«Объект из облака Оорта, который направляется в настоящее время в Солнечную систему, может содержать в себе новые ключи к пониманию этого загадочного облака.
Транснептуновый объект 2010 WG9 выделяется среди других подобных ему гостей из таинственного облака комет тем, что он представляет собой планетезималь, сохранившийся со времён формирования Солнечной системы. Он был выбит со своей орбиты и вскоре будет доступен учёным для наблюдений. Однако это лишь первый положительный момент.
Второй момент состоит в том, что этот объект практически не изменился со времени формирования Солнечной системы, поэтому команда астрономов во главе с доктором Давидом Рабиновичем, с нетерпением ожидающая появления 2010 WG9, отзывается о нём как о Священном Граале для планетологов. Удачная траектория объекта - его удалённость от Солнца - позволит ему не испариться под влиянием солнечного тепла, а потому он будет всё время оставаться наблюдаемым в своём первозданном виде.
Изучение объекта 2010 WG9 поможет учёным глубже проникнуть в природу загадочного кометного облака Оорта, а значит - в природу формирования Солнечной системы». («Астрономы встречают в Солнечной системе необычный объект из облака Оорта». 29 мая 2013).
An artist’s conception of two tidally locked objects orbiting the Sun from afar. The system: 2010 WG9 may likely look like this. Credit: ESO |
Mysterious and Well-Preserved Oort Cloud Object Heading Into Our Solar System
According to Rabinowitz, the next step will be to observe 2010 WG9 with larger telescopes — perhaps the Hubble Space Telescope - in order to better measure the color variation. We may even be able to determine if this object is in a binary system after all, and observe the secondary object as well.
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«What if we could journey to the outer edge of the Solar System – beyond the familiar rocky planets and the gas giants, past the orbits of asteroids and comets – one thousand times further still – to the spherical shell of icy particles that enshrouds the Solar System. This shell, more commonly known as the Oort cloud, is believed to be a remnant of the early Solar System.
Imagine what astronomers could learn about the early Solar System by sending a probe to the Oort cloud! Unfortunately 1-2 light years is more than a little beyond our reach. But we’re not entirely out of luck. 2010 WG9 – a trans-Neptunian object - is actually an Oort Cloud object in disguise. It has been kicked out of its orbit, and is heading closer towards us so we can get an unprecedented look.
But it gets even better! 2010 WG9 won’t get close to the Sun, meaning that its icy surface will remain well-preserved. Dr. David Rabinowitz, lead author of a paper about the ongoing observations of this object told Universe Today, “This is one of the Holy Grails of Planetary Science – to observe an unaltered planetesimal left over from the time of Solar System formation.”
Now you might be thinking: wait, don’t comets come from the Oort Cloud? It’s true; most comets were pulled out of the Oort cloud by a gravitational disturbance. But observing comets is extremely difficult, as they are surrounded by bright clouds of dust and gas. They also come much closer to the Sun, meaning that their ices evaporate and their original surface is not preserved.
So while there is a surprisingly high number of Oort cloud objects hanging out within the inner solar system, we needed to find one that is easy to observe and whose surface is well preserved. 2010 WG9 is just the object for the job! It is not covered by dust or gas, and is believed to have spent most of its lifetime at distances greater than 1000 AU. In fact, it will never approach closer than Uranus.
Astronomers at Yale University have observed 2010 WG9 for over two years, taking images in different filters. Just as coffee filters allow ground coffee to pass through but will block larger coffee beans, astronomical filters allow certain wavelengths of light to pass through, while blocking all others.
Recall that the wavelength of visible light relates to color. The color red, for example, has a wavelength of approximately 650 nm. An object that is very red will therefore be brighter in a filter of this wavelength, as opposed to a filter of, say, 475 nm, or blue. The use of filters allow astronomers to study specific colors of light.
Astronomers observed 2010 WG9 with four filters: B, V, R, and I, also known as blue, visible, red, and infrared wavelengths. What did they see? Variation – a change in color over the course of just days.
The likely source is a patchy surface. Imagine looking at the Earth (pretend there’s no atmosphere) with a blue filter. It would brighten when an ocean came into view, and dim when that ocean left the field of view. There would be a variation in color, dependent on the different elements located on the surface of the planet.
The dwarf planet Pluto has patches of methane ice, which also show up as color variations on its surface. Unlike Pluto, 2010 WG9 is small (100 m in diameter) and cannot hold on to its methane ice. It’s possible that part of the surface is newly exposed after an impact. According to Rabinowitz, astronomers are still unsure what the color variations mean.
Rabinowitz was very keen to explain that 2010 WG9 has an unusually slow rotation. Most trans-Neptunian objects rotate every few hours. 2010 WG9 rotates on the order of 11 days! The best reason for this discrepancy is that it exists in a binary system. If 2010 WG9 is tidally locked to another body - meaning that the spin of each body is locked to the rate of rotation - then 2010 WG9 will be slowed down in its rotation.
According to Rabinowitz, the next step will be to observe 2010 WG9 with larger telescopes — perhaps the Hubble Space Telescope - in order to better measure the color variation. We may even be able to determine if this object is in a binary system after all, and observe the secondary object as well.
Any future observations will help us further understand the Oort cloud. “Very little is known about the Oort cloud – how many objects are in it, what are its dimensions, and how it formed,” Rabinowitz explained. “By studying the detailed properties of a newly arrived member of the Oort cloud, we may learn about its constituents.”
2010 WG9 will likely hint at the origin of the Solar System in helping us further understand its own origin: the mysterious Oort cloud». (MAY 28, 2013).
Source: «The Peculiar Photometric Properties of 2010 WG9: A Slowly-Rotating Trans-Neptunian Object from the Oort Cloud». http://arxiv.org/abs/1305.5134
Объект пояса Койпера в восприятии художника |
[Федор Дергачев:
Загадочной особенностью транснептунового
объекта 2010 WG9 является его чрезвычайно медленное вращение – 1 оборот за 11
суток! Вроде бы предположение о участии объекта в двойной системе должно снять
вопрос, если бы не непонятное обилие именно двойных объектов в поясе Койпера (их
доля в этом поясе на порядок выше, чем в Поясе астероидов, расположенном между
Марсом и Юпитером). Такое обилие заставляет предполагать, что упомянутые
двойные объекты выполняют на «Пограничной заставе
Солнечной системы» некие особые функции.
Впрочем, период вращения астероида Матильда
составляет более 17
земных суток, в то время, как ни в какую двойную систему он не входит…]
«Земля и
Вселенная». Часть 21. «Скорость ветра на Венере достигла небывалого максимума». http://artefact-2007.blogspot.ru/2013/06/21.html
На эту тему:
«"Пограничная застава" на окраине Солнечной системы». (11 апреля 2012 года). http://artefact-2007.blogspot.ru/2012/04/11.html
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