2001 QW322


is an extremely wide binary system of Kuiper belt objects discovered by astronomers at Mauna Kea Observatory on 24 August 2001. Located beyond Neptune, the binary system comprises two identical components, each about in diameter, orbiting their mutual barycenter with an orbital period of 17 years. The components have an average separation of, making the widest known binary minor planet. The immense separation between the components means they are weakly bound together by gravity, which makes the binary system prone to disruption via collisions or gravitational perturbations by close-passing Kuiper belt objects. Studies have suggested that the system most likely formed with an initially small separation but widened over billions of years due to such perturbations by Kuiper belt objects.
The system is a member of the "cold" classical Kuiper belt, as it follows a distant, low-inclination, and low-eccentricity orbit around the Sun. The cold classical Kuiper belt objects are believed to have formed at their current distances from the Sun, far enough from Neptune to remain undisturbed by the planet's gravitational influence throughout the Solar System's lifetime. Both components of the system exhibit less red colors compared to most cold classical Kuiper belt objects, which has led astronomers to hypothesize that formed in a high-temperature environment where reddening substances like methanol were unavailable.

Discovery

was discovered by astronomers of the Canada–France Ecliptic Plane Survey, which included John J. Kavelaars, Jean-Marc Petit, Brett Gladman, and Matthew Holman. The discovery took place on 24 August 2001, during a search for moons of Uranus using the Canada–France–Hawaii Telescope at Mauna Kea Observatory in Hawaii. The discovery images, which were taken by Kavelaars and analyzed by Petit, revealed that is a binary system consisting of two identical components moving together. The components had an angular separation of 4 arcseconds from each other, which translated to an apparent physical separation of —far larger than any other binary Solar System object known at the time.
The discoverers immediately recognized the exceptionally wide binary nature of and thus began a multi-year observing campaign using various large telescopes to determine the binary system's mutual and heliocentric orbits. The discovery of the binary system was announced in circulars issued by the Minor Planet Center and Central Bureau for Astronomical Telegrams on 9 November 2001. The heliocentric orbit of was determined by 2003, while the mutual orbit was determined by late 2007 and published in October 2008.

Heliocentric orbit

The system orbits the Sun at an average distance of, taking 291.5 years to complete one heliocentric orbit. It is located in the classical region of the Kuiper belt between 42 and from the Sun, beyond the orbit of Neptune where many other icy objects like Pluto can be found. shares its orbit with many other objects in the Kuiper belt, which makes it possible for these objects to pass within a few Hill radii of the binary system.
The heliocentric orbit of the system is nearly circular with a low orbital eccentricity of 0.024. It comes as close as to the Sun at perihelion to as far as from the Sun at aphelion, and does not come closer than from Neptune. Its heliocentric orbit is slightly tilted with a low orbital inclination of 4.8° with respect to the ecliptic. These orbital characteristics make a member of the "cold" classical Kuiper belt objects (KBOs), which are so named because they have distinctly less excited orbits. The cold classical KBOs do not come close enough to Neptune to experience significant perturbations by the planet's gravity, so their orbits can remain stable for a long period of time.

Binary system

Nomenclature

is the minor planet provisional designation of the whole binary system, given by the Minor Planet Center as a shorthand for its discovery date. The components of the system could not be reliably distinguished by their brightness or size, so astronomers have instead distinguished them based on their relative positions in the sky at the time of discovery. The MPC and a 2008 study led by Jean-Marc Petit have labeled the southern component "A" and the northern component "B", whereas a 2011 study led by Alex H. Parker has arbitrarily labeled the northern component as "primary" and the southern component as "secondary".
The MPC may give a permanent minor planet number to once its heliocentric orbit is determined with sufficient accuracy. Once numbered, the discoverers can propose a formal name for. According to naming guidelines of the International Astronomical Union's Working Group for Small Bodies Nomenclature, trans-Neptunian objects must be given a mythological name, though in the case of classical KBOs like, names related to creation myths are preferred. John J. Kavelaars, one of the discoverers, has nicknamed "Antipholus and Antipholus" in a 2011 news article on the Canada–France Ecliptic Plane Survey's website.

Physical characteristics

The components of the system are virtually identical in brightness, with the "primary" being 0.03 magnitudes brighter than the "secondary" on average. If both components share the same albedo, then their identical brightnesses imply identical sizes. The albedo of is inferred to be, which suggests a diameter of for the primary component. A calculation by Johnstons Archive finds a marginally smaller diameter of for the secondary component based on its slightly dimmer brightness, although it is still identical to the primary component's diameter within error bounds. Both components are assumed to be made of water ice and rock, with identical masses and densities within the range of 0.8 to. The total mass of the system, which was determined from their mutual orbit, is.
Observations of in different visible light filters have shown that both components share identical colors, implying they have similar surfaces and albedos. The components have a spectral slope of, indicating they are less red compared to most cold classical KBOs. The "blue" color of 's components suggests they have exposed ice surfaces. Blue cold classical KBOs like have been observed to occur more frequently as binary systems than as single objects; astronomers have termed these systems "blue binaries".
The components of the system have been reported to vary in brightness during observations from 2002 to 2007, with the secondary component varying up to 0.45 magnitudes and the primary component varying up to 0.35 magnitudes. The components' brightness variations may be caused by both phase angle effects and the rotation of a non-spherical shape, although the photometric precision of these observations was insufficient to determine a rotation period for either component.

Mutual orbit

The components of the system are separated by an average distance of approximately, which is equivalent to about one-fourth of the distance between Earth and the Moon, or 22% of the binary system's Hill radius. This separation distance, which is the largest seen in any binary minor planet, makes an "ultra-wide" binary system. Ultra-wide binaries are mainly found in the cold classical Kuiper belt, but they only constitute a small fraction of binary cold classical KBOs. The components in ultra-wide binary systems are weakly bound by each other's gravity, which makes them prone to perturbations by close-passing KBOs and the Kozai effect. Studies have shown that collisions or perturbations by close-passing KBOs could disrupt an ultra-wide system like within a billion-year timescale, resulting in the permanent separation of the components into their own heliocentric orbits.
Since the components of have presumably identical masses, the binary system's barycenter lies between them. The components follow extremely slow, elliptical orbits around their system barycenter, taking 17 years to complete one mutual orbit. The components move at an average orbital speed of approximately, comparable to the walking speed of a human. Their mutual orbit has an average eccentricity of 0.41, though it can vary between 0.342 and 0.477 due to the Kozai effect. At periapsis of their mutual orbit, the components can come as close as from each other, although orbital variations from the Kozai effect can make their periapsis separation as small as . The mutual orbit of the system is retrograde with respect to the ecliptic and its heliocentric orbit; its orbital inclination with respect to these reference planes is 150.7° and 152.7°, respectively.

Origin

The wide binary nature and dynamically cold heliocentric orbit of suggest that it was not greatly disturbed throughout the Solar System's history, which implies that it formed where it orbits now. Astronomers widely believe that during the early stages of the Solar System, Neptune underwent a period of outward migration during which it passed through a circumsolar disk of planetesimals around from the Sun. In this scenario, planetesimals that passed close to Neptune were gravitationally scattered onto highly inclined and eccentric heliocentric orbits, whereas planetesimals farther out remained undisturbed from their original orbits and became part of the cold classical Kuiper belt. Any binary systems within the cold classical Kuiper belt would remain intact after Neptune's migration.
Various studies have proposed different mechanisms for the formation of ultra-wide binary KBOs like. Generally, binary systems within the cold classical Kuiper belt are believed to be a common outcome of streaming instability, a process by which solid particles in a turbulent protoplanetary disk become sufficiently concentrated to begin rapid gravitational collapse into large, -sized planetesimals. Studies led by Hunter M. Campbell during the 2020s have shown that binary KBOs with initially small separations could become ultra-wide over billions of years, due to perturbations by close-passing KBOs. Such close encounters mainly occurred during the early Solar System, when the Kuiper belt was more populated. Alternatively, a 2010 study led by David Nesvorný proposed that ultra-wide binary KBOs with equal-mass components could form directly from the gravitational collapse of a particle cloud with excess angular momentum, and then survive to the present day. Although it is theoretically possible that ultra-wide binary KBOs could form primordially and survive to the present day, their high likelihood of disruption within billion-year timescales makes this possibility unlikely. A 2025 study by Campbell and collaborators showed that only 1.7% of primordial binary KBOs with -like separations could survive after 4 billion years, suggesting that the initial population of -like ultra-wide binaries would have to be roughly 40–60 times higher than today.
The less red or "blue" color of suggests that it had a warmer temperature in the past. While blue KBOs have been hypothesized to have formed closer to the Sun, the distant location and in situ history of challenges this hypothesis. A 2022 study by Nesvorný and colleagues proposed that formed in situ at an earlier time than red KBOs, when the Sun's protoplanetary disk was hotter due to greater irradiance by the young Sun. In this hypothesis, reddening substances like methanol and hydrocarbons did not begin accreting into KBOs until the disk's temperature had decreased sufficiently. KBOs that primarily formed from these reddening substances would appear red, whereas pre-existing KBOs like would only accumulate a thin layer of these substances. Nesvorný and colleagues suggested that the reddened surfaces of pre-existing KBOs would be later excavated via processes such as impacts, which would expose interior materials and potentially result in a bluer color.