67P/Churyumov-Gerasimenko上彗星核的物质侵蚀和输运

Oxford Research Encyclopedia of Planetary Science Pub Date : 2021-08-31 DOI:10.1093/acrefore/9780190647926.013.186

W. Ip

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摘要

罗塞塔号航天器于2014-2016年与67P/Churyumov-Gerasimenko彗星会合，并观察了其表面形态和质量损失过程。彗核的大倾角(52°)引入了许多以前不知道的新物理效应。这些包括在近日点通过期间从南半球到北半球的尘埃颗粒的弹道运输，从而形成了两面的二分法，北半球大部分被回收的尘埃物质(后落)的尘埃层覆盖，而南半球主要由固结地形组成。在每个轨道上，大量的表面物质可以在4-10米深的地方通过核表面转移。驱动排气和粉尘喷射效应的物理机制的新理论正在发展。彗星尘埃颗粒与太阳星云中蓬松的聚集体和鹅卵石在流不稳定情景的框架下可能存在联系。因此，罗塞塔任务成功地实现了其最初的科学目标之一，即彗星的起源及其与太阳系形成的关系。

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Mass Erosion and Transport on Cometary Nuclei, as Found on 67P/Churyumov-Gerasimenko

The Rosetta spacecraft rendezvoused with comet 67P/Churyumov-Gerasimenko in 2014–2016 and observed its surface morphology and mass loss process. The large obliquity (52°) of the comet nucleus introduces many novel physical effects not known before. These include the ballistic transport of dust grains from the southern hemisphere to the northern hemisphere during the perihelion passage, thus shaping the dichotomy of two sides, with the northern hemisphere largely covered by dust layers from the recycled dusty materials (back fall) and the southern hemisphere consisting mostly of consolidated terrains. A significant amount of surface material up to 4–10 m in depth could be transferred across the nucleus surface in each orbit. New theories of the physical mechanisms driving the outgassing and dust ejection effects are being developed. There is a possible connection between the cometary dust grains and the fluffy aggregates and pebbles in the solar nebula in the framework of the streaming-instability scenario. The Rosetta mission thus succeeded in fulfilling one of its original scientific goals concerning the origin of comets and their relation to the formation of the solar system.

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Oxford Research Encyclopedia of Planetary Science

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