54509 YORP

54509 YORP (provisional designation 2000 PH₅) is an Earth co-orbital asteroid^[5] discovered on 3 August 2000 by the Lincoln Laboratory Near-Earth Asteroid Research (LINEAR) Team at Lincoln Laboratory Experimental Test Site in Socorro, New Mexico. Measurements of the rotation rate of this object provided the first observational evidence of the YORP effect, hence the name of the asteroid. The asteroid's rate of rotation is increasing at the rate of (2.0 ± 0.2) × 10⁻⁴ deg/day² which between 2001 and 2005 caused the asteroid to rotate about 250° further than its spin rate in 2001 would have predicted.^[4] Simulations of the asteroid suggest that it may reach a rotation period of ~20 seconds near the end of its expected lifetime, which has a 75% probability of happening within the next 35 million years.^[6] The simulations also ruled out the possibility that close encounters with the Earth have been the cause of the increased spin rate.^[6]

54509 YORP

Radar image and 3D model of YORP
Discovery[1]
Discovered by	LINEAR
Discovery site	Lincoln Lab's ETS
Discovery date	3 August 2000
Designations
MPC designation	(54509) YORP
Named after	YORP effect
Alternative designations	2000 PH5
Minor planet category	Apollo NEO
Orbital characteristics[2][3]
Epoch 21 November 2025 (JD 2461000.5)
Uncertainty parameter 0
Observation arc	1826 days (5.00 yr)
Aphelion	1.23717 AU (185.078 Gm)
Perihelion	0.77455 AU (115.871 Gm)
Semi-major axis	1.00586 AU (150.475 Gm)
Eccentricity	0.22996
Orbital period (sidereal)	1.01 yr (368.47 d)
Average orbital speed	29.31 km/s
Mean anomaly	130.15693°
Mean motion	0° 58m 37.245s / day
Inclination	1.59946°
Longitude of ascending node	278.18528°
Argument of perihelion	278.99884°
Earth MOID	0.000495246 AU (74,087.7 km)
Jupiter MOID	3.72092 AU (556.642 Gm)
TJupiter	6.029
Physical characteristics
Dimensions	150×128×93 m[4]
Sidereal rotation period	0.2029 h 12.174 min[3]
Axial tilt	173°[4]
Pole ecliptic longitude	180°[4]
Pole ecliptic latitude	−85°[4]
Absolute magnitude (H)	22.7 (JPL)[3]

Discovery and naming

YORP was discovered on 3 August 2000 by the Lincoln Near-Earth Asteroid Research (LINEAR) program at the Lincoln Laboratory's Experimental Test Site in Socorro, New Mexico. It was given the provisional designation 2000 PH₅,^[1] and its discovery was announced in a Minor Planets Electronic Circular on 7 August.^[7] At the time of discovery, YORP was located 0.04 astronomical units (AU) away from Earth.^[4]: 275 Once its orbit was sufficiently determined, it was numbered 54509 by the Minor Planet Center on 16 February 2003.^[8]: 905 It is named after researchers Ivan Yarkovsky, John O'Keefe, Vladimir Radzievskij, and Stephen Paddock, contributors to the understanding of the mechanisms behind the YORP effect and after whom the effect is named. The naming was chosen as the asteroid provided the first direct observational evidence for the effect; the name announced in Minor Planets Circular 59387 on 2 April 2007.^[9]

Orbit

YORP orbits the Sun with an average distance, or semi-major axis, of 1.006 AU, completing one orbit in 368.5 days. Due to its orbital eccentricity of 0.23, its distance from the Sun varies from 0.775 AU at perihelion to 1.237 AU at aphelion, crossing Earth's orbit. YORP's orbit is inclined by 1.6° with respect to the ecliptic plane.^[3]

YORP is classified as an Apollo asteroid,^[3] a subgroup of Earth-crossing near-Earth asteroids (NEAs) with semi-major axes greater than 1 AU.^[10] YORP is also classified as an Earth co-orbital; it is in a near-1:1 mean-motion resonance with Earth in a horseshoe configuration.^[6]: 273 In a horseshoe configuration, the asteroid's orbit librates between the L₄ and L₅ Lagrange points, traversing the L₃ point.^[11]: 1 Over a cycle lasting about 100 years, YORP librates until it experiences a close encounter with Earth, after which its libration reverses direction until it encounters Earth again. Because of its eccentricity, its encounters with Earth are close, coming within a few lunar distances. For the past cycle, YORP trailed Earth, approaching it at a rate of roughly 3° per year. It encountered Earth in July 2003, where its semi-major axis was raised from 0.994 AU to 1.006 AU. It is currently lagging behind by 3° per year; it will reach the other end of its horseshoe path about 100 years from now.^[12]

Possible asteroid group

YORP is the largest member of a candidate asteroid group. More than a dozen NEAs have similar orbital properties to YORP, including 2017 DR109, which also follows a horseshoe trajectory.^[13]: 3451 A 2018 study by Carlos and Raul de la Fuente Marcos concluded that the asteroids are likely dynamically if not genetically related,^[13]: 3445 but the scarcity of spectroscopic data and the poorly determined orbits of several candidate members prevented a definitive confirmation. Several of these asteroids may originate from YORP effect-driven mass shedding of 54509 YORP, tidal disruption events from close Earth and Venus encounters, and collisional disruption.^{[13]: 3450–3451}

Potential members^[a]

Asteroid	a (AU)	e	i (°)	Earth MOID (AU)	H (mag)
54509 YORP	1.0062	0.2302	1.5993	0.0028	22.7
2009 HE60	0.9958	0.2649	1.5848	0.0154	25.6
2012 VZ19	0.9825	0.2541	1.2474	0.0111	25.6
(488490) 2000 AF20	1.0341	0.2768	2.4084	0.0182	21.7
2017 BU	1.0196	0.2512	1.5052	0.0229	25.1
2015 YA	0.9962	0.2794	1.6192	0.0035	27.4
2008 UB95	0.9897	0.2686	3.2372	0.0003	24.7
2016 JA	0.0132	0.2685	0.0579	0.0002	27.6
2017 DR109	1.0006	0.2414	3.0600	0.0062	27.6
2012 BD14	1.0176	0.2405	1.5356	0.0080	26.5
2000 QX69	1.0101	0.2715	4.5740	0.0002	24.2
2014 NZ64	1.0368	0.2734	4.4945	0.0092	22.8
2010 FN	0.9896	0.2110	0.1237	0.0008	26.6
2002 VX91	0.9840	0.2013	2.3417	0.0018	24.3
(471984) 2013 UE3	1.0262	0.2257	3.3574	0.0235	22.7
2007 WU3	1.0113	0.2040	2.3933	0.0402	23.8
2009 BK2	1.0125	0.2126	3.5534	0.0260	25.3
2011 OJ45	1.0169	0.2037	0.7492	0.0076	26.0
2017 FZ2	1.0071	0.2641	1.8117	0.0014	26.7

Physical characteristics

YORP's size and shape has been directly measured through radar observations conducted by the Goldstone observatory on 27–28 July 2001 and the Arecibo Telescope on 27–28 July 2004 and 24–26 July 2005.^[4]: 275 Various shape models were compared against Doppler images of YORP, with the best-fit model having a diameter of 112.8 metres (370 ft) and dimensions of 149 by 134 by 96 metres (489 ft × 440 ft × 315 ft).^[4]: 276 YORP has a very irregular shape, with Doppler imagery revealing convex, linear, and concave topography features. Its northern hemisphere is flattened, though it has a prominent concavity.^{[4]: 275–276}

Rotation

YORP has a retrograde spin, with an axial tilt of 173° relative to its orbit normal. Its spin axis points towards the ecliptic south, lying within 10° of the J2000 ecliptic coordinates (180°, –85°). Observations of YORP's lightcurve, or fluctuations in brightness as it rotates, suggests a sidereal rotation period of 12.17 minutes, which has been corroborated by radar observations.^{[4]: 275–276} YORP's fast rotation and small size classifies it as a monolithic fast rotator.^[6]: 273

In 2007, two studies—one led by Stephen C. Lowry and the other led by Patrick A. Taylor—investigated changes in YORP's rotation period over time, reporting the direct detection of the YORP effect.^{[6]: 272 [4]: 274} This was the first direct observational evidence of the YORP effect;^[9] previously, evidence of the effect was indirect, manifesting in the anomalous distributions of some asteroids' rotation periods and axial tilts.^[6]: 272 YORP's lightcurve data from 2001 to 2005 suggests its rotation period is fractionally decreasing by 1.7×10⁻⁶ per year.^[6]: 274 Taylor and collaborators used YORP's shape model to theoretically derive the expected change in its rotation period under the YORP effect. Despite incomplete shape and thermal data, theoretical predictions agreed within an order of magnitude with the observed change in period. Tidal torques from repeated close encounters with Earth were ruled out as an explanation, leaving the YORP effect as the most likely explanation for the change in the asteroid's spin.^[4]: 276

Gallery

Animation of 54509 YORP orbit from 1600 to 2500

Relative to Sun and Earth

Around Earth

Around Sun

   Sun ·    Earth ·   54509 YORP

See also

• 1620 Geographos
• 1862 Apollo
• 25143 Itokawa
• 2002 AA29
• 2003 YN107
• (419624) 2010 SO16

Notes

1. Orbital elements as of epoch 4 September 2017 (JD 2458000.5), with the exception of 2012 VZ₁₉, which is of epoch 5 November 2012 (JD 2456236.5).^[13]: 3451