A Photochemical Model for NH3 in an Early Martian Atmosphere
Abstract
A warm and wet climate scenario for early Mars has been explained by invoking a 5-bar CO2 atmosphere; however, Kasting has shown that CO2 will condense in the Martian atmosphere at these pressures. The formation of CO2 clouds will reduce the convection lapse rate and reduce the magnitude of the greenhouse effect. It is possible that additional greenhouse gases such as methane and ammonia were present in the early Mars atmosphere. We are using a one dimensional photochemical model to estimate the magnitude of the ammonia source required to maintain a given ammonia concentration in a dense CO2 atmosphere. Because CO2 is 2.5 times more efficient at Rayleigh scattering than Earth's N2 atmosphere, we anticipate increased scattering opacities and decreased photolytic destruction rates of ammonia on early Mars. The reduced gravity on Mars means that a 1 bar atmosphere will be approximately 3 times as thick as on Earth. It is possible that ammonia could have been shielded from photolysis by hydrocarbon aerosols which form as a product of methane photolysis.
- Publication:
-
Evolution of the Martian Atmosphere
- Pub Date:
- 1992
- Bibcode:
- 1992LPICo.787Q...3B
- Keywords:
-
- Ammonia;
- Atmospheric Composition;
- Atmospheric Models;
- Carbon Dioxide;
- Greenhouse Effect;
- Mars Atmosphere;
- Photochemical Reactions;
- Photolysis;
- Rayleigh Scattering;
- Aerosols;
- Hydrocarbons;
- Methane;
- Opacity;
- Reduced Gravity;
- Lunar and Planetary Exploration