系外行星地质学:从当前和未来的观测中我们能学到什么?

Bradford J. Foley
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摘要

概述 在发现第一颗围绕主序星的系外行星近 30 年后,现已证实有数千颗行星。这些发现彻底改变了我们对行星系统的认识,揭示了太阳系中不存在但在太阳系外系统中却很常见的行星类型,以及各种各样的系统结构。我们的太阳系显然不是行星系统的默认系统。目前,研究界正在从系外行星的基本特征(质量、半径和轨道)转向对其大气层甚至表面进行更深入的特征描述。随着观测能力的提高,现在有可能探测岩质系外行星的地质情况;这为我们了解岩质行星的演化带来了类似革命的可能性。然而,即使使用下一代望远镜,描述岩质系外行星上发生的地质或地质过程也是一项重大挑战。本章回顾了我们在近期和长期内通过这些努力可能取得的成果。在近期,詹姆斯-韦伯太空望远镜(JWST)正在揭示哪些岩质行星会失去大气层,哪些会保留大气层。本章将讨论这些发现的影响,包括即使是没有大气层或大气层极小的行星,如何仍然能够为地表地质学和长期地质演化提供约束条件。然后还回顾了更长远的可能性,包括碳酸盐-硅酸盐循环稳定气候的假说是否可以通过下一代望远镜进行检验。要利用当前和未来的观测结果来制约岩质系外行星的地质和演化,就需要有新的建模策略,以涵盖各种可能的演化方案。
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Exoplanet Geology: What Can We Learn from Current and Future Observations?
OVERVIEW
Nearly 30 years after the discovery of the first exoplanet around a main sequence star, thousands of planets have now been confirmed. These discoveries have completely revolutionized our understanding of planetary systems, revealing types of planets that do not exist in our solar system but are common in extrasolar systems, and a wide range of system architectures. Our solar system is clearly not the default for planetary systems. The community is now moving beyond basic characterization of exoplanets (mass, radius, and orbits) towards a deeper characterization of their atmospheres and even surfaces. With improved observational capabilities there is potential to now probe the geology of rocky exoplanets; this raises the possibility of an analogous revolution in our understanding of rocky planet evolution. However, characterizing the geology or geological processes occurring on rocky exoplanets is a major challenge, even with next generation telescopes. This chapter reviews what we may be able to accomplish with these efforts in the near-term and long-term. In the near-term, the James Webb Space Telescope (JWST) is revealing which rocky planets lose versus retain their atmospheres. This chapter discusses the implications of such discoveries, including how even planets with no or minimal atmospheres can still provide constraints on surface geology and long-term geological evolution. Longer-term possibilities are then reviewed, including whether the hypothesis of climate stabilization by the carbonate–silicate cycle can be tested by next generation telescopes. New modeling strategies sweeping through ranges of possibly evolutionary scenarios will be needed to use the current and future observations to constrain rocky exoplanet geology and evolution.
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