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Sulfuric acid aerosols in the atmospheres of the terrestrial planets

Author(s): McGouldrick K, Toon OB, Grinspoon DH

Published: May, 2010

Publisher: Planetary and Space Science

DOI: 10.1016/j.pss.2010.05.020

Tags: Stratospheric Aerosols, Climate Modelling

URL: http://www.sciencedirect.com/science/article/pii/S0032063310001583

Abstract: Clouds and hazes composed of sulfuric acid are observed to exist or postulated to have once existed on each of the terrestrial planets with atmospheres in our solar system. Venus today maintains a global cover of clouds composed of a sulfuric acid/water solution that extends in altitude from roughly 50 km to roughly 80 km. Terrestrial polar stratospheric clouds (PSCs) form on stratospheric sulfuric acid aerosols, and both PSCs and stratospheric aerosols play a critical role in the formation of the ozone hole. Stratospheric aerosols can modify the climate when they are enhanced following volcanic eruptions, and are a current focus for geoengineering studies. Rain is made more acidic by sulfuric acid originating from sulfur dioxide generated by industry on Earth. Analysis of the sulfur content of Martian rocks has led to the hypothesis that an early Martian atmosphere, rich in SO2 and H2O, could support a sulfur-infused hydrological cycle. Here we consider the plausibility of frozen sulfuric acid in the upper clouds of Venus, which could lead to lightning generation, with implications for observations by the European Space Agency's Venus Express and the Japan Aerospace Exploration Agency's Venus Climate Orbiter (also known as Akatsuki). We also present simulations of a sulfur-rich early Martian atmosphere. We find that about 40 cm/yr of precipitation having a pH of about 2.0 could fall in an early Martian atmosphere, assuming a surface temperature of 273 K, and SO2 generation rates consistent with the formation of Tharsis. This modeled acid rain is a powerful sink for SO2, quickly removing it and preventing it from having a significant greenhouse effect.


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