posted on 2020-07-13, 10:48authored byJI Moses, T Cavalie, LN Fletcher, MT Roman
Comparatively little is known about atmospheric chemistry on Uranus and
Neptune, because remote spectral observations of these cold, distant ``Ice
Giants'' are challenging, and each planet has only been visited by a single
spacecraft during brief flybys in the 1980s. Thermochemical equilibrium is
expected to control the composition in the deeper, hotter regions of the
atmosphere on both planets, but disequilibrium chemical processes such as
transport-induced quenching and photochemistry alter the composition in the
upper atmospheric regions that can be probed remotely. Surprising disparities
in the abundance of disequilibrium chemical products between the two planets
point to significant differences in atmospheric transport. The atmospheric
composition of Uranus and Neptune can provide critical clues for unravelling
details of planet formation and evolution, but only if it is fully understood
how and why atmospheric constituents vary in a three-dimensional sense and how
material coming in from outside the planet affects observed abundances. Future
mission planning should take into account the key outstanding questions that
remain unanswered about atmospheric chemistry on Uranus and Neptune,
particularly those questions that pertain to planet formation and evolution,
and those that address the complex, coupled atmospheric processes that operate
on Ice Giants within our solar system and beyond.
Funding
J.M. acknowledges support from the NASA Solar System Workings grant 80NSSC19K0536.T.C. acknowledges funding from CNES and from the Programme National de Planétologie (PNP) ofCNRS/INSU. L.F. was supported by a Royal Society Research Fellowship at the University of Leicester.L.F. and M.R. acknowledge support from a European Research Council Consolidator Grant (under theEuropean Union’s Horizon 2020 research and innovation programme, grant agreement No. 723890)
History
Citation
Philosophical Transactions A: Mathematical, Physical and Engineering Sciences, 2020
Author affiliation
School of Physics and Astronomy
Version
AM (Accepted Manuscript)
Published in
Philosophical Transactions A: Mathematical, Physical and Engineering Sciences