. This gives the distance from Earth's orbit at the points where the solid curves cross the yellow curve. Apophis has a low inclination orbit (3.3°) that varies from just outside the orbit of
Venus (0.746 AU, as compared to the aphelion of Venus, 0.728) to just outside the orbit of
Earth (1.099 AU). Although its orbit changes slightly each time it comes close to Earth, at present it comes near Earth once in 7.75 years on average (four times between April 14, 1998, and April 13, 2029). Because of its eccentric orbit, these moments are not evenly spaced and tend to occur between December and April, when Apophis is in the outer portions of its orbit. In fact, the eccentricity and semi-major axis are such that (before 2029) Apophis is always receding from Earth around May 1 and is always approaching around December 2. At the
ascending node (where Apophis crosses the plane of Earth's orbit from south to north) Apophis is very close to where Earth is around 13 April of any year, and this is what gives rise to close encounters such as the one on 13 April 2029. The orbit also passes south of where the earth is in mid December, producing for example the close approaches of December 16, 1889, and December 18, 1939. After the 2029 Earth approach, the orbit will change dramatically. The period will change from around of a year to a bit under . It will still come very close to Earth's yearly April 13 location. It will no longer pass close to Earth's yearly mid-December location, but will then pass close to Earth's mid-September location. This will cause a close encounter on 11 September 2102, after which the uncertainty in the location of Apophis will increase rapidly with time.
2029 close approach The closest known approach of Apophis will occur on 13 April 2029, at 21:46
UT, when Apophis will pass Earth at a distance of about above the surface. Using the June 2024 orbit solution which includes the
Yarkovsky effect, the
3-sigma uncertainty region in the 2029 approach distance is about ±3.3 km. The distance, a hair's breadth in astronomical terms, is five times the
radius of the Earth, one tenth the distance to the
Moon, and closer than the ring of
geostationary satellites currently orbiting the Earth. It will be the closest asteroid of its size in recorded history. On that date, it will become as bright as magnitude 3.1 (visible to the
naked eye from rural as well as darker suburban areas, visible with
binoculars from most locations). The close approach will be visible from
Europe,
Africa, and western
Asia. Over the course of about a day, Apophis will move northwest from
Centaurus to
Perseus and then southwest to
Pisces, an arc of 205°. Approaching Earth its speed relative to Earth will be 6.0 km/s. Earth's gravity will accelerate it to 7.4 km/s at the time of closest approach, and then slow it back down to 6 as it departs. During the approach, Earth will
perturb Apophis from an
Aten-class orbit with a
semi-major axis of 0.92
AU to an
Apollo-class orbit with a semi-major axis of 1.1 AU.
Perihelion will lift from 0.746 AU to 0.895 AU and aphelion will lift from 1.10 AU to 1.31 AU. Apophis also encounters the Moon at from the lunar surface, after the encounter with Earth. During the 2029 approach, Apophis's brightness will peak at
magnitude 3.1, easily visible to the naked eye, with a maximum angular speed of 42° per hour. The maximum apparent
angular diameter will be approximately 2
arcseconds. This is roughly equivalent to the
angular diameter of
Neptune from Earth. Therefore, the asteroid will be barely
resolved by ground-based telescopes not equipped with
adaptive optics but very well resolved by those that are. Because the approach will be so close,
tidal forces are likely to alter Apophis's rotation axis, but Apophis will not approach within the
Roche limit where it would be broken up by tidal forces. A partial resurfacing of the asteroid is possible, which might change its spectral class from a
weathered Sq- to an unweathered
Q-type.
2036 approaches In 2036, Apophis will pass the Earth at a third the distance of the Sun in both March and December. Using the 2024 orbit solution, the Earth approach on 27 March 2036, will be no closer than , but more likely about . For comparison, the planet Venus will be closer to Earth at on 30 May 2036. On 31 December 2036, Apophis will be a little bit further away than the March approach at about .
2051 approach Around 19–20 April 2051, Apophis will pass about from Earth and it will be the first time since 2029 that Apophis will pass within 10 million km of Earth.
2066 and 2068 Although early simulations showed that there was a chance Apophis could hit the earth on 12 April 2068, this was later excluded and
JPL Horizons calculates that Apophis will be about from Earth, making the asteroid much farther than the Sun. By 2116, the
JPL Small-Body Database and
NEODyS close approach data start to become
divergent. In April 2116, Apophis is expected to pass about from Earth, but could pass as close as or as far as .
Refinement of close approach predictions Six months after discovery, and shortly after a close approach to Earth on 21 December 2004, the improved orbital estimates led to the prediction of a very close approach on 13 April 2029, by both NASA's automatic
Sentry system and
NEODyS, a similar automatic program run by the
University of Pisa and the
University of Valladolid. Subsequent observations decreased the uncertainty in Apophis's trajectory and the probability of an impact event in 2029 temporarily climbed, peaking at 2.7% (1 in 37) on 27 December 2004, when the uncertainty region had shrunk to 83,000 km. This probability, combined with its size, caused Apophis to be assessed at level 4 on the
Torino scale and 1.10 on the
Palermo scale (corresponding to an impact hazard over 12 times the background level), scales scientists use to represent how dangerous a given asteroid is to Earth. These are the highest values at which any object has been rated on either scale. The chance that there would be an impact in 2029 was eliminated later in the day of 27 December 2004, as a result of a
precovery image that extended the observation arc back to March 2004. The danger of a 2036 passage was lowered to level 0 on the Torino scale in August 2006. With a cumulative Palermo scale rating of −3.22, the risk of impact from Apophis is less than one thousandth the background hazard level. In July 2005, former
Apollo astronaut
Rusty Schweickart, as chairman of the
B612 Foundation, formally asked NASA to investigate the possibility that the asteroid's post-2029 orbit could be in
orbital resonance with Earth, which would increase the probability of future impacts. Schweickart also asked NASA to investigate whether a
transponder should be placed on the asteroid to enable more accurate tracking of how its orbit is affected by the
Yarkovsky effect.
2011 observations On 31 January 2011, astronomers took the first new images of Apophis in more than three years.
2013–2015 refinement The close approach in 2029 will substantially alter the object's orbit, prompting Jon Giorgini of JPL to say in 2011, "If we get radar ranging in 2013 [the next good opportunity], we should be able to predict the location of out to at least 2070." Apophis passed within of Earth in 2013, allowing astronomers to refine the trajectory for future close passes. Just after the closest approach on 9 January 2013, the asteroid peaked at an
apparent magnitude of about 15.6. The
Goldstone radar observed Apophis during that approach from 3 January through 17 January. The
Arecibo Observatory observed Apophis once it entered Arecibo's field of view after 13 February 2013. The 2013 observations basically ruled out any chance of a 2036 impact. A NASA assessment as of 21 February 2013, that did not use the January and February 2013 radar measurements gave an impact probability of 2.3 in a million for 2068. As of 6 May 2013, using observations through 15 April 2013, the odds of an impact on 12 April 2068, as calculated by the JPL Sentry risk table had increased slightly to 3.9 in a million (1 in 256,000). Incorporating early 2015 observations, the April 12, 2068, impact probability was 6.7 in a million (1 in 150,000), and the asteroid had a cumulative 9 in a million (1 in 110,000) chance of impacting Earth before 2106. After 2015, its orbit kept it near the Sun from the perspective of Earth, precluding telescopic observations. It was not further than 60 degrees from the Sun between April 2014 and December 2019.
2020–2021 observations No observations of Apophis were made between January 2015 and February 2019 but observations began again in January 2020. In March 2020, astronomers
David Tholen and Davide Farnocchia measured the acceleration of Apophis due to the
Yarkovsky effect for the first time, significantly improving the prediction of its orbit past the 2029 flyby. Tholen and Farnocchia found that the Yarkovsky effect causes the
semi-major axis to decrease by about 170 metres per year, causing an increase in
ecliptic longitude that is
quadratic in time. In late 2020 Apophis approached the Earth and passed from Earth on 6 March 2021, brightening to +15
mag at that time. Radar observations of Apophis were carried out at Goldstone in March 2021. The asteroid has been observed by
NEOWISE (between December 2020 and April 2021) and by
NEOSSat (in January 2021). These observations showed that the
impact parameter ζ (basically how far behind Earth Apophis would pass if it were not deflected by the gravitational pull of Earth) in 2029 will be about 47,363 km, less than the earlier nominal value of 47,659 km by 296 km because of the
Yarkovsky effect. This means that Apophis will not hit Earth in the coming century, in particular avoiding the keyhole 212.14 km below nominal that would have led to a collision in 2068. Apophis was the target of an observing campaign by the
International Asteroid Warning Network, resulting in the collection of
light curves,
spectra, and
astrometry. The observations were used to practice and coordinate the response to an actual impact threat. Ignoring all earlier observations, the estimated probability of an impact in 2029 reached 16 percent before going down to zero. On 21 February 2021, Apophis was removed from the
Sentry Risk Table, as an impact in the next 100 years was finally ruled out. Several
occultations of bright stars (
apparent magnitude 8–11) by Apophis occurred in March and April 2021. A total of five separate occultations were observed successfully, marking the first time that an asteroid as small as Apophis was observed using the
occultation method (beating the previous record set in 2019 by asteroid
3200 Phaethon, which is more than ten times the size of Apophis). The first event, on 7 March, was successfully observed from the United States by multiple observers. The next potential occultation, which occurred on 11 March, was predicted to be visible from central Europe, but was not observed, mainly because of bad weather (two negative observations were recorded from
Greece). Another occultation occurred on 22 March, but larger-than-expected
residuals in the 7 March data had caused the majority of observers to be deployed outside of the actual path for the occultation, and it was observed only by a single observer from the United States,
amateur astronomer Roger Venable. This single detection then allowed the prediction of several more events that would have been unobservable otherwise, including an occultation on 4 April, which was observed from
New Mexico, again by Venable, alongside others. Two more occultations, observable on 10 and 11 April from
Japan and New Mexico, respectively, were seen by several observers each. The occultation measurements allowed refinement of the measurement of the asteroid size and orbit. On 9 March 2021, using radar observations from Goldstone taken on 3–8 March and three positive detections of the stellar occultation on 7 March 2021, Apophis became the asteroid with the most precisely measured Yarkovsky effect of all asteroids, at a
signal-to-noise ratio (SNR) of 186.4, surpassing
101955 Bennu (SNR=181.6). The 2021 apparition was the last opportunity to observe Apophis until shortly before its 2029 flyby.
History of impact estimates == Possible impact effects ==