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Panspermia - A Modern Astrophysical and Biological Approach

Published online by Cambridge University Press:  04 August 2017

J. Mayo Greenberg  and
Peter Weber
J. Mayo Greenberg
Affiliation:
Laboratory Astrophysics, University of Leiden, The Netherlands
Peter Weber
Affiliation:
Laboratory Astrophysics, University of Leiden, The Netherlands

Abstract

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For the first time a laboratory simulation of the effect of the interstellar environment has been used to provide quantitative estimates of bacterial spore survival in the space between the stars. In the diffuse regions between clouds ten percent survival is limited to at most hundreds of years although one in ten thousand may survive for several thousand years. Within common dense clouds the ten percent life expectancy is extended to tens of millions of years because of the severely reduced ultraviolet within these clouds as well as because of the accretion of ultraviolet absorbing mantles on the spores. The random motion of molecular clouds is shown to provide a possible vehicle for transport of spores from one solar system to another. The most hazardous times in such a journey are at the start and finish and, although the requirements for survival during these periods are quantified here, the possibility or probability of their being satisfied remains pure conjecture.

Type
Section III. Planetary, Interplanetary and Interstellar Organic Matter
Information
Symposium - International Astronomical Union , Volume 112: The Search for Extraterrestrial Life: Recent Developments , 1985 , pp. 157 - 164
Copyright
Copyright © Reidel 1985 

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