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Changing spatial distribution of water flow charts major change in Mars's greenhouse effect.

Edwin S KiteMichael A MischnaBowen FanAlexander M MorganSharon A WilsonMark I Richardson
Published in: Science advances (2022)
Early Mars had rivers, but the cause of Mars's wet-to-dry transition remains unknown. Past climate on Mars can be probed using the spatial distribution of climate-sensitive landforms. We analyzed global databases of water-worked landforms and identified changes in the spatial distribution of rivers over time. These changes are simply explained by comparison to a simplified meltwater model driven by an ensemble of global climate model simulations, as the result of ≳10 K global cooling, from global average surface temperature [Formula: see text] ≥ 268 K to [Formula: see text] ~ 258 K, due to a weaker greenhouse effect. In other words, river-forming climates on early Mars were warm and wet first, and cold and wet later. Unexpectedly, analysis of the greenhouse effect within our ensemble of global climate model simulations suggests that this shift was primarily driven by waning non-CO 2 radiative forcing, and not changes in CO 2 radiative forcing.
Keyphrases
  • climate change
  • molecular dynamics
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  • molecular dynamics simulations
  • municipal solid waste
  • human milk
  • convolutional neural network
  • big data
  • deep learning
  • heavy metals