Abstract
The nature of the early martian climate is one of the major unanswered questions of planetary science. Key challenges remain, but a new wave of orbital and in situ observations and improvements in climate modeling have led to significant advances over the past decade. Multiple lines of geologic evidence now point to an episodically warm surface during the late Noachian and early Hesperian periods 3–4 Ga. The low solar flux received by Mars in its first billion years and inefficiency of plausible greenhouse gases such as CO2 mean that the steady-state early martian climate was likely cold. A denser CO2 atmosphere would have caused adiabatic cooling of the surface and hence migration of water ice to the higher-altitude equatorial and southern regions of the planet. Transient warming caused melting of snow and ice deposits and a temporarily active hydrological cycle, leading to erosion of the valley networks and other fluvial features. Precise details of the warming mechanisms remain unclear, but impacts, volcanism, and orbital forcing all likely played an important role. The lack of evidence for glaciation across much of Mars's ancient terrain suggests the late Noachian surface water inventory was not sufficient to sustain a northern ocean. Though mainly inhospitable on the surface, early Mars may nonetheless have presented significant opportunities for the development of microbial life.
Highlights
With the exception of Earth, Mars is the Solar System’s best-studied planet
The biggest mystery of all is the nature of the early climate: 3-4 Ga Mars should have been freezing cold, but there is abundant evidence that liquid water flowed across its surface
The aim of this review is to provide a general introduction to the latest research on the early Martian climate
Summary
With the exception of Earth, Mars is the Solar System’s best-studied planet. Since the first Mariner flybys in the 1960s, Mars has been successfully observed by a total of 11 orbiters and 7 landers, four of them rovers. Studying Mars has the potential to inform us about the evolution of our own planet, because many of the processes thought to be significant to climate on early Mars (e.g. volcanism, impacts) have been of major importance on Earth. In this era of exoplanet science, Mars represents a test case that can inform us about the climates of small rocky planets in general. It is argued that future progress will require an integrated approach, where three-dimensional climate models are compared with the geologic evidence on both global and regional scales
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