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2020 CD3

2020 CD3 is a small near-Earth , approximately 1 to 2 meters in diameter, that was temporarily captured by Earth's gravity and orbited the planet as a "minimoon" from late 2018 until early 2020. This car-sized object, formally designated as a near-Earth , followed a geocentric distinct from typical solar orbits, making it the second confirmed instance of such a temporary Earth after 2006 RH120; a third, 2024 PT5, was later discovered in 2024. Unlike the , 2020 CD3's orbit was highly elliptical and unstable, with periods ranging from 47 to 90 days and apogees extending up to four times the -Moon distance. The asteroid was discovered on February 15, 2020, by astronomers Kacper Wierzchos and Theodore Pruyne using the Mount Lemmon Observatory as part of the NASA-funded Catalina Sky Survey. observations, including images from October 30, 2019, later confirmed that 2020 CD3 had entered Earth's on September 23, 2018, plus or minus one day, indicating it had been orbiting undetected for over a year prior to discovery. Its small size and faint brightness—estimated from —made it challenging to detect earlier, highlighting the rarity of such captures among the thousands of near-Earth objects tracked by surveys. During its geocentric phase, 2020 CD3 maintained a stable but temporary , with its closest approach to on February 13, 2020, at about 41,000 kilometers (25,000 miles) altitude. The object's was influenced solely by Earth's gravity after capture from a heliocentric path, without evidence of artificial origin such as , though this possibility was initially considered. It escaped Earth's gravitational influence on March 7, 2020, transitioning back to a solar that will bring it near again in 2044, though without recapture at that time. The discovery of 2020 CD3 underscores the dynamic nature of populations and the potential frequency of short-lived minimoons, which may occur more often than previously thought due to gravitational interactions in the Earth-Moon system. Subsequent discoveries, such as 2024 PT5, further support this. Observations, including color imaging from the North telescope, revealed 2020 CD3 as a likely natural fragment, possibly from the main belt or , contributing to studies on temporary captures and planetary defense. Its brief tenure as a minimoon provides valuable for modeling orbital evolution and improving detection of similar transient objects with advancing telescopes.

Discovery and Initial Observations

Discovery

2020 CD3 was detected on February 15, 2020, by astronomers Theodore Pruyne and Kacper Wierzchoś, both research specialists at the , using the 1.5-meter reflector telescope at Observatory near , as part of the NASA-funded Catalina Sky Survey. The object appeared as a faint, 20th-magnitude streak across four 30-second exposure images, exhibiting unusual geocentric motion that distinguished it from typical solar-orbiting asteroids. The survey's automated detection software played a crucial role in flagging this atypical movement, prompting immediate analysis. Follow-up observations from February 16 to 24, 2020, confirmed the object's Earth-orbiting trajectory through additional imaging at multiple facilities, including Steward Observatory. These efforts provided sufficient data to compute a preliminary , verifying 2020 CD3 as a temporarily captured . The officially announced the discovery on February 25, 2020, via Minor Planet Electronic Circular 2020-D104, designating it as provisional object 2020 CD3 and highlighting its status as a potential temporary of . This marked only the second confirmed instance of such a minimoon, underscoring the rarity of the event.

Precovery and Follow-up

Precovery observations of 2020 CD3 were identified in archival data from the Catalina Sky Survey, with detections dating back to May 9, 2018, at Mount Bigelow, where four trailed images allowed measurement of trail ends to extend the observational baseline. Additional images were found from January 17, 2019, using the Camera on the Blanco 4-meter and from January 24, 2019, at , contributing to a refined pre-capture trajectory. These retrospective identifications, combined with the initial discovery on February 15, 2020, by the Catalina Sky Survey at , significantly lengthened the observational arc. Follow-up observations continued through May 2020, involving multiple s to track the object's until its ejection. Key efforts included photometric imaging with the 8.1-meter Gemini North on February 24, 2020, which provided color indices consistent with a natural asteroid, and astrometric photometry using the 2.2-meter University of on , employing nonsidereal tracking to maintain the stellar point-spread function amid the object's rapid motion. International collaborations, including teams from the (USA), ESA's Coordination Centre (), Queen's University Belfast (), and the University of (USA), coordinated these efforts to gather 126 optical observations in total. No direct contributions from the were reported in primary accounts. Observing 2020 CD3 presented challenges due to its faint of approximately 19–20 and close proximity to , which caused image trailing and required short-exposure nonsidereal tracking to prevent and enable precise measurements. These difficulties necessitated of trailed detections and limited the number of usable frames, particularly in early follow-up phases. The complete observational arc, spanning from May 9, , to May 20, 2020, enabled accurate initial and confirmation of the object's temporary capture. from these observations briefly supported its natural origin as a rocky , with details further explored in physical characterization studies.

Nomenclature and Classification

Designation

Upon initial detection on February 15, 2020, by the Sky Survey, the object received the temporary internal designation C26FED2, adhering to survey-specific conventions for unconfirmed discoveries where "C" denotes the observatory and the subsequent alphanumeric sequence encodes the observation date and order. Following confirmatory follow-up observations, the officially assigned the provisional designation CD3 on February 25, 2020. This follows the standard format for minor planet provisional designations: the four-digit year "2020" indicates the discovery year, the letter "C" specifies the first half of February (with A for the first half of January, B for the second half, skipping I to avoid confusion with 1), and "D3" marks it as the third such object numbered in that half-month interval. As a small, temporarily captured lacking a well-established long-term sufficient for numbering, 2020 CD3 has not been granted a permanent name under guidelines, which reserve naming rights for discoverers only after orbital reliability and assignment of a permanent number. As of 2025, it retains its provisional designation without a permanent number or name. This provisional status parallels that of other transient near-Earth objects, such as the earlier minimoon 2006 RH120, which similarly retains its provisional designation due to its brief association with Earth's vicinity.

Orbital Classification

2020 CD3 is classified as an asteroid, a rare subtype of small, Earth-crossing near-Earth objects characterized by orbits with semi-major axes close to 1 AU and low , making them dynamically similar to Earth's path around the Sun. This classification stems from its pre-capture , which align with the loosely defined Arjuna population of dynamically cold asteroids that exhibit Earth-like trajectories. Arjuna asteroids represent a secondary belt of over 100 known members, distinct from the main , and are prone to close approaches with Earth due to their low relative velocities. As a member of the broader Apollo group, 2020 CD3 qualifies through its orbit crossing Earth's path, a defining feature of these potentially hazardous near-Earth asteroids with semi-major axes greater than 1 AU. However, it is distinguished within this group by its history of temporary capture into a , facilitated by prior co-orbital configurations such as horseshoe or in its heliocentric phase (see Orbital Evolution). This hybrid nature highlights how objects can transition between standard Apollo-like crossings and more intimate interactions with .

Orbital Evolution

Long-term Orbit

The long-term of 2020 CD3 features a semi-major axis of 1.029 , an of 0.01245, and an inclination of 0.634° with respect to the . These parameters place it in a near-circular path closely aligned with 's , classifying it as an Earth co-orbital object. The resulting is approximately 1.04 years, during which 2020 CD3 reaches a perihelion of 1.016 and an aphelion of 1.042 . This configuration yields a stable, quasi-periodic motion around the Sun, with minimal variations in radial that keep the object within the inner solar system. Osculating , computed from the full observational arc spanning data from 2016 through post-discovery follow-up in 2020, demonstrate long-term stability over several centuries in the absence of significant planetary perturbations. Without such influences, the orbit maintains its low-, low-inclination characteristics, avoiding rapid chaotic evolution typical of more eccentric near-Earth objects. In comparison to (semi-major axis 1.000 , eccentricity 0.0167, inclination 0°), 2020 CD3 exhibits a notably low of approximately 6 m/s, which promotes occasional co-orbital resonances and repeated close approaches to . This similarity in orbital geometry underscores its membership in the asteroid subclass, facilitating transient interactions without requiring high-energy encounters.

Temporary Capture Mechanics

The temporary capture of 2020 CD3 by occurred when the entered Earth's , approximately 0.01 AU in radius, on September 23, 2018 ± 1 day, shifting its trajectory from a configuration relative to to a bound . This transition was facilitated by the low during the encounter, allowing Earth's to temporarily dominate over solar perturbations. The object maintained a stable for approximately 17 months, from late September 2018 until its discovery in February 2020, with ejection from Earth's occurring on March 7, 2020. During this phase, the orbit was highly eccentric, characterized by a geocentric semi-major axis of approximately 0.011 and an of about 47 days. The closest approach to Earth's surface took place on April 4, 2019, at a of 13,104 . The underlying mechanics involved Earth's gravity reducing the asteroid's relative to , enabling a negative geocentric energy state that bound it to Earth-Moon . This process was rigorously analyzed through N-body simulations in the Sun-Earth-asteroid framework, incorporating variations to account for observational uncertainties and confirming the capture's probabilistic nature. Such simulations demonstrated that low-velocity encounters with Earth-like orbits are prerequisites for temporary captures among near-Earth objects. The orbit's instability arose primarily from perturbations by the , which induced chaotic variations, and the asteroid's minuscule Hill radius—on the order of given its estimated and —rendering it highly susceptible to ejection. Lunar close approaches further destabilized the , ensuring the capture's transient despite the initially favorable conditions.

Ejection and Future Trajectory

On March 7, 2020, 2020 CD3's exceeded Earth's , marking the end of its temporary capture and allowing it to transition from a back to a heliocentric one. This ejection occurred as the object's trajectory carried it beyond Earth's at approximately 0.01 from the planet. Following its ejection, 2020 CD3's long-term trajectory has been modeled using data from NASA's (JPL) Small-Body Database, which incorporates planetary perturbations from major bodies in the Solar System to predict future paths. The object's next close approach to is projected for March 20, 2044, at a distance of 0.0245 (about 3.6 million km), a separation sufficient for observation from Earth with moderate telescopes. A subsequent approach will occur in August 2061, at 0.034 (roughly 5 million km). Risk assessments from JPL's system indicate a low probability of collision, with an 0.85% chance of impact on , 2082; however, due to 2020 CD3's small size (estimated at 1–2 meters), any such event would have negligible consequences, earning a rating of 0.

Physical Properties

Dimensions and Mass

2020 CD3 has an estimated of 0.9–1.2 meters, derived from its of H = 31.9 ± 0.1 and an assumed ranging from 0.23 (typical for near-Earth objects) to 0.35 (typical for V-type asteroids). Observations indicate an irregular shape, inferred from lightcurve variations with an amplitude of approximately 1 magnitude, suggesting an elongated form with an axial ratio of ~2.5:1. The is calculated to be on the order of 10³–10⁴ kg, based on the volume derived from the range and a estimate of 2.1 ± 0.7 g/cm³ assuming minimal macroporosity; alternative assessments assuming a larger effective of ~2 meters yield a of approximately 8,800 kg. For scale, this places 2020 CD3 in size comparable to a large or a small . Uncertainties in these parameters stem from the absence of radar imaging or direct measurements, with all estimates relying on optical photometry obtained during its 2020 close approach to .

Composition and Rotation

Spectroscopic observations of 2020 CD3 conducted using the Keck I telescope with the Low Resolution Imaging Spectrometer (LRIS) on March 23, 2020, revealed a visible-wavelength spectrum (434–912 nm) that closely resembles V-type (vestoid) asteroids according to the Bus-DeMeo taxonomy. This classification indicates a basaltic composition dominated by pyroxene silicates, evidenced by a reddish spectral slope of approximately 18% per 100 nm between 434 and 761 nm and an absorption feature near 0.9 μm attributable to pyroxene minerals. V-type asteroids, including 2020 CD3, share compositional similarities with the asteroid 4 Vesta, featuring mafic silicates that produce characteristic absorption bands at around 0.9 and 2.0 μm in near-infrared spectra, though the latter was not directly observed for this object due to the wavelength coverage of the available data. Follow-up spectroscopy with the Gemini North telescope in March 2020 confirmed 2020 CD3 as a natural Solar System body rather than artificial , based on its rocky inconsistent with known human-made materials. The estimated of 2.1 ± 0.4 g/cm³, derived from photometric assuming a V-type , aligns with that of stony meteorites and supports a silicate-rich interior without significant voids. Photometric lightcurve analysis from multiple observatories revealed complex al behavior. Time-resolved photometry obtained with Keck I detected periodic variations with a of approximately 573 seconds (0.159 hours) and an of about 1 , suggesting an elongated shape with an axial ratio of roughly 2.5. Independent lightcurve observations using the Lowell Discovery Telescope yielded a primary of 191 seconds (0.053 hours) with a peak-to-peak of 0.5 magnitudes, though non-principal (tumbling) could not be ruled out due to data limitations. The discrepancy in reported periods, ranging from roughly 190 to 573 seconds, indicates possible irregular influenced by the object's small and recent dynamical history near .

Significance

As Earth's Minimoon

2020 CD3 was the second confirmed natural minimoon of at the time of its characterization, following the asteroid 2006 RH120, which was temporarily captured between 2006 and 2007. A third minimoon, 2024 PT5, was confirmed in 2024. Precovery observations indicate that 2020 CD3 entered 's geocentric orbit on September 15, 2017, and remained undetected until its discovery on February 15, 2020, by the Catalina Sky Survey. A minimoon is defined as a natural celestial body, typically a small near- , that is temporarily captured into a , completing at least one full revolution around before escaping back to a heliocentric path. This distinguishes minimoons from artificial satellites, which are human-made, and from permanently captured bodies like the , which remain in stable orbits over geological timescales. Such events are rare, with models of near-Earth populations predicting that captures objects smaller than 10 meters into minimoon orbits approximately once every 10 to 20 years for longer-duration episodes. In contrast to natural minimoons, artificial objects such as discarded boosters can occasionally enter similar temporary geocentric orbits, mimicking minimoon trajectories but originating from human activities; initial analyses of 2020 CD3 briefly considered this possibility before confirming its natural asteroidal nature through orbital and data. Detecting future minimoons poses significant observational challenges due to their small size, resulting in faint apparent magnitudes often exceeding 20th magnitude, and their brief residency times, which typically span weeks to a few years, requiring wide-field surveys to scan vast sky areas for fast-moving, low-albedo targets.

Scientific Implications

The detailed characterization of 2020 CD3 in a 2020 paper published in The Astronomical Journal confirmed its natural origin through multi-faceted analysis, including photometric and astrometric data that aligned with expectations for a primitive asteroid rather than artificial debris. Complementary spectroscopic observations further supported this by revealing a V-type composition indicative of a silicate-rich, space-weathered surface, inconsistent with the metallic or organic signatures typical of space junk. These findings have enhanced models of (NEO) dynamics, enabling the first empirical validation of theoretical predictions for temporary capture rates and stability, which in turn refines simulations for planetary defense by better accounting for undetected transient satellites. The object's trajectory provided direct evidence of chaotic interactions within the Earth-Moon system, improving forecasts of ejection mechanisms and long-term NEO evolution. Subsequent discoveries, such as the 2024 minimoon 2024 PT5, and 2025 research suggesting lunar as a potential source for additional minimoons, further support these models and indicate higher capture frequencies than previously estimated. As an Arjuna asteroid—a class of Earth-coorbital bodies with low-eccentricity orbits—2020 CD3 contributes to understanding the dynamical pathways that populate this "secondary belt," potentially linking main-belt origins to frequent encounters and informing projections for future minimoon discoveries. Surveys like the Catalina Sky Survey, which identified 2020 CD3, and the (ATLAS) are poised to expand this knowledge by increasing the sample size of captured objects, facilitating statistical analyses of minimoon populations. The event has held substantial educational and public engagement value, exemplifying Earth's role in transiently capturing small Solar System bodies and underscoring the diversity of as remnants of planetary formation processes. Despite these advances, gaps persist in detecting minimoons early in their capture phase due to their faintness and rapid motion, necessitating more sensitive telescopes and automated detection algorithms to enable comprehensive studies and mitigate overlooked risks in NEO monitoring.

References

  1. [1]
    Tiny Object Discovered in Distant Orbit Around the Earth - CNEOS
    Feb 27, 2020 · Based on its brightness, 2020 CD3 is very small, no more than 1 to 2 meters (3 to 6 feet) in size. The discovery was made on February 15, 2020 ...
  2. [2]
    A New Mini-Moon Was Found Orbiting Earth. There Will Be More.
    Nov 11, 2021 · The object, a car-size asteroid called 2020 CD3, won't be here for long, and new telescopes will help us spot more of these objects.
  3. [3]
    Precovery Observations Confirm the Capture Time of Asteroid 2020 ...
    May 18, 2021 · Abstract. Asteroid 2020 CD3 was discovered on 2020 February 15 by the Catalina Sky Survey while it was temporarily captured in a geocentric ...
  4. [4]
    Earth's minimoon is gone but not forgotten: Report - Space
    Mar 21, 2020 · Our (former) minimoon, known formally as 2020 CD3, was officially identified in February after it had been orbiting our planet for at least a year.
  5. [5]
    Minimoon 2020 CD3 in Color - NOIRLab
    International Gemini Observatory image of 2020 CD3 (center, point source) obtained with the 8-meter Gemini North telescope on Hawaii's Maunakea.<|control11|><|separator|>
  6. [6]
    Catalina Sky Survey Discovers New Mini-Moon Orbiting Earth
    Feb 28, 2020 · 2020 CD3 first appeared to Pruyne and Wierzchos as a sequence of four short streaks tracking across images acquired at the CSS's 60-inch ...Missing: Theodore Wierzchoś
  7. [7]
    Earth Has A Mini-Moon — But Not for Long! - Sky & Telescope
    Earth took on a brand new moon. Known as 2020 CD 3, it was discovered on February 15th by Catalina Sky Survey (CSS) astronomers Kacper Wierzchos and Teddy ...
  8. [8]
    New 'mini-moon' orbiting Earth — for now, astronomers say
    Feb 26, 2020 · On the night of Feb. 15, my Catalina Sky Survey teammate Teddy Pruyne and I found a 20th magnitude object." Wierzchos said that the object ...Missing: Theodore Wierzchoś
  9. [9]
    Earth Has New, Temporary Moon: 2020 CD3 | Astronomy - Sci.News
    Feb 27, 2020 · After being captured, they typically orbit the Earth for no more than a few years before breaking free to reclaim an independent orbit about ...
  10. [10]
    Establishing Earth's Minimoon Population through Characterization ...
    Nov 23, 2020 · 2020 CD3 was discovered on 2020 February 15.51 UT by the Catalina Sky Survey (CSS; Christensen et al. 2018) 1.5 m telescope on Mt. Lemmon ...
  11. [11]
    Earth just gained a new mini-moon—but it won't be around for long
    Feb 27, 2020 · The two researchers responsible for the discovery held off on announcing their findings while they confirmed exactly what 2020 CD3 was and what ...<|control11|><|separator|>
  12. [12]
    https://www.technologyreview.com/2020/02/27/905652/earth-just-gained-a-new-mini-moonbut-it-wont-be-around-for-long/
  13. [13]
    [PDF] RULES AND GUIDELINES FOR NAMING NON-COMETARY SMALL ...
    Dec 20, 2021 · Small bodies can be named by their discoverers once their orbits are sufficiently well-known and small body numbers have been assigned by the ...
  14. [14]
    [1410.4104] Geometric characterization of the Arjuna orbital domain
    Oct 15, 2014 · Abstract:Arjuna-type orbits are characterized by being Earth-like ... Apollo or Aten asteroid populations. We estimate that their ...
  15. [15]
    https://arxiv.org/abs/1410.4104
  16. [16]
    On the orbital evolution of meteoroid 2020 CD3, a temporarily ... - arXiv
    Mar 20, 2020 · We confirm that 2020 CD3 is currently following a geocentric trajectory although it will escape into a heliocentric path by early May 2020. Our ...
  17. [17]
    What is the 'Mini Moon' That is Now Orbiting Earth?
    Oct 4, 2024 · “About every 10 to 20 years an object probably from the Arjuna asteroid belt falls into the gravitational influence of the Earth-moon system and ...
  18. [18]
    https://iopscience.iop.org/article/10.3847/2041-8213/abae69
  19. [19]
    Characterization of Temporarily Captured Minimoon 2020 CD 3 by ...
    Sep 15, 2020 · We present time-resolved visible spectrophotometry of 2020 CD 3 , the second known minimoon. The spectrophotometry was taken with the Keck I/Low Resolution ...
  20. [20]
    https://ssd.jpl.nasa.gov/tools/sbdb_lookup.html?des=2020+CD3
  21. [21]
    https://cneos.jpl.nasa.gov/sentry/
  22. [22]
    Sentry: Earth Impact Monitoring - Nasa CNEOS
    Sentry is a highly automated collision monitoring system that continually scans the most current asteroid catalog for possibilities of future impact with Earth.Torino Scale · Introduction · Palermo Scale · Object Details
  23. [23]
    Characterization of Temporarily-Captured Minimoon 2020 CD$_3 ...
    Aug 12, 2020 · 2020 CD_3 is a minimoon, the second temporarily captured by Earth-Moon, with a diameter of ~0.9m, and a ~2 year capture duration.Missing: CD3 | Show results with:CD3
  24. [24]
    Mysterious Minimoon Identified - NOIRLab
    Nov 22, 2020 · Now, observations from a collection of telescopes including Gemini North on Hawai'i's Maunakea have shown 2020 CD3 to be natural in origin.
  25. [25]
    Earth will get another moon this month — but not for long! | Space
    Sep 17, 2024 · "Objects in the Arjuna asteroid belt are part of the near ... These temporary captures can last just days, weeks or even a few months.Missing: probability | Show results with:probability