Pluto’s Volatile and Climate Cycles on Short and Long Timescales

The Pluto System After New Horizons Pub Date : 2019-07-01 DOI:10.2458/azu_uapress_9780816540945-ch014

A. Earle, R. Binzel, L. Young, T. Bertrand, M. Buie, D. Cruikshank, K. Ennico, F. Forget, W. Grundy, J. Moore, C. Olkin, B. Schmitt, J. Spencer, J. Stansberry, S. Stern, L. Trafton, O. Umurhan, H. Weaver

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引用次数: 7

Abstract

The volatiles on Pluto’s surface, N2, CH4, and CO, are present in its atmosphere as well. The movement of volatiles affects Pluto’s surface and atmosphere on multiple timescales. On diurnal timescales, N2 is transported from areas of high to low insolation, and the latent heat of sublimation or condensation maintains a nearly isobaric atmosphere. On seasonal (orbital) timescales, Pluto’s atmosphere changes its 20 pressure by orders of magnitude, but most models predict that it is unlikely to collapse even at aphelion due to the equatorial N2 source in Sputnik Planitia and the high thermal inertia of the subsurface. On seasonal timescales, meters of N2 ice are transported across Pluto’s surface, but it is not yet clear from models how much of this transport is between areas which maintain N2 over an entire year (such as Sputnik Planitia) and to what extent deposition creates new volatile-covered areas (of either N2-rich or CH4-rich ice) or sublimation reveals underlying terrain. Pluto’s orbit and obliquity variations on ~3 Myr timescales (a Milankovitch cycle) induce considerable climate changes along with local accumulation or erosion of m-to-km thick layers of volatile ice. In a non-cyclical process, volatiles filled the large depression that is now Sputnik Planitia.

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冥王星的挥发性和气候周期在短期和长期的时间尺度

冥王星表面的挥发物，N2, CH4和CO，也存在于它的大气中。挥发物的运动在多个时间尺度上影响冥王星的表面和大气。在日尺度上，N2从高日照区向低日照区输送，而升华或凝结潜热维持了一个接近等压的大气。在季节(轨道)时间尺度上，冥王星的大气压强以数量级变化，但大多数模型预测，由于斯普特尼克平原的赤道氮气源和地下的高热惯性，它即使在远日点也不太可能崩溃。在季节的时间尺度上，几米的氮气冰在冥王星表面运输，但从模型中还不清楚有多少这种运输是在全年保持氮气的地区(如Sputnik Planitia)之间进行的，以及沉积在多大程度上创造了新的挥发物覆盖区域(富含氮气或富含甲烷的冰)，或者升华揭示了潜在的地形。冥王星的轨道和倾角在~ 3myr的时间尺度(一个米兰科维奇周期)上的变化，会引起相当大的气候变化，同时伴有局部积聚或侵蚀m- km厚的挥发性冰层。在一个非周期性的过程中，挥发物充满了现在的斯普特尼克平原的大洼地。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Pluto System After New Horizons

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