List of Solar System objects by greatest aphelion

This is a list of Solar System objects by greatest aphelion or the greatest distance from the Sun that the orbit could take it if the Sun and object were the only objects in the universe. It is implied that the object is orbiting the Sun in a two-body solution without the influence of the planets, passing stars, or the galaxy. The aphelion can change significantly due to the gravitational influence of planets and other stars. Most of these objects are comets on a calculated path and may not be directly observable. For instance, comet Hale-Bopp was last seen in 2013 at magnitude 24 and continues to fade, making it invisible to all but the most powerful telescopes.
The maximum extent of the region in which the Sun's gravitational field is dominant, the Hill sphere, may extend to as calculated in the 1960s. But any comet currently more than about from the Sun can be considered lost to the interstellar medium. The nearest known star is Proxima Centauri at, followed by Alpha Centauri at about 4.35 light years.
Oort cloud comets orbit the Sun at great distances, but can then be perturbed by passing stars and the galactic tides. As they come into or leave the inner Solar System they may have their orbit changed by the planets, or alternatively be ejected from the Solar System. It is also possible they may collide with the Sun or a planet.
S/2021 N 1 takes over 27 years to orbit Neptune, comets can take up to 30 million years to orbit the Sun, and the Sun orbits the Milky Way in about 230 million years.

Satellite	Orbital period	Parent body	Percentage of parent body orbital period
S/2021 N 1	27.4	Neptune	16.6%
Oort cloud comet	30 million	Sun	13%
Sun	230 million	Milky Way	N/A

Explanation

Barycentric vs heliocentric orbits

As many of the objects listed below have some of the most extreme orbits of any objects in the Solar System, describing their orbit precisely can be particularly difficult and sensitive to the time the orbit is defined at. For most objects in the Solar System, a heliocentric reference frame is sufficient to explain their orbits. However, as the orbits of objects become closer to the Solar System's escape velocity, with long orbital periods on the order of hundreds or thousands of years, a different reference frame is required to describe their orbit: a barycentric reference frame. A barycentric reference frame measures the asteroid's orbit relative to the gravitational center of the entire Solar System, rather than just the Sun. Mostly due to the influence of the outer gas giants, the Solar System barycenter varies by up to twice the radius of the Sun.
This difference in position can lead to significant changes in the orbits of long-period comets and distant asteroids. Many comets have hyperbolic orbits in a heliocentric reference frame, but in a barycentric reference frame have much more firmly bound orbits, with only a small handful remaining truly hyperbolic.

Eccentricity and V_inf

The orbital parameter used to describe how non-circular an object's orbit is, is eccentricity. An object with an e of 0 has a perfectly circular orbit, with its perihelion distance being just as close to the Sun as its aphelion distance. An object with an e of between 0 and 1 will have a bound elliptical orbit. For example, an object with an e of ⅓ will have a perihelion twice as close to the Sun as its aphelion. As an object's e approaches 1, its orbit will be more and more elongated, and at e=1, the object's orbit will be
parabolic and unbound to the Solar System. An e greater than 1 will produce a hyperbolic orbit and still be unbound to the Solar System.
Although it describes how "unbound" an object's orbit is, eccentricity does not necessarily reflect how high an incoming velocity said object had before entering the Solar System. A clear example of this is the eccentricities of the two known interstellar objects as of October 2019, 1I/ʻOumuamua and 2I/Borisov. ʻOumuamua had an incoming V_inf of, but due to its low perihelion distance of only 0.255 AU, it had an eccentricity of 1.200. However, Borisov's V_inf was only slightly higher, at, but due to its higher perihelion distance of ~2.003 AU, its eccentricity was a comparably higher 3.340. In practice, no object originating from the Solar System should have an incoming heliocentric eccentricity much higher than 1, and should rarely have an incoming barycentric eccentricity of above 1, as that would imply that the object had originated from an indefinitely far distance from the Sun.

Orbital epochs

Due to having the most eccentric orbits of any Solar System body, a comet's orbit typically intersects one or more of the planets in the Solar System. As a result, the orbit of a comet is frequently perturbed significantly, even over the course of a single pass through the inner Solar System. Due to the changing orbit, it's necessary to provide a calculation of the orbit of the comet both before and after entering the inner Solar System. For example, Comet ISON was ~312 au from the Sun in 1600, and its remnants will be ~431 au from the Sun in 2400, both well outside of any significant gravitational influence from the planets.

Comets with greatest aphelion (2 body heliocentric)

Object	Heliocentric Aphelion Perihelion epoch	Barycentric Aphelion epoch 2200	Barycentric Aphelion epoch 1800
C/2004 R2		13000 AU	4000 AU
C/2015 O1		15000 AU	60000 AU
C/2012 S4		5700 AU	8400 AU
C/2012 CH₁₇		7283 AU	26000 AU
C/2008 C1		3822 AU	520 AU
C/1992 J1		3700 AU	75000 AU
C/2007 N3		2419 AU	64000 AU
C/2017 T2		2975 AU	84000 AU
C/1937 N1		7121 AU	16000 AU
C/1972 X1		5630 AU	4200 AU
C/2014 R3		12841 AU	19000 AU
C/2015 O1		21753 AU	52000 AU
C/2001 C1		ejection	98000 AU
C/2002 J4		ejection	59000 AU
C/1958 D1		1110 AU	7800 AU
C/1986 V1		8946 AU	5400 AU
C/2005 G1		40572 AU	110000 AU
C/2006 W3		8212 AU	5300 AU
C/2009 W2		3847 AU	4200 AU
C/2005 L3		6851 AU	33000 AU
C/2004 YJ₃₅		2480 AU	75000 AU
C/2003 H3		ejection	4900 AU
C/2010 L3		21094 AU	12000 AU
C/1902 R1		2306 AU	74000 AU
C/1889 G1		1575 AU	2100 AU
C/2007 VO₅₃		16835 AU	22000 AU

Distant comets with long observation arcs and/or barycentric

Examples of comets with a more well-determined orbit. Comets are extremely small relative to other bodies and hard to observe once they stop outgassing. Because they are typically discovered close to the Sun, it will take some time even thousands of years for them to actually travel out to great distances. The Whipple proposal might be able to detect Oort cloud objects at great distances, but probably not a particular object.

Comet West 70,000 AU
C/1999 F1 66,600 AU
C/2012 S4 5700 AU
Comet Hyakutake 3410 AU
C/1910 A1 about 2974 AU
C/1992 J1 3650 AU
C/2007 N3 2400 AU

Minor planets

A large number of trans-Neptunian objects – minor planets orbiting beyond the orbit of Neptune – have been discovered in recent years. Many TNOs have orbits that take them far beyond Pluto's aphelion of 49.3 AU. Some of these TNOs with an extreme aphelion are detached objects such as, which always reside in the outermost region of the Solar System, while for other TNOs, the extreme aphelion is due to an exceptionally high eccentricity such as for, which orbits the Sun at a distance between 4.1 and 2200 AU. The following is a list of minor planets with the largest aphelion in descending order.

Minor planets with a heliocentric aphelion greater than 400 AU

The following group of bodies have orbits with an aphelion above 400 AU, with 1-sigma uncertainties given to two significant digits. As of May 2024, there are 73 such bodies.

Object	Aphelion	Absolute Magnitude	Ref
A/2020 M4	29020.06 ±420	14.01 ±0.28
	20162.05 ±6000	14.08
A/2024 D1	3875.88 ±2456	11.45 ±0.52
	3559.58 ±220	6.19
541132 Leleākūhonua	2713.25 ±360	5.57 ±0.13
	2419.67 ±320	14.21 ±0.33
	2314.82 ±51	6.74±0.12
	2261.12 ±2.4	10.88
	2115.35 ±690	12.80±0.43
	2108.10 ±450	6.35 ±0.14
	2062.42 ±1.6	7.94
A/2022 B3	1957.25 ±11	16.56 ±0.76
	1877.78 ±1.3	7.12
	1718.93 ±50	6.84
	1717.16 ±300	14.10
	1418.77 ±320	6.72 ±0.24
A/2019 G2	1397.41 ±1.7	16.31 ±0.55
A/2021 E4	1388.62 ±1.2	14.26 ±0.45
A/2018 W3	1341.59 ±10	10.70 ±0.29
	1326.78 ±0.76	9.10
	1295.34 ±51	15.30
	1241.82 ±7.2	8.20
	1118.81 ±0.64	6.47
	1052.34 ±0.51	9.92 ±0.37
	1032.63 ±0.62	8.16 ±0.35
	1015.61 ±9.9	11.74 ±0.79
	1008.19 ±2.7	6.23 ±0.22
	1006.90±2.7	1.50
	990.67 ±0.62	14.55 ±0.37
	986.20 ±0.37	10.56 ±0.43
	933.55 ±2.5	4.34
	888.63 ±8.1	6.20
	859.76 ±4.7	8.38 ±0.52
	853.72 ±1.7	14.50 ±0.26
	846.98 ±0.49	9.30 ±0.42
	828.61 ±0.46	10.30
	816.45 ±11	14.90 ±0.47
	776.26 ±30	8.70
	773.46 ±4.1	7.06 ±0.32
	767.45 ±0.085	9.74
	762.63 ±0.1	10.30
	753.12 ±16	8.22 ±0.31
	732.44 ±7.7	15.30
	731.06±7.6	6.70 ±0.33
	704.80 ±2.0	7.86 ±0.44
	689.35±0.57	12.23 ±0.41
	684.64 ±270000	8.52 ±0.10
A/2020 H9	680.42 ±1.1	17.70 ±0.34
	663.36 ±2.3	6.46
	653.9 ±0.91	7.13 ±0.33
	650.82 ±140	21.20
	648.32 ±0.27	8.07 ±0.44
	637.57 ±0.22	12.04 ±0.18
	630.26 ±14	6.74
	601.90 ±2.4	6.46
	579.67 ±0.35	13.10
	570.60 ±0.17	10.55
	560.73 ±1.2	7.26 ±0.27
	554.67 ±4.5	8.50
	552.06 ±0.56	13.90
	545.94 ±34	7.76 ±0.05
	543.67 ±0.15	9.95
	519.49 ±2.7	7.20
	511.63 ±16	17.90
	505.11 ±2.3	8.78 ±0.11
	484.56 ±1.2	7.81 ±0.36
	480.63 ±0.028	11.06 ±0.44
	467.17 ±0.99	4.09
	464.64±0.39	7.50 ±0.41
	449.66 ±9.0	8.90
A/2021 E2	430.46 ±8.3	17.90 ±0.44
	411.63 ±0.32	7.53 ±0.24
	400.29 ±1.2	6.14

Greatest barycentric aphelion

The following Minor planets have an incoming barycentric aphelion of at least 1000 AU.

name	diameter	perihelion	Barycentric aphelion	Barycentric aphelion	Change
A/2020 M4	5.2	5.95	5558	4484	-24
	206.8	36.33	4071	4051	-0.49
	3.0	2.691	2279	1180	-93
	5.2	4.106	2478	1913	-30
541132 Leleākūhonua	272.6	65.08	2322	2323	0
A/2022 B3	1.9	3.708	2100	2540	+21
	5.2	4.456	2040	2840	+28
	130.5	14.57	2000	2050	+2.4
	23.7	8.355	1850	1920	+3.6
	700	44.9	1610	1612	0
	94.5	24.14	1540	1560	+1.3
	156.8	50.03	1410	1410	0
	78.6	40.50	1320	1320	0
	29.9	7.927	1260	827	-34
	3.6	2.677	1190	852	-28
	78.6	23.52	1130	1120	-0.9
	49.6	20.73	1120	1070	-4.5