from the Sentry Risk Table.

In February 2006, (144898) 2004 VD17 was assigned a Torino Scale rating of 2 due to a close encounter predicted for May 4, 2102.[61] After additional observations allowed increasingly precise predictions, the Torino rating was lowered first to 1 in May 2006, then to 0 in October 2006, and the asteroid was removed from the Sentry Risk Table entirely in February 2008.[55]

As of 2021, 2010 RF12 is listed with the highest chance of impacting Earth, at 1 in 22 on September 5, 2095. At only 7 m (23 ft) across, the asteroid however is much too small to be considered a potentially hazardous asteroid and it poses no serious threat: the possible 2095 impact therefore rates only −3.32 on the Palermo Scale.[52] Observations during the August 2022 close approach are expected to ascertain whether the asteroid will impact or miss Earth in 2095.[62]

Projects to minimize the threat

Main article: Asteroid impact avoidance
 
 
Annual NEA discoveries by survey: all NEAs (top) and NEAs > 1 km (bottom)
 
NEOWISE – first four years of data starting in December 2013 (animated; April 20, 2018)

The first astronomical program dedicated to the discovery of near-Earth asteroids was the Palomar Planet-Crossing Asteroid Survey. The link to impact hazard, the need for dedicated survey telescopes and options to head off an eventual impact were first discussed at a 1981 interdisciplinary conference in Snowmass, Colorado.[46] Plans for a more comprehensive survey, named the Spaceguard Survey, were developed by NASA from 1992, under a mandate from the United States Congress.[63][64] To promote the survey on an international level, the International Astronomical Union (IAU) organised a workshop at Vulcano, Italy in 1995,[63] and set up the Spaceguard Foundation also in Italy a year later.[7] In 1998, the United States Congress gave NASA a mandate to detect 90% of near-earth asteroids over 1 km (0.62 mi) diameter (that threaten global devastation) by 2008.[64][65]

Several surveys have undertaken "Spaceguard" activities (an umbrella term), including Lincoln Near-Earth Asteroid Research (LINEAR), Spacewatch, Near-Earth Asteroid Tracking (NEAT), Lowell Observatory Near-Earth-Object Search (LONEOS), Catalina Sky Survey (CSS), Campo Imperatore Near-Earth Object Survey (CINEOS), Japanese Spaceguard Association, Asiago-DLR Asteroid Survey (ADAS) and Near-Earth Object WISE (NEOWISE). As a result, the ratio of the known and the estimated total number of near-Earth asteroids larger than 1 km in diameter rose from about 20% in 1998 to 65% in 2004,[7] 80% in 2006,[65] and 93% in 2011. The original Spaceguard goal has thus been met, only three years late.[8][66] As of November 2021, 891 NEAs larger than 1 km have been discovered,[1] or 97% of an estimated total of about 920.[67]

In 2005, the original USA Spaceguard mandate was extended by the George E. Brown, Jr. Near-Earth Object Survey Act, which calls for NASA to detect 90% of NEOs with diameters of 140 m (460 ft) or greater, by 2020.[9] As of January 2020, it is estimated that less than half of these have been found, but objects of this size hit the earth only about once in 2000 years.[68] In January 2016, NASA announced the creation of the Planetary Defense Coordination Office (PDCO) to track NEOs larger than about 30–50 m (98–164 ft) in diameter and coordinate an effective threat response and mitigation effort.[10][69]

Survey programs aim to identify threats years in advance, giving humanity time to prepare a space mission to avert the threat.

REP. STEWART: ... are we technologically capable of launching something that could intercept [an asteroid]? ...
DR. A'HEARN: No. If we had spacecraft plans on the books already, that would take a year ... I mean a typical small mission ... takes four years from approval to start to launch ...

— Rep. Chris Stewart (R, UT) and Dr. Michael F. A'Hearn, April 10, 2013, United States Congress[70]

The ATLAS project, by contrast, aims to find impacting asteroids shortly before impact, much too late for deflection maneuvers but still in time to evacuate and otherwise prepare the affected Earth region.[71] Another project, the Zwicky Transient Facility (ZTF), which surveys for objects that change their brightness rapidly,[72] also detects asteroids passing close to Earth.[73]

Further information: List of near-Earth object observation projects

Scientists involved in NEO research have also considered options for actively averting the threat if an object is found to be on a collision course with Earth.[46] All viable methods aim to deflect rather than destroy the threatening NEO, because the fragments would still cause widespread destruction.[13] Deflection, which means a change in the object's orbit months to years prior to the predicted impact, also requires orders of magnitude less energy.[13]

Number and classification

 
Cumulative discoveries of near-Earth asteroids known by size, 1980–2023

Near-Earth objects are classified as meteoroids, asteroids, or comets depending on size, composition, and orbit. Those which are asteroids can additionally be members of an asteroid family, and comets create meteoroid streams that can generate meteor showers.

As of November 4, 2021 and according to statistics maintained by CNEOS, 27,440 NEOs have been discovered. Only 117 (0.43%) of them are comets, whilst 27,323 (99.57%) are asteroids. 2,224 of those NEOs are classified as potentially hazardous asteroids (PHAs).[1]

As of November 2021, over 1,200 NEAs appear on the Sentry impact risk page at the NASA website.[52] Over 1,000 of these NEAs are less than 50 meters in diameter and none of the listed objects are placed even in the "green zone" (Torino Scale 1), meaning that none warrant the attention of the general public.[48]

Observational biases

The main problem with estimating the number of NEOs is that the probability of detecting one is influenced by a number of aspects of the NEO, starting naturally with its size but also including the characteristics of its orbit and the reflectivity of its surface.[74] What is easily detected will be more counted,[75] and these observational biases need to be compensated when trying to calculate the number of bodies in a population from the list of its detected members.[74]

 
Artist’s impression of an asteroid that orbits closer to the Sun than Earth’s orbit

Bigger asteroids reflect more light,[75] and the two biggest Near-Earth objects, 433 Eros and 1036 Ganymed, were naturally also among the first to be detected.[76] 1036 Ganymed is about 35 km (22 mi) in diameter and 433 Eros is about 17 km (11 mi) in diameter .[76]

The other major detection bias is that it is much easier to spot objects on the night-side of Earth. The day sky near the Sun is much brighter than the night sky, and there is therefore much better contrast in the night sky.[75] The night-side searcher is also looking at the sunlit side of the asteroids, while in the daytime sky a searcher looks towards the sun and sees the unlit backside of the object. In addition, opposition surge makes asteroids even brighter when the Earth is close to the axis of sunlight. The combined effect is equivalent to the comparison of a Full moon at night to a New Moon in daytime, and the light of the Sun-lit asteroids has been called "full asteroid" similar to a "full moon".[75] Evidencing this bias and as depicted in the diagram below, over half (53%) of the known Near Earth objects were discovered in just 3.8% of the sky, in a 22.5° cone facing directly away from the Sun, and the vast majority (87%) were first found in only 15% of the sky, in the 45° cone facing away from the Sun.[77] The most practical way around this opposition bias is to use thermal infrared telescopes in space that observe their heat emissions instead of the light they reflect, with a sensitivity that is almost independent of the illumination.[75]

Asteroids with orbits that make them spend more time on the day-side of the Earth are therefore less likely to be discovered than those that spend most of their time beyond the orbit of the Earth. For example, one study noted that detection of bodies in low-eccentricity Earth-crossing orbits is favored, making Atens more likely to be detected than Apollos.[78]

Such observational biases must be identified and quantified to determine NEO populations, as studies of asteroid populations then take those known observational selection biases into account to make a more accurate assessment.[79] In the year 2000 and taking into account all known observational biases, it was estimated that there are approximately 900 near-Earth asteroids of at least kilometer size, or technically and more accurately, with an absolute magnitude brighter than 17.75.[74]

Near-Earth asteroids (NEAs)

 
Asteroid Toutatis from Paranal

These are asteroids in a near-Earth orbit without the tail or coma of a comet. As of November 2022, 30,503 near-Earth asteroids are known, 2,304 of which are both sufficiently large and may come sufficiently close to Earth to be classified as potentially hazardous.[1]

NEAs survive in their orbits for just a few million years.[22] They are eventually eliminated by planetary perturbations, causing ejection from the Solar System or a collision with the Sun, a planet, or other celestial body.[22] With orbital lifetimes short compared to the age of the Solar System, new asteroids must be constantly moved into near-Earth orbits to explain the observed asteroids. The accepted origin of these asteroids is that main-belt asteroids are moved into the inner Solar System through orbital resonances with Jupiter.[22] The interaction with Jupiter through the resonance perturbs the asteroid's orbit and it comes into the inner Solar System. The asteroid belt has gaps, known as Kirkwood gaps, where these resonances occur as the asteroids in these resonances have been moved onto other orbits. New asteroids migrate into these resonances, due to the Yarkovsky effect that provides a continuing supply of near-Earth asteroids.[80] Compared to the entire mass of the asteroid belt, the mass loss necessary to sustain the NEA population is relatively small; totalling less than 6% over the past 3.5 billion years.[22] The composition of near-Earth asteroids is comparable to that of asteroids from the asteroid belt, reflecting a variety of asteroid spectral types.[81]

A small number of NEAs are extinct comets that have lost their volatile surface materials, although having a faint or intermittent comet-like tail does not necessarily result in a classification as a near-Earth comet, making the boundaries somewhat fuzzy. The rest of the near-Earth asteroids are driven out of the asteroid belt by gravitational interactions with Jupiter.[22][82]

Many asteroids have natural satellites (minor-planet moons). As of October 2021, 85 NEAs were known to have at least one moon, including three known to have two moons.[83] The asteroid 3122 Florence, one of the largest PHAs[27] with a diameter of 4.5 km (2.8 mi), has two moons measuring 100–300 m (330–980 ft) across, which were discovered by radar imaging during the asteroid's 2017 approach to Earth.[84]

In May 2022, an algorithm known as Tracklet-less Heliocentric Orbit Recovery or THOR and developed by University of Washington researchers to discover asteroids in the solar system was announced as a success.[85] The International Astronomical Union's Minor Planet Center confirmed a series of first candidate asteroids identified by the algorithm.[86]

Size distribution

 
Known near-Earth asteroids by size

While the size of a very small fraction of these asteroids is known to better than 1%, from radar observations, from images of the asteroid surface, or from stellar occultations, the diameter of the vast majority of near Earth asteroids has only been estimated on the basis of their brightness and a representative asteroid surface reflectivity or albedo, which is commonly assumed to be 14%.[28] Such indirect size estimates are uncertain by over a factor of 2 for individual asteroids, since asteroid albedos can range at least as low as 5% and as high as 30%. This makes the volume of those asteroids uncertain by a factor of 8, and their mass by at least as much, since their assumed density also has its own uncertainty. Using this crude method, an absolute magnitude of 17.75 roughly corresponds to a diameter of 1 km (0.62 mi)[28] and an absolute magnitude of 22.0 to a diameter of 140 m (460 ft).[2] Diameters of intermediate precision, better than from an assumed albedo but not nearly as precise as good direct measurements, can be obtained from the combination of reflected light and thermal infrared emission, using a thermal model of the asteroid to estimate both its diameter and its albedo. In May 2016, technologist Nathan Myhrvold questioned the precision of such asteroid diameter estimates arising from thermal modeling of measurements by the Wide-field Infrared Survey Explorer and NEOWISE missions.[87][88][89] The original version of his criticism itself faced criticism for its methodology[90] and did not pass peer review,[88][91] but a revised version was subsequently published.[92][93]

In 2000, NASA reduced from 1,000–2,000 to 500–1,000 its estimate of the number of existing near-Earth asteroids over one kilometer in diameter, or more exactly brighter than an absolute magnitude of 17.75.[94][95] Shortly thereafter, the LINEAR survey provided an alternative estimate of 1,227+170
−90.[96] In 2011, on the basis of NEOWISE observations, the estimated number of one-kilometer NEAs was narrowed to 981±19 (of which 93% had been discovered at the time), while the number of NEAs larger than 140 meters across was estimated at 13,200±1,900.[8][66] The NEOWISE estimate differed from other estimates primarily in assuming a slightly lower average asteroid albedo, which produces larger estimated diameters for the same asteroid brightness. This resulted in 911 then known asteroids at least 1 km across, as opposed to the 830 then listed by CNEOS from the same inputs but assuming a slightly higher albedo.[97] In 2017, two studies using an improved statistical method reduced the estimated number of NEAs brighter than absolute magnitude 17.75 (approximately over one kilometer in diameter) slightly to 921±20.[67][98] The estimated number of near-Earth asteroids brighter than absolute magnitude of 22.0 (approximately over 140 m across) rose to 27,100±2,200, double the WISE estimate,[98] of which about a third were known as of 2018. The number of asteroids brighter than H = 25, which corresponds to about 40 m (130 ft) in diameter, is estimated at 840,000±23,000—of which about 1.3 percent had been discovered by February 2016; the number of asteroids brighter than H = 30 (larger than 3.5 m (11 ft)) is estimated at 400±100 million—of which about 0.003 percent had been discovered by February 2016.[98]


As of January 12, 2023, and using diameters mostly estimated crudely from a measured absolute magnitude and an assumed albedo, 859 NEAs listed by CNEOS, including 152 PHAs, measure at least 1 km in diameter, and 10,362 known NEAs, including 2322 PHAs, are larger than 140 m in diameter.[1] The smallest known near-Earth asteroid is 2008 TS26 with an absolute magnitude of 33.2,[29] corresponding to an estimated diameter of about 1 m (3.3 ft).[99] The largest such object is 1036 Ganymed,[29] with an absolute magnitude of 9.45 and directly measured irregular dimensions which are equivalent to a diameter of about 38 km (24 mi).[100]

Orbital classification

 
Types of near-Earth asteroid orbits

Near-Earth asteroids are divided into groups based on their semi-major axis (a), perihelion distance (q), and aphelion distance (Q):[2][22]

  • The Atiras or Apoheles have orbits strictly inside Earth's orbit: an Atira asteroid's aphelion distance (Q) is smaller than Earth's perihelion distance (0.983 AU). That is, Q < 0.983 AU, which implies that the asteroid's semi-major axis is also less than 0.983 AU.[101]
 
The group of Atira (Apohele) asteroids compared to the orbits of the terrestrial planets of the Solar System.
  • The Atens have a semi-major axis of less than 1 AU and cross Earth's orbit. Mathematically, a < 1.0 AU and Q > 0.983 AU. (0.983 AU is Earth's perihelion distance.)
 
The Aten group compared to the orbits of the terrestrial planets of the Solar System.
  • The Apollos have a semi-major axis of more than 1 AU and cross Earth's orbit. Mathematically, a > 1.0 AU and q < 1.017 AU. (1.017 AU is Earth's aphelion distance.)
 
Location of the Apollo asteroids compared to the orbits of the terrestrial planets of the Solar System.
  • The Amors have orbits strictly outside Earth's orbit: an Amor asteroid's perihelion distance (q) is greater than Earth's aphelion distance (1.017 AU). Amor asteroids are also near-earth objects so q < 1.3 AU. In summary, 1.017 AU < q < 1.3 AU. (This implies that the asteroid's semi-major axis (a) is also larger than 1.017 AU.) Some Amor asteroid orbits cross the orbit of Mars.
 
The Amor asteroid group compared to the orbits of the terrestrial planets of the Solar System.

(Note: Some authors define Atens differently: they define it as being all the asteroids with a semi-major axis of less than 1 AU.[102][103] That is, they consider the Atiras to be part of the Atens.[103] Historically, until 1998, there were no known or suspected Atiras, so the distinction wasn't necessary.)

Atiras and Amors do not cross the Earth's orbit and are not immediate impact threats, but their orbits may change to become Earth-crossing orbits in the future.[104][22]

As of November 4, 2021, 26 Atiras, 2,113 Atens, 15,186 Apollos and 9,998 Amors have been discovered and cataloged.[1]

Co-orbital asteroids

 
The five Lagrangian points relative to Earth and possible orbits along gravitational contours
 
Overview of the Inner Solar System with different co-orbital bodies.

NEAs on a co-orbital configuration have the same orbital period as the Earth. All co-orbital asteroids have special orbits that are relatively stable and, paradoxically, can prevent them from getting close to Earth:

  • Trojans: Near the orbit of a planet, there are five gravitational equilibrium points, the Lagrangian points, in which an asteroid would orbit the Sun in fixed formation with the planet. Two of these, 60 degrees ahead and behind the planet along its orbit (designated L4 and L5 respectively) are stable; that is, an asteroid near these points would stay there for millions of years even if lightly perturbed by other planets and by non-gravitational forces. As of March 2018, Earth's only confirmed Trojan is 2010 TK7, circling Earth's L4 point.[105]
  • Horseshoe librators: The region of stability around L4 and L5 also includes orbits for co-orbital asteroids that run around both L4 and L5. Relative to the Earth and Sun, the orbit can resemble the circumference of a horseshoe, or may consist of annual loops that wander back and forth (librate) in a horseshoe-shaped area. In both cases, the Sun is at the horseshoe's center of gravity, Earth is in the gap of the horseshoe, and L4 and L5 are inside the ends of the horseshoe. By 2016, 12 horseshoe librators of Earth have been discovered.[106] The most-studied and, at about 5 km (3.1 mi), largest is 3753 Cruithne, which travels along bean-shaped annual loops and completes its horseshoe libration cycle every 770–780 years.[107][108] (419624) 2010 SO16 is an asteroid on a relatively stable circumference-of-a-horseshoe orbit, with a horseshoe libration period of about 350 years.[109]
  • Quasi-satellites: Quasi-satellites are co-orbital asteroids on a normal elliptic orbit with a higher eccentricity than Earth's, which they travel in a way synchronised with Earth's motion. Since the asteroid orbits the Sun slower than Earth when further away and faster than Earth when closer to the Sun, when observed from Earth, the quasi-satellite appears to orbit Earth in a retrograde direction in one year, even though it is not bound gravitationally. By 2016, five asteroids were known to be a quasi-satellite of Earth. 469219 Kamoʻoalewa is Earth's closest quasi-satellite, in an orbit that has been stable for almost a century.[110] Orbit calculations until 2016 showed that all quasi-satellites and four of the horseshoe librators then known repeatedly transfer between horseshoe and quasi-satellite orbits.[110] One of these objects, 2003 YN107, was observed during its transition from a quasi-satellite orbit to a horseshoe orbit in 2006; it is expected to transfer back to a quasi-satellite orbit sometime around year 2066.[111]
  • Temporary satellites: NEAs can also transfer between solar orbits and distant Earth orbits, becoming gravitationally bound temporary satellites. According to simulations, temporary satellites are typically caught when they pass the L1 or L2 Lagrangian points, and Earth typically has at least one temporary satellite 1 m (3.3 ft) across at any given time, but they are too faint to detect by current surveys.[112] As of November 2021, the only observed transitions were those of asteroids 2006 RH120 and 2020 CD3, which were temporary satellites of Earth for at least a year since their capture dates.[113][114]

Meteoroids

In 1961, the IAU defined meteoroids as a class of solid interplanetary objects distinct from asteroids by their considerably smaller size.[115] This definition was useful at the time because, with the exception of the Tunguska event, all historically observed meteors were produced by objects significantly smaller than the smallest asteroids then observable by telescopes.[115] As the distinction began to blur with the discovery of ever smaller asteroids and a greater variety of observed NEO impacts, revised definitions with size limits have been proposed from the 1990s.[115] In April 2017, the IAU adopted a revised definition that generally limits meteoroids to a size between 30 µm and 1 m in diameter, but permits the use of the term for any object of any size that caused a meteor, thus leaving the distinction between asteroid and meteoroid blurred.[116]

Near-Earth comets

 
Halley's Comet during its 0.10 AU[117] approach of Earth in May 1910

Near-Earth comets (NECs) are objects in a near-Earth orbit with a tail or coma. Comet nuclei are typically less dense than asteroids but they pass Earth at higher relative speeds, thus the impact energy of a comet nucleus is slightly larger than that of a similar-sized asteroid.[118] NECs may pose an additional hazard due to fragmentation: the meteoroid streams which produce meteor showers may include large inactive fragments, effectively NEAs.[119] Although no impact of a comet in Earth's history has been conclusively confirmed, the Tunguska event may have been caused by a fragment of Comet Encke.[120]

Comets are commonly divided between short-period and long-period comets. Short-period comets, with an orbital period of less than 200 years, originate in the Kuiper belt, beyond the orbit of Neptune; while long-period comets originate in the Oort Cloud, in the outer reaches of the Solar System.[13] The orbital period distinction is of importance in the evaluation of the risk from near-Earth comets because short-period NECs are likely to have been observed during multiple apparitions and thus their orbits can be determined with some precision, while long-period NECs can be assumed to have been seen for the first and last time when they appeared during the Age of Science, thus their approaches cannot be predicted well in advance.[13] Since the threat from long-period NECs is estimated to be at most 1% of the threat from NEAs, and long-period comets are very faint and thus difficult to detect at large distances from the Sun, Spaceguard efforts have consistently focused on asteroids and short-period comets.[63][118] CNEOS even restricts its definition of NECs to short-period comets[2]—as of November 4, 2021, 117 such objects have been discovered.[1]

As of November 2021, only 23 comets have been observed to pass within 0.1 AU (15,000,000 km; 9,300,000 mi) of Earth, including 10 which are or have been short-period comets.[121] Two of these comets, Halley's Comet and 73P/Schwassmann–Wachmann, have been observed during multiple close approaches.[121] The closest observed approach was 0.0151 AU (5.88 LD) for Lexell's Comet on July 1, 1770.[121] After an orbit change due to a close approach of Jupiter in 1779, this object is no longer a NEC. The closest approach ever observed for a current short-period NEC is 0.0229 AU (8.92 LD) for Comet Tempel–Tuttle in 1366.[121] This comet is the parent body of the Leonid meteor shower, which also produced the Great Meteor Storm of 1833.[122] Orbital calculations show that P/1999 J6 (SOHO), a faint sungrazing comet and confirmed short-period NEC observed only during its close approaches to the Sun,[123] passed Earth undetected at a distance of 0.0121 AU (4.70 LD) on June 12, 1999.[124]

Comet 109P/Swift–Tuttle, which is also the source of the Perseid meteor shower every year in August, has a roughly 130-year orbit that passes close to the Earth. During the comet's September 1992 recovery, when only the two previous returns in 1862 and 1737 had been identified, calculations showed that the comet would pass close to Earth during its next return in 2126, with an impact within the range of uncertainty. By 1993, even earlier returns (back to at least 188 AD) have been identified, and the longer observation arc eliminated the impact risk. The comet will pass Earth in 2126 at a distance of 23 million kilometers. In 3044, the comet is expected to pass Earth at less than 1.6 million kilometers.[125]

Artificial near-Earth objects

 
J002E3 discovery images taken on September 3, 2002. J002E3 is in the circle

Defunct space probes and final stages of rockets can end up in near-Earth orbits around the Sun, and be re-discovered by NEO surveys when they return to Earth's vicinity.

In September 2002, astronomers found an object designated J002E3. The object was on a temporary satellite orbit around Earth, leaving for a solar orbit in June 2003. Calculations showed that it was also on a solar orbit before 2002, but was close to Earth in 1971. J002E3 was identified as the third stage of the Saturn V rocket that carried Apollo 12 to the Moon.[126][127] In 2006, two more apparent temporary satellites were discovered which were suspected of being artificial.[127] One of them was eventually confirmed as an asteroid and classified as the temporary satellite 2006 RH120.[127] The other, 6Q0B44E, was confirmed as an artificial object, but its identity is unknown.[127] Another temporary satellite was discovered in 2013, and was designated 2013 QW1 as a suspected asteroid. It was later found to be an artificial object of unknown origin. 2013 QW1 is no longer listed as an asteroid by the Minor Planet Center.[127][128]

In some cases, active space probes on solar orbits have been observed by NEO surveys and erroneously catalogued as asteroids before identification. During its 2007 flyby of Earth on its route to a comet, ESA's space probe Rosetta was detected unidentified and classified as asteroid 2007 VN84, with an alert issued due to its close approach.[129] The designation 2015 HP116 was similarly removed from asteroid catalogues when the observed object was identified with Gaia, ESA's space observatory for astrometry.[130]

Impacts

Main article: Impact event

When a near-Earth object impacts Earth, objects up to a few tens of metres across ordinarily explode in the upper atmosphere (usually harmlessly), with most or all of the solids vaporized and only small amounts of meteorites arriving to the Earth surface, while larger objects hit the water surface, forming tsunami waves, or the solid surface, forming impact craters.[131]

The frequency of impacts of objects of various sizes is estimated on the basis of orbit simulations of NEO populations, the frequency of impact craters on the Earth and the Moon, and the frequency of close encounters.[132][133] The study of impact craters indicates that impact frequency has been more or less steady for the past 3.5 billion years, which requires a steady replenishment of the NEO population from the asteroid main belt.[22] One impact model based on widely accepted NEO population models estimates the average time between the impact of two stony asteroids with a diameter of at least 4 m (13 ft) at about one year; for asteroids 7 m (23 ft) across (which impacts with as much energy as the atomic bomb dropped on Hiroshima, approximately 15 kilotonnes of TNT) at five years, for asteroids 60 m (200 ft) across (an impact energy of 10 megatons, comparable to the Tunguska event in 1908) at 1,300 years, for asteroids 1 km (0.62 mi) across at half a million years, and for asteroids 5 km (3.1 mi) across at 18 million years.[134] Some other models estimate similar impact frequencies,[22] while others calculate higher frequencies.[133] For Tunguska-sized (10 megaton) impacts, the estimates range from one event every 2,000–3,000 years to one event every 300 years.[133]

 
Location and impact energy of small asteroids impacting Earth's atmosphere

The second-largest observed event after the Tunguska meteor was a 1.1 megaton air blast in 1963 near the Prince Edward Islands between South Africa and Antarctica, which was detected only by infrasound sensors.[135] However this may not have been a meteor.[136] The third-largest, but by far best-observed impact, was the Chelyabinsk meteor of 15 February 2013. A previously unknown 20 m (66 ft) asteroid exploded above this Russian city with an equivalent blast yield of 400–500 kilotons.[135] The calculated orbit of the pre-impact asteroid is similar to that of Apollo asteroid 2011 EO40, making the latter the meteor's possible parent body.[137]

On 7 October 2008, 19 hours after it was first observed, 4 m (13 ft) asteroid 2008 TC3 blew up 37 km (23 mi) above the Nubian Desert in Sudan. It was the first time that an asteroid was observed and its impact was predicted prior to its entry into the atmosphere as a meteor.[138] 10.7 kg of meteorites were recovered after the impact.[139]

On 2 January 2014, just 21 hours after it was the first asteroid to be discovered in 2014, 2–4 m 2014 AA blew up in Earth's atmosphere above the Atlantic Ocean. Far from any land, the meteor explosion was only observed by three infrasound detectors of the Comprehensive Nuclear-Test-Ban Treaty Organization. This impact was the second to be predicted.[140]

Further predicted impacts include 2018 LA around the border between Botswana and South Africa and 2019 MO off Puerto Rico, but asteroid impact prediction remains in its infancy and successfully predicted asteroid impacts are rare. The vast majority of impacts recorded by infrasound sensors designed to detect detonation of nuclear devices are not predicted.[141]

Observed impacts aren't restricted to the surface and atmosphere of Earth. Dust-sized NEOs have impacted man-made spacecraft, including NASA's Long Duration Exposure Facility, which collected interplanetary dust in low Earth orbit for six years from 1984.[115] Impacts on the Moon can be observed as flashes of light with a typical duration of a fraction of a second.[142] The first lunar impacts were recorded during the 1999 Leonid storm.[143] Subsequently, several continuous monitoring programs were launched.[142][144][145] As of March 2018, the largest observed lunar impact occurred on 11 September 2013, lasted 8 seconds, and was likely caused by an object 0.6–1.4 m (2.0–4.6 ft) in diameter.[144]

Close approaches

Main article: List of asteroid close approaches to Earth
 
Flyby of asteroid 2004 FH (centre dot being followed by the sequence). The other object that flashes by is an artificial satellite

Each year, several mostly small NEOs pass Earth closer than the distance of the Moon.[146]

On August 10, 1972, a meteor that became known as the 1972 Great Daylight Fireball was witnessed by many people; it moved north over the Rocky Mountains from the U.S. Southwest to Canada. It was an Earth-grazing meteoroid that passed within 57 km (35 mi) of the Earth's surface, and was filmed by a tourist at the Grand Teton National Park in Wyoming with an 8-millimeter color movie camera.[147]

On October 13, 1990, Earth-grazing meteoroid EN131090 was observed above Czechoslovakia and Poland, moving at 41.74 km/s (25.94 mi/s) along a 409 km (254 mi) trajectory from south to north. The closest approach to the Earth was 98.67 km (61.31 mi) above the surface. It was captured by two all-sky cameras of the European Fireball Network, which for the first time enabled geometric calculations of the orbit of such a body.[148]

On March 18, 2004, LINEAR announced that a 30 m (98 ft) asteroid, 2004 FH, would pass the Earth that day at only 42,600 km (26,500 mi), about one-tenth the distance to the Moon, and the closest miss ever noticed until then. They estimated that similar-sized asteroids come as close about every two years.[149]

On March 31, 2004, two weeks after 2004 FH, 2004 FU162 set a new record for closest recorded approach above the atmosphere, passing Earth's surface only 6,500 km (4,000 mi) away (about one Earth radius or one-sixtieth of the distance to the Moon). Because it was very small (6 meters/20 feet), FU162 was detected only hours before its closest approach. If it had collided with Earth, it probably would have disintegrated harmlessly in the atmosphere.[150]

On February 4, 2011, an asteroid designated 2011 CQ1, estimated at 0.8–2.6 m (2.6–8.5 ft) in diameter, passed within 5,500 km (3,400 mi) of the Earth.[151]

On November 8, 2011, asteroid (308635) 2005 YU55, relatively large at about 360 m (1,180 ft) in diameter, passed within 324,600 km (201,700 mi) (0.85 lunar distances) of Earth.[152]

On February 15, 2013, the 30 m (98 ft) asteroid 367943 Duende (2012 DA14) passed approximately 27,700 km (17,200 mi) above the surface of Earth, closer than satellites in geosynchronous orbit.[153] The asteroid was not visible to the unaided eye. This was the first close passage of an object discovered during a previous passage, and was thus the first to be predicted well in advance.[154]

 
Diagram showing spacecraft and asteroids (past and future) between the Earth and the Moon.

Exploratory missions

Some NEOs are of special interest because they can be physically explored with lower mission velocity than is necessary for even the Moon, due to their combination of low velocity with respect to Earth and weak gravity. They may present interesting scientific opportunities both for direct geochemical and astronomical investigation, and as potentially economical sources of extraterrestrial materials for human exploitation.[11] This makes them an attractive target for exploration.[155]

Missions to NEAs

 
433 Eros as seen by NASA's NEAR probe
 
Image mosaic of asteroid 101955 Bennu, target of NASA's OSIRIS-REx probe
Further information: List of minor planets and comets visited by spacecraft

The IAU held a minor planets workshop in Tucson, Arizona, in March 1971. At that point, launching a spacecraft to asteroids was considered premature; the workshop only inspired the first astronomical survey specifically aiming for NEAs.[12] Missions to asteroids were considered again during a workshop at the University of Chicago held by NASA's Office of Space Science in January 1978. Of all of the near-Earth asteroids (NEA) that had been discovered by mid-1977, it was estimated that spacecraft could rendezvous with and return from only about 1 in 10 using less propulsive energy than is necessary to reach Mars. It was recognised that due to the low surface gravity of all NEAs, moving around on the surface of an NEA would cost very little energy, and thus space probes could gather multiple samples.[12] Overall, it was estimated that about one percent of all NEAs might provide opportunities for human-crewed missions, or no more than about ten NEAs known at the time. A five-fold increase in the NEA discovery rate was deemed necessary to make a crewed mission within ten years worthwhile.[12]

The first near-Earth asteroid to be visited by a spacecraft was 17 km (11 mi) asteroid 433 Eros when NASA's Near Earth Asteroid Rendezvous (NEAR) probe orbited it from February 2001, landing on the asteroid surface in February 2002.[16] A second near-Earth asteroid, the 535 m (1,755 ft) long peanut-shaped 25143 Itokawa, was visited in September 2005 by JAXA's Hayabusa mission,[17] which succeeded in taking material samples back to Earth. A third near-Earth asteroid, the 2.26 km (1.40 mi) long elongated 4179 Toutatis, was explored by CNSA's Chang'e 2 spacecraft during a flyby in December 2012.[18][57]

The 980 m (3,220 ft) Apollo asteroid 162173 Ryugu is the target of JAXA's Hayabusa2 mission. The space probe was launched in December 2014, arrived at the asteroid in June 2018, and returned a sample to Earth in December 2020.[19] The 500 m (1,600 ft) Apollo asteroid 101955 Bennu, which, as of November 2021, has the highest cumulative Palermo scale rating (−1.41 for several close encounters between 2178 and 2290),[52] is the target of NASA's OSIRIS-REx probe. The New Frontiers program mission was launched in September 2016.[20] On its two-year journey to Bennu, the probe had searched for Earth's Trojan asteroids,[156] rendezvoused with Bennu in August 2018, and had entered into orbit around the asteroid in December 2018. OSIRIS-REx will return samples from the asteroid in September 2023.[20]

In April 2012, the company Planetary Resources announced its plans to mine asteroids commercially. In a first phase, the company reviewed data and selected potential targets among NEAs. In a second phase, space probes would be sent to the selected NEAs; mining spacecraft would be sent in a third phase.[157] Planetary Resources launched two testbed satellites in April 2015[158] and January 2018,[159] and the first prospecting satellite for the second phase was planned for a 2020 launch prior to the company closing and its assets purchased by ConsnSys Space in 2018.[158][160]

The Near-Earth Object Surveillance Mission (NEOSM) is planned for launch no earlier than 2025 to discover and characterize the orbit of most of the potentially hazardous asteroids larger than 140 m (460 ft) over the course of its mission.[161]

On September 26, 2022, the DART spacecraft impacted Dimorphos, in a test of a method of planetary defense against near-Earth objects.

Missions to NECs

 
67P/Churyumov–Gerasimenko as seen by ESA's Rosetta probe

The first near-Earth comet visited by a space probe was 21P/Giacobini–Zinner in 1985, when the NASA/ESA probe International Cometary Explorer (ICE) passed through its coma. In March 1986, ICE, along with Soviet probes Vega 1 and Vega 2, ISAS probes Sakigake and Suisei and ESA probe Giotto flew by the nucleus of Halley's Comet. In 1992, Giotto also visited another NEC, 26P/Grigg–Skjellerup.[13]

In November 2010, the NASA probe Deep Impact flew by the near-Earth comet 103P/Hartley. Earlier, in July 2005, this probe flew by the non-near-Earth comet Tempel 1, hitting it with a large copper mass.[14]

In August 2014, ESA probe Rosetta began orbiting near-Earth comet 67P/Churyumov–Gerasimenko, while its lander Philae landed on its surface in November 2014. After the end of its mission, Rosetta was crashed into the comet's surface in 2016.[15]

See also

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External links

 
Wikimedia Commons has media related to Near-Earth objects.
  • Center for Near Earth Object Studies (CNEOS) – Jet Propulsion Laboratory, NASA
  • Table of Asteroids Next Closest Approaches to the Earth – Sormano Astronomical Observatory
  • Earth In The Cosmic Shooting – D.J. Asher, The Observatory, 2005
  • Catalogue of the Solar System Small Bodies Orbital Evolution – Samara State Technical University
  • Armagh Observatory
Minor Planet Center
  • The NEO Confirmation Page
  • Minor Planet Center: Asteroid Hazards, Part 2: The Challenge of Detection on YouTube (min. 7:14)
  • Minor Planet Center: Asteroid Hazards, Part 3: Finding the Path on YouTube (min. 5:38)

February 08, 2023
near, earth, object, near, earth, object, small, solar, system, body, whose, orbit, brings, into, proximity, with, earth, convention, solar, system, body, closest, approach, perihelion, less, than, astronomical, units, orbit, crosses, earth, orbit, object, lar. A near Earth object NEO is any small Solar System body whose orbit brings it into proximity with Earth By convention a Solar System body is a NEO if its closest approach to the Sun perihelion is less than 1 3 astronomical units AU 2 If a NEO s orbit crosses the Earth s orbit and the object is larger than 140 meters 460 ft across it is considered a potentially hazardous object PHO 3 Most known PHOs and NEOs are asteroids but a small fraction are comets 1 Radar imaging of 388188 2006 DP14 by a DSN antennaVery Large Telescope image of the very faint near Earth asteroid 2009 FD as seen by the VLT telescopeNear Earth comet 103P Hartley as seen by NASA s Deep Impact probe 27 000 known NEOs divided into several orbital subgroups 1 Apollos 15142 55 35 Amors 9963 36 42 Atens 2107 7 70 Comets 117 0 43 Atiras 27 0 099 ꞌAyloꞌchaxnims 1 0 004 There are over 30 503 known near Earth asteroids NEAs and over a hundred known short period near Earth comets NECs 1 A number of solar orbiting meteoroids were large enough to be tracked in space before striking the Earth It is now widely accepted that collisions in the past have had a significant role in shaping the geological and biological history of the Earth 4 Asteroids as small as 20 metres 66 ft in diameter can cause significant damage to the local environment and human populations 5 Larger asteroids penetrate the atmosphere to the surface of the Earth producing craters if they impact a continent or tsunamis if they impact the sea Interest in NEOs has increased since the 1980s because of greater awareness of this potential danger Asteroid impact avoidance by deflection is possible in principle and methods of mitigation are being researched 6 Two scales the simple Torino scale and the more complex Palermo scale rate the risk presented by an identified NEO based on the probability of it impacting the Earth and on how severe the consequences of such an impact would be Some NEOs have had temporarily positive Torino or Palermo scale ratings after their discovery Since 1998 the United States the European Union and other nations are scanning the sky for NEOs in an effort called Spaceguard 7 The initial US Congress mandate to NASA to catalog at least 90 of NEOs that are at least 1 kilometre 3 300 ft in diameter sufficient to cause a global catastrophe was met by 2011 8 In later years the survey effort was expanded 9 to include smaller objects 10 which have the potential for large scale though not global damage NEOs have low surface gravity and many have Earth like orbits that make them easy targets for spacecraft 11 12 As of January 2019 update five near Earth comets 13 14 15 and five near Earth asteroids have been visited by spacecraft 16 17 18 19 20 A small sample of one NEO was returned to Earth in 2010 and similar missions are in progress 19 20 Preliminary plans for commercial asteroid mining have been drafted by private startup companies either through the use of robots or even by sending private commercial astronauts to act as space miners 21 Contents 1 Definitions 2 History of human awareness of NEOs 2 1 Risk 2 1 1 Risk scales 2 1 2 Magnitude of risk 2 1 3 Highly rated risks 2 2 Projects to minimize the threat 3 Number and classification 3 1 Observational biases 3 2 Near Earth asteroids NEAs 3 2 1 Size distribution 3 2 2 Orbital classification 3 2 3 Co orbital asteroids 3 3 Meteoroids 3 4 Near Earth comets 3 5 Artificial near Earth objects 4 Impacts 5 Close approaches 6 Exploratory missions 6 1 Missions to NEAs 6 2 Missions to NECs 7 See also 8 References 9 External linksDefinitions Edit Plot of orbits of known potentially hazardous asteroids size over 140 m 460 ft and passing within 7 6 10 6 km 4 7 10 6 mi of Earth s orbit as of early 2013 alternate image Near Earth objects NEOs are by convention technically defined as all small Solar System bodies with orbits around the Sun that lie partly between 0 983 and 1 3 astronomical units AU Sun Earth distance away from the Sun 22 23 NEOs are thus not necessarily currently near the Earth but they can potentially approach the Earth relatively closely The term is also sometimes used more flexibly for example for objects in orbit around the Earth or for quasi satellites 24 which have a more complex orbital relationship with the Earth When a NEO is detected like all other small Solar System bodies its positions and brightness are submitted to the International Astronomical Union s IAU s Minor Planet Center MPC for cataloging The MPC maintains separate lists of confirmed NEOs and potential NEOs 25 26 The orbits of some NEOs intersect that of the Earth so they pose a collision danger 3 These are considered potentially hazardous objects PHOs if their estimated diameter is above 140 meters The MPC maintains a separate list for the asteroids among PHOs the potentially hazardous asteroids PHAs 27 NEOs are also catalogued by two separate units of the Jet Propulsion Laboratory JPL of the National Aeronautics and Space Administration NASA the Center for Near Earth Object Studies CNEOS 28 and the Solar System Dynamics Group 29 PHAs are defined based on two parameters relating to respectively their potential to approach the Earth dangerously closely and the estimated consequences that an impact would have if it occurs 2 Objects with both an Earth minimum orbit intersection distance MOID of 0 05 AU or less and an absolute magnitude of 22 0 or brighter a rough indicator of large size are considered PHAs Objects that either cannot approach closer to the Earth i e MOID greater than 0 05 AU 7 500 000 km 4 600 000 mi or which are fainter than H 22 0 about 140 m 460 ft in diameter with assumed albedo of 14 are not considered PHAs 2 NASA s catalog of near Earth objects includes the approach distances of asteroids and comets expressed in lunar distances 30 History of human awareness of NEOs Edit 1910 drawing of the path of Halley s Comet The near Earth asteroid 433 Eros was visited by a probe in the 1990s The first near Earth objects to be observed by humans were comets Their extraterrestrial nature was recognised and confirmed only after Tycho Brahe tried to measure the distance of a comet through its parallax in 1577 and the lower limit he obtained was well above the Earth diameter the periodicity of some comets was first recognised in 1705 when Edmond Halley published his orbit calculations for the returning object now known as Halley s Comet 31 The 1758 1759 return of Halley s Comet was the first comet appearance predicted 32 It has been said that Lexell s comet of 1770 was the first discovered Near Earth object 33 The first near Earth asteroid to be discovered was 433 Eros in 1898 34 The asteroid was subject to several extensive observation campaigns primarily because measurements of its orbit enabled a precise determination of the then imperfectly known distance of the Earth from the Sun 35 In 1937 asteroid 69230 Hermes was discovered when it passed the Earth at twice the distance of the Moon 36 Hermes was considered a threat because it was lost after its discovery thus its orbit and potential for collision with Earth were not known precisely 37 Hermes was only re discovered in 2003 and it is now known to be no threat for at least the next century 36 On June 14 1968 the 1 4 km diameter asteroid 1566 Icarus passed Earth at a distance of 0 042 AU 6 300 000 km or 16 times the distance of the Moon 38 During this approach Icarus became the first minor planet to be observed using radar with measurements obtained at the Haystack Observatory 39 and the Goldstone Tracking Station 40 This was the first close approach predicted years in advance Icarus had been discovered in 1949 and also earned significant public attention due to alarmist news reports 37 A year before the approach MIT students launched Project Icarus devising a plan to deflect the asteroid with rockets in case it was found to be on a collision course with Earth 41 Project Icarus received wide media coverage and inspired the 1979 disaster movie Meteor in which the US and the USSR join forces to blow up an Earth bound fragment of an asteroid hit by a comet 42 On March 23 1989 the 300 m 980 ft diameter Apollo asteroid 4581 Asclepius 1989 FC missed the Earth by 700 000 km 430 000 mi If the asteroid had impacted it would have created the largest explosion in recorded history equivalent to 20 000 megatons of TNT It attracted widespread attention because it was discovered only after the closest approach 43 In March 1998 early orbit calculations for recently discovered asteroid 35396 1997 XF11 showed a potential 2028 close approach 0 00031 AU 46 000 km from the Earth well within the orbit of the Moon but with a large error margin allowing for a direct hit Further data allowed a revision of the 2028 approach distance to 0 0064 AU 960 000 km with no chance of collision By that time inaccurate reports of a potential impact had caused a media storm 37 Known asteroids as of January 2018Video 0 55 July 23 2018 Risk Edit Asteroid 4179 Toutatis is a potentially hazardous object that passed within 4 lunar distances in September 2004 and currently has a minimum possible distance of 2 5 lunar distances From the late 1990s a typical frame of reference in searches for NEOs has been the scientific concept of risk The risk that any near Earth object poses is viewed having regard to both the culture and the technology of human society Through history humans have associated NEOs with changing risks based on religious philosophical or scientific views as well as humanity s technological or economical capability to deal with such risks 6 Thus NEOs have been seen as omens of natural disasters or wars harmless spectacles in an unchanging universe the source of era changing cataclysms 6 or potentially poisonous fumes during Earth s passage through the tail of Halley s Comet in 1910 44 and finally as a possible cause of a crater forming impact that could even cause extinction of humans and other life on Earth 6 The potential of catastrophic impacts by near Earth comets was recognised as soon as the first orbit calculations provided an understanding of their orbits in 1694 Edmond Halley presented a theory that Noah s flood in the Bible was caused by a comet impact 45 Human perception of near Earth asteroids as benign objects of fascination or killer objects with high risk to human society has ebbed and flowed during the short time that NEAs have been scientifically observed 12 Scientists have recognised the threat of impacts that create craters much bigger than the impacting bodies and have indirect effects on an even wider area since the 1980s after the confirmation of a theory that the Cretaceous Paleogene extinction event in which the non avian dinosaurs died out 65 million years ago was caused by a large asteroid impact 6 46 The awareness of the wider public of the impact risk rose after the observation of the impact of the fragments of Comet Shoemaker Levy 9 into Jupiter in July 1994 6 46 In 1998 the movies Deep Impact and Armageddon popularised the notion that near Earth objects could cause catastrophic impacts 46 Also at that time a conspiracy theory arose about the supposed 2003 impact of the fictitious planet Nibiru which persisted on the internet as the predicted impact date was moved to 2012 and then 2017 47 Risk scales Edit There are two schemes for the scientific classification of impact hazards from NEOs the simple Torino scale which rates the risks of impacts in the next 100 years according to impact energy and impact probability using integer numbers between 0 and 10 48 49 and the more complex Palermo Technical Impact Hazard Scale which ascribes ratings that can be any positive or negative real number these ratings depend on the background impact frequency impact probability and time until possible impact 50 On both scales risks of any concern are indicated by values above zero 48 50 Magnitude of risk Edit The annual background frequency used in the Palermo scale for impacts of energy greater than E megatonnes is estimated as 50 f B 0 03 E 0 8 displaystyle f B 0 03E 0 8 For instance this formula implies that the expected value of the time from now until the next impact greater than 1 megatonne is 33 years and that when it occurs there is a 50 chance that it will be above 2 4 megatonnes This formula is only valid over a certain range of E However another paper 51 published in 2002 the same year as the paper on that the Palermo scale is based found a power law with different constants f B 0 00737 E 0 9 displaystyle f B 0 00737E 0 9 This formula gives considerably lower rates for a given E For instance it gives the rate for bolides of 10 megatonnes or more like the Tunguska explosion as 1 per thousand years rather than 1 per 210 years as in the Palermo formula However the authors give a rather large uncertainty once in 400 to 1800 years for 10 megatonnes due in part to uncertainties in determining the energies of the atmospheric impacts that they used in their determination Highly rated risks Edit NASA maintains an automated system to evaluate the threat from known NEOs over the next 100 years which generates the continuously updated Sentry Risk Table 52 All or nearly all of the objects are highly likely to drop off the list eventually as more observations come in reducing the uncertainties and enabling more accurate orbital predictions 52 53 In March 2002 163132 2002 CU11 became the first asteroid with a temporarily positive rating on the Torino Scale with about a 1 in 9 300 chance of an impact in 2049 54 Additional observations reduced the estimated risk to zero and the asteroid was removed from the Sentry Risk Table in April 2002 55 It is now known that within the next two centuries 2002 CU11 will pass the Earth at a safe closest distance perigee of 0 00425 AU 636 000 km 395 000 mi on August 31 2080 56 Radar image of asteroid 1950 DA Asteroid 1950 DA was lost after its 1950 discovery since its observations over just 17 days were insufficient to precisely determine its orbit it was rediscovered on December 31 2000 It has a diameter of about a kilometer 0 6 miles and an impact would therefore be globally catastrophic It was observed by radar during its close 2001 approach allowing much more precise orbit calculations Although this asteroid will not strike for at least 800 years and thus has no Torino scale rating it was added to the Sentry list in April 2002 as the first object with a Palermo scale value greater than zero 57 58 The then calculated 1 in 300 maximum chance of impact and 0 17 Palermo scale value was roughly 50 greater than the background risk of impact by all similarly large objects until 2880 59 Uncertainties in the orbit calculations were further reduced using additional radar observations in 2012 and this decreased the odds of an impact 60 Taking all radar and optical observations through 2021 into account the probability of impact in March 2880 is as of June 2022 update assessed at 1 in 34 000 52 The corresponding Palermo scale value of 2 05 is still among the highest for all objects on the Sentry List Table 52 On December 24 2004 370 m 1 210 ft asteroid 99942 Apophis at the time known only by its provisional designation 2004 MN4 was assigned a 4 on the Torino scale the highest rating given to date as the information available at the time translated to a 2 7 chance of Earth impact on Friday April 13 2029 By December 28 2004 additional observations had significantly reduced the uncertainty zone for the 2029 approach and it no longer included the Earth The 2029 risk of impact consequently dropped to zero but later potential impact dates were still rated 1 on the Torino scale Further observations lowered the 2036 risk to a Torino rating of 0 in August 2006 In 2021 Apophis was removed from the Sentry Risk Table In February 2006 144898 2004 VD17 was assigned a Torino Scale rating of 2 due to a close encounter predicted for May 4 2102 61 After additional observations allowed increasingly precise predictions the Torino rating was lowered first to 1 in May 2006 then to 0 in October 2006 and the asteroid was removed from the Sentry Risk Table entirely in February 2008 55 As of 2021 update 2010 RF12 is listed with the highest chance of impacting Earth at 1 in 22 on September 5 2095 At only 7 m 23 ft across the asteroid however is much too small to be considered a potentially hazardous asteroid and it poses no serious threat the possible 2095 impact therefore rates only 3 32 on the Palermo Scale 52 Observations during the August 2022 close approach are expected to ascertain whether the asteroid will impact or miss Earth in 2095 62 Projects to minimize the threat Edit Main article Asteroid impact avoidance Annual NEA discoveries by survey all NEAs top and NEAs gt 1 km bottom NEOWISE first four years of data starting in December 2013 animated April 20 2018 The first astronomical program dedicated to the discovery of near Earth asteroids was the Palomar Planet Crossing Asteroid Survey The link to impact hazard the need for dedicated survey telescopes and options to head off an eventual impact were first discussed at a 1981 interdisciplinary conference in Snowmass Colorado 46 Plans for a more comprehensive survey named the Spaceguard Survey were developed by NASA from 1992 under a mandate from the United States Congress 63 64 To promote the survey on an international level the International Astronomical Union IAU organised a workshop at Vulcano Italy in 1995 63 and set up the Spaceguard Foundation also in Italy a year later 7 In 1998 the United States Congress gave NASA a mandate to detect 90 of near earth asteroids over 1 km 0 62 mi diameter that threaten global devastation by 2008 64 65 Several surveys have undertaken Spaceguard activities an umbrella term including Lincoln Near Earth Asteroid Research LINEAR Spacewatch Near Earth Asteroid Tracking NEAT Lowell Observatory Near Earth Object Search LONEOS Catalina Sky Survey CSS Campo Imperatore Near Earth Object Survey CINEOS Japanese Spaceguard Association Asiago DLR Asteroid Survey ADAS and Near Earth Object WISE NEOWISE As a result the ratio of the known and the estimated total number of near Earth asteroids larger than 1 km in diameter rose from about 20 in 1998 to 65 in 2004 7 80 in 2006 65 and 93 in 2011 The original Spaceguard goal has thus been met only three years late 8 66 As of November 2021 update 891 NEAs larger than 1 km have been discovered 1 or 97 of an estimated total of about 920 67 In 2005 the original USA Spaceguard mandate was extended by the George E Brown Jr Near Earth Object Survey Act which calls for NASA to detect 90 of NEOs with diameters of 140 m 460 ft or greater by 2020 9 As of January 2020 update it is estimated that less than half of these have been found but objects of this size hit the earth only about once in 2000 years 68 In January 2016 NASA announced the creation of the Planetary Defense Coordination Office PDCO to track NEOs larger than about 30 50 m 98 164 ft in diameter and coordinate an effective threat response and mitigation effort 10 69 Survey programs aim to identify threats years in advance giving humanity time to prepare a space mission to avert the threat REP STEWART are we technologically capable of launching something that could intercept an asteroid DR A HEARN No If we had spacecraft plans on the books already that would take a year I mean a typical small mission takes four years from approval to start to launch Rep Chris Stewart R UT and Dr Michael F A Hearn April 10 2013 United States Congress 70 The ATLAS project by contrast aims to find impacting asteroids shortly before impact much too late for deflection maneuvers but still in time to evacuate and otherwise prepare the affected Earth region 71 Another project the Zwicky Transient Facility ZTF which surveys for objects that change their brightness rapidly 72 also detects asteroids passing close to Earth 73 Further information List of near Earth object observation projects Scientists involved in NEO research have also considered options for actively averting the threat if an object is found to be on a collision course with Earth 46 All viable methods aim to deflect rather than destroy the threatening NEO because the fragments would still cause widespread destruction 13 Deflection which means a change in the object s orbit months to years prior to the predicted impact also requires orders of magnitude less energy 13 Number and classification Edit Cumulative discoveries of near Earth asteroids known by size 1980 2023 Near Earth objects are classified as meteoroids asteroids or comets depending on size composition and orbit Those which are asteroids can additionally be members of an asteroid family and comets create meteoroid streams that can generate meteor showers As of November 4 2021 update and according to statistics maintained by CNEOS 27 440 NEOs have been discovered Only 117 0 43 of them are comets whilst 27 323 99 57 are asteroids 2 224 of those NEOs are classified as potentially hazardous asteroids PHAs 1 As of November 2021 update over 1 200 NEAs appear on the Sentry impact risk page at the NASA website 52 Over 1 000 of these NEAs are less than 50 meters in diameter and none of the listed objects are placed even in the green zone Torino Scale 1 meaning that none warrant the attention of the general public 48 Observational biases Edit The main problem with estimating the number of NEOs is that the probability of detecting one is influenced by a number of aspects of the NEO starting naturally with its size but also including the characteristics of its orbit and the reflectivity of its surface 74 What is easily detected will be more counted 75 and these observational biases need to be compensated when trying to calculate the number of bodies in a population from the list of its detected members 74 Artist s impression of an asteroid that orbits closer to the Sun than Earth s orbit Bigger asteroids reflect more light 75 and the two biggest Near Earth objects 433 Eros and 1036 Ganymed were naturally also among the first to be detected 76 1036 Ganymed is about 35 km 22 mi in diameter and 433 Eros is about 17 km 11 mi in diameter 76 The other major detection bias is that it is much easier to spot objects on the night side of Earth The day sky near the Sun is much brighter than the night sky and there is therefore much better contrast in the night sky 75 The night side searcher is also looking at the sunlit side of the asteroids while in the daytime sky a searcher looks towards the sun and sees the unlit backside of the object In addition opposition surge makes asteroids even brighter when the Earth is close to the axis of sunlight The combined effect is equivalent to the comparison of a Full moon at night to a New Moon in daytime and the light of the Sun lit asteroids has been called full asteroid similar to a full moon 75 Evidencing this bias and as depicted in the diagram below over half 53 of the known Near Earth objects were discovered in just 3 8 of the sky in a 22 5 cone facing directly away from the Sun and the vast majority 87 were first found in only 15 of the sky in the 45 cone facing away from the Sun 77 The most practical way around this opposition bias is to use thermal infrared telescopes in space that observe their heat emissions instead of the light they reflect with a sensitivity that is almost independent of the illumination 75 Asteroids with orbits that make them spend more time on the day side of the Earth are therefore less likely to be discovered than those that spend most of their time beyond the orbit of the Earth For example one study noted that detection of bodies in low eccentricity Earth crossing orbits is favored making Atens more likely to be detected than Apollos 78 Such observational biases must be identified and quantified to determine NEO populations as studies of asteroid populations then take those known observational selection biases into account to make a more accurate assessment 79 In the year 2000 and taking into account all known observational biases it was estimated that there are approximately 900 near Earth asteroids of at least kilometer size or technically and more accurately with an absolute magnitude brighter than 17 75 74 Near Earth asteroids NEAs Edit Asteroid Toutatis from Paranal These are asteroids in a near Earth orbit without the tail or coma of a comet As of November 2022 update 30 503 near Earth asteroids are known 2 304 of which are both sufficiently large and may come sufficiently close to Earth to be classified as potentially hazardous 1 NEAs survive in their orbits for just a few million years 22 They are eventually eliminated by planetary perturbations causing ejection from the Solar System or a collision with the Sun a planet or other celestial body 22 With orbital lifetimes short compared to the age of the Solar System new asteroids must be constantly moved into near Earth orbits to explain the observed asteroids The accepted origin of these asteroids is that main belt asteroids are moved into the inner Solar System through orbital resonances with Jupiter 22 The interaction with Jupiter through the resonance perturbs the asteroid s orbit and it comes into the inner Solar System The asteroid belt has gaps known as Kirkwood gaps where these resonances occur as the asteroids in these resonances have been moved onto other orbits New asteroids migrate into these resonances due to the Yarkovsky effect that provides a continuing supply of near Earth asteroids 80 Compared to the entire mass of the asteroid belt the mass loss necessary to sustain the NEA population is relatively small totalling less than 6 over the past 3 5 billion years 22 The composition of near Earth asteroids is comparable to that of asteroids from the asteroid belt reflecting a variety of asteroid spectral types 81 A small number of NEAs are extinct comets that have lost their volatile surface materials although having a faint or intermittent comet like tail does not necessarily result in a classification as a near Earth comet making the boundaries somewhat fuzzy The rest of the near Earth asteroids are driven out of the asteroid belt by gravitational interactions with Jupiter 22 82 Many asteroids have natural satellites minor planet moons As of October 2021 update 85 NEAs were known to have at least one moon including three known to have two moons 83 The asteroid 3122 Florence one of the largest PHAs 27 with a diameter of 4 5 km 2 8 mi has two moons measuring 100 300 m 330 980 ft across which were discovered by radar imaging during the asteroid s 2017 approach to Earth 84 In May 2022 an algorithm known as Tracklet less Heliocentric Orbit Recovery or THOR and developed by University of Washington researchers to discover asteroids in the solar system was announced as a success 85 The International Astronomical Union s Minor Planet Center confirmed a series of first candidate asteroids identified by the algorithm 86 Size distribution Edit Known near Earth asteroids by size While the size of a very small fraction of these asteroids is known to better than 1 from radar observations from images of the asteroid surface or from stellar occultations the diameter of the vast majority of near Earth asteroids has only been estimated on the basis of their brightness and a representative asteroid surface reflectivity or albedo which is commonly assumed to be 14 28 Such indirect size estimates are uncertain by over a factor of 2 for individual asteroids since asteroid albedos can range at least as low as 5 and as high as 30 This makes the volume of those asteroids uncertain by a factor of 8 and their mass by at least as much since their assumed density also has its own uncertainty Using this crude method an absolute magnitude of 17 75 roughly corresponds to a diameter of 1 km 0 62 mi 28 and an absolute magnitude of 22 0 to a diameter of 140 m 460 ft 2 Diameters of intermediate precision better than from an assumed albedo but not nearly as precise as good direct measurements can be obtained from the combination of reflected light and thermal infrared emission using a thermal model of the asteroid to estimate both its diameter and its albedo In May 2016 technologist Nathan Myhrvold questioned the precision of such asteroid diameter estimates arising from thermal modeling of measurements by the Wide field Infrared Survey Explorer and NEOWISE missions 87 88 89 The original version of his criticism itself faced criticism for its methodology 90 and did not pass peer review 88 91 but a revised version was subsequently published 92 93 In 2000 NASA reduced from 1 000 2 000 to 500 1 000 its estimate of the number of existing near Earth asteroids over one kilometer in diameter or more exactly brighter than an absolute magnitude of 17 75 94 95 Shortly thereafter the LINEAR survey provided an alternative estimate of 1 227 170 90 96 In 2011 on the basis of NEOWISE observations the estimated number of one kilometer NEAs was narrowed to 981 19 of which 93 had been discovered at the time while the number of NEAs larger than 140 meters across was estimated at 13 200 1 900 8 66 The NEOWISE estimate differed from other estimates primarily in assuming a slightly lower average asteroid albedo which produces larger estimated diameters for the same asteroid brightness This resulted in 911 then known asteroids at least 1 km across as opposed to the 830 then listed by CNEOS from the same inputs but assuming a slightly higher albedo 97 In 2017 two studies using an improved statistical method reduced the estimated number of NEAs brighter than absolute magnitude 17 75 approximately over one kilometer in diameter slightly to 921 20 67 98 The estimated number of near Earth asteroids brighter than absolute magnitude of 22 0 approximately over 140 m across rose to 27 100 2 200 double the WISE estimate 98 of which about a third were known as of 2018 The number of asteroids brighter than H 25 which corresponds to about 40 m 130 ft in diameter is estimated at 840 000 23 000 of which about 1 3 percent had been discovered by February 2016 the number of asteroids brighter than H 30 larger than 3 5 m 11 ft is estimated at 400 100 million of which about 0 003 percent had been discovered by February 2016 98 As of January 12 2023 update and using diameters mostly estimated crudely from a measured absolute magnitude and an assumed albedo 859 NEAs listed by CNEOS including 152 PHAs measure at least 1 km in diameter and 10 362 known NEAs including 2322 PHAs are larger than 140 m in diameter 1 The smallest known near Earth asteroid is 2008 TS26 with an absolute magnitude of 33 2 29 corresponding to an estimated diameter of about 1 m 3 3 ft 99 The largest such object is 1036 Ganymed 29 with an absolute magnitude of 9 45 and directly measured irregular dimensions which are equivalent to a diameter of about 38 km 24 mi 100 Orbital classification Edit Types of near Earth asteroid orbits Near Earth asteroids are divided into groups based on their semi major axis a perihelion distance q and aphelion distance Q 2 22 The Atiras or Apoheles have orbits strictly inside Earth s orbit an Atira asteroid s aphelion distance Q is smaller than Earth s perihelion distance 0 983 AU That is Q lt 0 983 AU which implies that the asteroid s semi major axis is also less than 0 983 AU 101 The group of Atira Apohele asteroids compared to the orbits of the terrestrial planets of the Solar System The Atens have a semi major axis of less than 1 AU and cross Earth s orbit Mathematically a lt 1 0 AU and Q gt 0 983 AU 0 983 AU is Earth s perihelion distance The Aten group compared to the orbits of the terrestrial planets of the Solar System The Apollos have a semi major axis of more than 1 AU and cross Earth s orbit Mathematically a gt 1 0 AU and q lt 1 017 AU 1 017 AU is Earth s aphelion distance Location of the Apollo asteroids compared to the orbits of the terrestrial planets of the Solar System The Amors have orbits strictly outside Earth s orbit an Amor asteroid s perihelion distance q is greater than Earth s aphelion distance 1 017 AU Amor asteroids are also near earth objects so q lt 1 3 AU In summary 1 017 AU lt q lt 1 3 AU This implies that the asteroid s semi major axis a is also larger than 1 017 AU Some Amor asteroid orbits cross the orbit of Mars The Amor asteroid group compared to the orbits of the terrestrial planets of the Solar System Note Some authors define Atens differently they define it as being all the asteroids with a semi major axis of less than 1 AU 102 103 That is they consider the Atiras to be part of the Atens 103 Historically until 1998 there were no known or suspected Atiras so the distinction wasn t necessary Atiras and Amors do not cross the Earth s orbit and are not immediate impact threats but their orbits may change to become Earth crossing orbits in the future 104 22 As of November 4 2021 update 26 Atiras 2 113 Atens 15 186 Apollos and 9 998 Amors have been discovered and cataloged 1 Co orbital asteroids Edit The five Lagrangian points relative to Earth and possible orbits along gravitational contours Overview of the Inner Solar System with different co orbital bodies NEAs on a co orbital configuration have the same orbital period as the Earth All co orbital asteroids have special orbits that are relatively stable and paradoxically can prevent them from getting close to Earth Trojans Near the orbit of a planet there are five gravitational equilibrium points the Lagrangian points in which an asteroid would orbit the Sun in fixed formation with the planet Two of these 60 degrees ahead and behind the planet along its orbit designated L4 and L5 respectively are stable that is an asteroid near these points would stay there for millions of years even if lightly perturbed by other planets and by non gravitational forces As of March 2018 update Earth s only confirmed Trojan is 2010 TK7 circling Earth s L4 point 105 Horseshoe librators The region of stability around L4 and L5 also includes orbits for co orbital asteroids that run around both L4 and L5 Relative to the Earth and Sun the orbit can resemble the circumference of a horseshoe or may consist of annual loops that wander back and forth librate in a horseshoe shaped area In both cases the Sun is at the horseshoe s center of gravity Earth is in the gap of the horseshoe and L4 and L5 are inside the ends of the horseshoe By 2016 12 horseshoe librators of Earth have been discovered 106 The most studied and at about 5 km 3 1 mi largest is 3753 Cruithne which travels along bean shaped annual loops and completes its horseshoe libration cycle every 770 780 years 107 108 419624 2010 SO16 is an asteroid on a relatively stable circumference of a horseshoe orbit with a horseshoe libration period of about 350 years 109 Quasi satellites Quasi satellites are co orbital asteroids on a normal elliptic orbit with a higher eccentricity than Earth s which they travel in a way synchronised with Earth s motion Since the asteroid orbits the Sun slower than Earth when further away and faster than Earth when closer to the Sun when observed from Earth the quasi satellite appears to orbit Earth in a retrograde direction in one year even though it is not bound gravitationally By 2016 five asteroids were known to be a quasi satellite of Earth 469219 Kamoʻoalewa is Earth s closest quasi satellite in an orbit that has been stable for almost a century 110 Orbit calculations until 2016 showed that all quasi satellites and four of the horseshoe librators then known repeatedly transfer between horseshoe and quasi satellite orbits 110 One of these objects 2003 YN107 was observed during its transition from a quasi satellite orbit to a horseshoe orbit in 2006 it is expected to transfer back to a quasi satellite orbit sometime around year 2066 111 Temporary satellites NEAs can also transfer between solar orbits and distant Earth orbits becoming gravitationally bound temporary satellites According to simulations temporary satellites are typically caught when they pass the L1 or L2 Lagrangian points and Earth typically has at least one temporary satellite 1 m 3 3 ft across at any given time but they are too faint to detect by current surveys 112 As of November 2021 update the only observed transitions were those of asteroids 2006 RH120 and 2020 CD3 which were temporary satellites of Earth for at least a year since their capture dates 113 114 Meteoroids Edit In 1961 the IAU defined meteoroids as a class of solid interplanetary objects distinct from asteroids by their considerably smaller size 115 This definition was useful at the time because with the exception of the Tunguska event all historically observed meteors were produced by objects significantly smaller than the smallest asteroids then observable by telescopes 115 As the distinction began to blur with the discovery of ever smaller asteroids and a greater variety of observed NEO impacts revised definitions with size limits have been proposed from the 1990s 115 In April 2017 the IAU adopted a revised definition that generally limits meteoroids to a size between 30 µm and 1 m in diameter but permits the use of the term for any object of any size that caused a meteor thus leaving the distinction between asteroid and meteoroid blurred 116 Near Earth comets Edit Halley s Comet during its 0 10 AU 117 approach of Earth in May 1910 Near Earth comets NECs are objects in a near Earth orbit with a tail or coma Comet nuclei are typically less dense than asteroids but they pass Earth at higher relative speeds thus the impact energy of a comet nucleus is slightly larger than that of a similar sized asteroid 118 NECs may pose an additional hazard due to fragmentation the meteoroid streams which produce meteor showers may include large inactive fragments effectively NEAs 119 Although no impact of a comet in Earth s history has been conclusively confirmed the Tunguska event may have been caused by a fragment of Comet Encke 120 Comets are commonly divided between short period and long period comets Short period comets with an orbital period of less than 200 years originate in the Kuiper belt beyond the orbit of Neptune while long period comets originate in the Oort Cloud in the outer reaches of the Solar System 13 The orbital period distinction is of importance in the evaluation of the risk from near Earth comets because short period NECs are likely to have been observed during multiple apparitions and thus their orbits can be determined with some precision while long period NECs can be assumed to have been seen for the first and last time when they appeared during the Age of Science thus their approaches cannot be predicted well in advance 13 Since the threat from long period NECs is estimated to be at most 1 of the threat from NEAs and long period comets are very faint and thus difficult to detect at large distances from the Sun Spaceguard efforts have consistently focused on asteroids and short period comets 63 118 CNEOS even restricts its definition of NECs to short period comets 2 as of November 4 2021 update 117 such objects have been discovered 1 As of November 2021 update only 23 comets have been observed to pass within 0 1 AU 15 000 000 km 9 300 000 mi of Earth including 10 which are or have been short period comets 121 Two of these comets Halley s Comet and 73P Schwassmann Wachmann have been observed during multiple close approaches 121 The closest observed approach was 0 0151 AU 5 88 LD for Lexell s Comet on July 1 1770 121 After an orbit change due to a close approach of Jupiter in 1779 this object is no longer a NEC The closest approach ever observed for a current short period NEC is 0 0229 AU 8 92 LD for Comet Tempel Tuttle in 1366 121 This comet is the parent body of the Leonid meteor shower which also produced the Great Meteor Storm of 1833 122 Orbital calculations show that P 1999 J6 SOHO a faint sungrazing comet and confirmed short period NEC observed only during its close approaches to the Sun 123 passed Earth undetected at a distance of 0 0121 AU 4 70 LD on June 12 1999 124 Comet 109P Swift Tuttle which is also the source of the Perseid meteor shower every year in August has a roughly 130 year orbit that passes close to the Earth During the comet s September 1992 recovery when only the two previous returns in 1862 and 1737 had been identified calculations showed that the comet would pass close to Earth during its next return in 2126 with an impact within the range of uncertainty By 1993 even earlier returns back to at least 188 AD have been identified and the longer observation arc eliminated the impact risk The comet will pass Earth in 2126 at a distance of 23 million kilometers In 3044 the comet is expected to pass Earth at less than 1 6 million kilometers 125 Artificial near Earth objects Edit J002E3 discovery images taken on September 3 2002 J002E3 is in the circle Defunct space probes and final stages of rockets can end up in near Earth orbits around the Sun and be re discovered by NEO surveys when they return to Earth s vicinity In September 2002 astronomers found an object designated J002E3 The object was on a temporary satellite orbit around Earth leaving for a solar orbit in June 2003 Calculations showed that it was also on a solar orbit before 2002 but was close to Earth in 1971 J002E3 was identified as the third stage of the Saturn V rocket that carried Apollo 12 to the Moon 126 127 In 2006 two more apparent temporary satellites were discovered which were suspected of being artificial 127 One of them was eventually confirmed as an asteroid and classified as the temporary satellite 2006 RH120 127 The other 6Q0B44E was confirmed as an artificial object but its identity is unknown 127 Another temporary satellite was discovered in 2013 and was designated 2013 QW1 as a suspected asteroid It was later found to be an artificial object of unknown origin 2013 QW1 is no longer listed as an asteroid by the Minor Planet Center 127 128 In some cases active space probes on solar orbits have been observed by NEO surveys and erroneously catalogued as asteroids before identification During its 2007 flyby of Earth on its route to a comet ESA s space probe Rosetta was detected unidentified and classified as asteroid 2007 VN84 with an alert issued due to its close approach 129 The designation 2015 HP116 was similarly removed from asteroid catalogues when the observed object was identified with Gaia ESA s space observatory for astrometry 130 Impacts EditMain article Impact event When a near Earth object impacts Earth objects up to a few tens of metres across ordinarily explode in the upper atmosphere usually harmlessly with most or all of the solids vaporized and only small amounts of meteorites arriving to the Earth surface while larger objects hit the water surface forming tsunami waves or the solid surface forming impact craters 131 The frequency of impacts of objects of various sizes is estimated on the basis of orbit simulations of NEO populations the frequency of impact craters on the Earth and the Moon and the frequency of close encounters 132 133 The study of impact craters indicates that impact frequency has been more or less steady for the past 3 5 billion years which requires a steady replenishment of the NEO population from the asteroid main belt 22 One impact model based on widely accepted NEO population models estimates the average time between the impact of two stony asteroids with a diameter of at least 4 m 13 ft at about one year for asteroids 7 m 23 ft across which impacts with as much energy as the atomic bomb dropped on Hiroshima approximately 15 kilotonnes of TNT at five years for asteroids 60 m 200 ft across an impact energy of 10 megatons comparable to the Tunguska event in 1908 at 1 300 years for asteroids 1 km 0 62 mi across at half a million years and for asteroids 5 km 3 1 mi across at 18 million years 134 Some other models estimate similar impact frequencies 22 while others calculate higher frequencies 133 For Tunguska sized 10 megaton impacts the estimates range from one event every 2 000 3 000 years to one event every 300 years 133 Location and impact energy of small asteroids impacting Earth s atmosphere The second largest observed event after the Tunguska meteor was a 1 1 megaton air blast in 1963 near the Prince Edward Islands between South Africa and Antarctica which was detected only by infrasound sensors 135 However this may not have been a meteor 136 The third largest but by far best observed impact was the Chelyabinsk meteor of 15 February 2013 A previously unknown 20 m 66 ft asteroid exploded above this Russian city with an equivalent blast yield of 400 500 kilotons 135 The calculated orbit of the pre impact asteroid is similar to that of Apollo asteroid 2011 EO40 making the latter the meteor s possible parent body 137 On 7 October 2008 19 hours after it was first observed 4 m 13 ft asteroid 2008 TC3 blew up 37 km 23 mi above the Nubian Desert in Sudan It was the first time that an asteroid was observed and its impact was predicted prior to its entry into the atmosphere as a meteor 138 10 7 kg of meteorites were recovered after the impact 139 On 2 January 2014 just 21 hours after it was the first asteroid to be discovered in 2014 2 4 m 2014 AA blew up in Earth s atmosphere above the Atlantic Ocean Far from any land the meteor explosion was only observed by three infrasound detectors of the Comprehensive Nuclear Test Ban Treaty Organization This impact was the second to be predicted 140 Further predicted impacts include 2018 LA around the border between Botswana and South Africa and 2019 MO off Puerto Rico but asteroid impact prediction remains in its infancy and successfully predicted asteroid impacts are rare The vast majority of impacts recorded by infrasound sensors designed to detect detonation of nuclear devices are not predicted 141 Observed impacts aren t restricted to the surface and atmosphere of Earth Dust sized NEOs have impacted man made spacecraft including NASA s Long Duration Exposure Facility which collected interplanetary dust in low Earth orbit for six years from 1984 115 Impacts on the Moon can be observed as flashes of light with a typical duration of a fraction of a second 142 The first lunar impacts were recorded during the 1999 Leonid storm 143 Subsequently several continuous monitoring programs were launched 142 144 145 As of March 2018 update the largest observed lunar impact occurred on 11 September 2013 lasted 8 seconds and was likely caused by an object 0 6 1 4 m 2 0 4 6 ft in diameter 144 Close approaches EditMain article List of asteroid close approaches to Earth Flyby of asteroid 2004 FH centre dot being followed by the sequence The other object that flashes by is an artificial satellite Each year several mostly small NEOs pass Earth closer than the distance of the Moon 146 On August 10 1972 a meteor that became known as the 1972 Great Daylight Fireball was witnessed by many people it moved north over the Rocky Mountains from the U S Southwest to Canada It was an Earth grazing meteoroid that passed within 57 km 35 mi of the Earth s surface and was filmed by a tourist at the Grand Teton National Park in Wyoming with an 8 millimeter color movie camera 147 On October 13 1990 Earth grazing meteoroid EN131090 was observed above Czechoslovakia and Poland moving at 41 74 km s 25 94 mi s along a 409 km 254 mi trajectory from south to north The closest approach to the Earth was 98 67 km 61 31 mi above the surface It was captured by two all sky cameras of the European Fireball Network which for the first time enabled geometric calculations of the orbit of such a body 148 On March 18 2004 LINEAR announced that a 30 m 98 ft asteroid 2004 FH would pass the Earth that day at only 42 600 km 26 500 mi about one tenth the distance to the Moon and the closest miss ever noticed until then They estimated that similar sized asteroids come as close about every two years 149 On March 31 2004 two weeks after 2004 FH 2004 FU162 set a new record for closest recorded approach above the atmosphere passing Earth s surface only 6 500 km 4 000 mi away about one Earth radius or one sixtieth of the distance to the Moon Because it was very small 6 meters 20 feet FU162 was detected only hours before its closest approach If it had collided with Earth it probably would have disintegrated harmlessly in the atmosphere 150 On February 4 2011 an asteroid designated 2011 CQ1 estimated at 0 8 2 6 m 2 6 8 5 ft in diameter passed within 5 500 km 3 400 mi of the Earth 151 On November 8 2011 asteroid 308635 2005 YU55 relatively large at about 360 m 1 180 ft in diameter passed within 324 600 km 201 700 mi 0 85 lunar distances of Earth 152 On February 15 2013 the 30 m 98 ft asteroid 367943 Duende 2012 DA14 passed approximately 27 700 km 17 200 mi above the surface of Earth closer than satellites in geosynchronous orbit 153 The asteroid was not visible to the unaided eye This was the first close passage of an object discovered during a previous passage and was thus the first to be predicted well in advance 154 Diagram showing spacecraft and asteroids past and future between the Earth and the Moon Exploratory missions EditSome NEOs are of special interest because they can be physically explored with lower mission velocity than is necessary for even the Moon due to their combination of low velocity with respect to Earth and weak gravity They may present interesting scientific opportunities both for direct geochemical and astronomical investigation and as potentially economical sources of extraterrestrial materials for human exploitation 11 This makes them an attractive target for exploration 155 Missions to NEAs Edit 433 Eros as seen by NASA s NEAR probe Image mosaic of asteroid 101955 Bennu target of NASA s OSIRIS REx probe Further information List of minor planets and comets visited by spacecraft The IAU held a minor planets workshop in Tucson Arizona in March 1971 At that point launching a spacecraft to asteroids was considered premature the workshop only inspired the first astronomical survey specifically aiming for NEAs 12 Missions to asteroids were considered again during a workshop at the University of Chicago held by NASA s Office of Space Science in January 1978 Of all of the near Earth asteroids NEA that had been discovered by mid 1977 it was estimated that spacecraft could rendezvous with and return from only about 1 in 10 using less propulsive energy than is necessary to reach Mars It was recognised that due to the low surface gravity of all NEAs moving around on the surface of an NEA would cost very little energy and thus space probes could gather multiple samples 12 Overall it was estimated that about one percent of all NEAs might provide opportunities for human crewed missions or no more than about ten NEAs known at the time A five fold increase in the NEA discovery rate was deemed necessary to make a crewed mission within ten years worthwhile 12 The first near Earth asteroid to be visited by a spacecraft was 17 km 11 mi asteroid 433 Eros when NASA s Near Earth Asteroid Rendezvous NEAR probe orbited it from February 2001 landing on the asteroid surface in February 2002 16 A second near Earth asteroid the 535 m 1 755 ft long peanut shaped 25143 Itokawa was visited in September 2005 by JAXA s Hayabusa mission 17 which succeeded in taking material samples back to Earth A third near Earth asteroid the 2 26 km 1 40 mi long elongated 4179 Toutatis was explored by CNSA s Chang e 2 spacecraft during a flyby in December 2012 18 57 The 980 m 3 220 ft Apollo asteroid 162173 Ryugu is the target of JAXA s Hayabusa2 mission The space probe was launched in December 2014 arrived at the asteroid in June 2018 and returned a sample to Earth in December 2020 19 The 500 m 1 600 ft Apollo asteroid 101955 Bennu which as of November 2021 update has the highest cumulative Palermo scale rating 1 41 for several close encounters between 2178 and 2290 52 is the target of NASA s OSIRIS REx probe The New Frontiers program mission was launched in September 2016 20 On its two year journey to Bennu the probe had searched for Earth s Trojan asteroids 156 rendezvoused with Bennu in August 2018 and had entered into orbit around the asteroid in December 2018 OSIRIS REx will return samples from the asteroid in September 2023 20 In April 2012 the company Planetary Resources announced its plans to mine asteroids commercially In a first phase the company reviewed data and selected potential targets among NEAs In a second phase space probes would be sent to the selected NEAs mining spacecraft would be sent in a third phase 157 Planetary Resources launched two testbed satellites in April 2015 158 and January 2018 159 and the first prospecting satellite for the second phase was planned for a 2020 launch prior to the company closing and its assets purchased by ConsnSys Space in 2018 158 160 The Near Earth Object Surveillance Mission NEOSM is planned for launch no earlier than 2025 to discover and characterize the orbit of most of the potentially hazardous asteroids larger than 140 m 460 ft over the course of its mission 161 On September 26 2022 the DART spacecraft impacted Dimorphos in a test of a method of planetary defense against near Earth objects Missions to NECs Edit 67P Churyumov Gerasimenko as seen by ESA s Rosetta probe The first near Earth comet visited by a space probe was 21P Giacobini Zinner in 1985 when the NASA ESA probe International Cometary Explorer ICE passed through its coma In March 1986 ICE along with Soviet probes Vega 1 and Vega 2 ISAS probes Sakigake and Suisei and ESA probe Giotto flew by the nucleus of Halley s Comet In 1992 Giotto also visited another NEC 26P Grigg Skjellerup 13 In November 2010 the NASA probe Deep Impact flew by the near Earth comet 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