New computed rates for excited S(1D) and SO(1Δ) plus a 1 ppm near-surface atomic sulfur source improve photochemical modeling of sulfur species in Venus and exo-Venus atmospheres.
Title resolution pending
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
citation-role summary
background 1
citation-polarity summary
fields
astro-ph.EP 3verdicts
UNVERDICTED 3roles
background 1polarities
background 1representative citing papers
Early Venus experienced large seasonal and latitudinal insolation redistribution but only modest orbit-averaged flux changes, making atmospheric opacity the dominant control on surface temperature rather than orbital forcing.
The authors introduce the Venus Similarity Index (VSI), Ancient Venus Similarity Index (AVSI) and Future Earth Similarity Index (FESI) as geometric-mean metrics to compare exoplanets to Venus-like environments for habitability studies.
citing papers explorer
-
A Comprehensive Sulfur Chemistry Network Including Excited S(1D) and SO(1{\Delta}) for the XODIAC Photochemical Model: Accounting for Missing Sulfur Processes in Venus and Exo-Venus Analogs
New computed rates for excited S(1D) and SO(1Δ) plus a 1 ppm near-surface atomic sulfur source improve photochemical modeling of sulfur species in Venus and exo-Venus atmospheres.
-
Seasonal Insolation Variability on Early Venus: Implications for Energy Budget
Early Venus experienced large seasonal and latitudinal insolation redistribution but only modest orbit-averaged flux changes, making atmospheric opacity the dominant control on surface temperature rather than orbital forcing.
-
Habitability Study of Terrestrial Planets: Application to Venus-like Worlds
The authors introduce the Venus Similarity Index (VSI), Ancient Venus Similarity Index (AVSI) and Future Earth Similarity Index (FESI) as geometric-mean metrics to compare exoplanets to Venus-like environments for habitability studies.