Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada

Meteorite impacts are ubiquitous throughout our solar system and are a fundamental geological process on rocky and icy planetary bodies. Though initially detrimental to biology, an impact event can favourably change the availability and habitability of a substrate for endolithic organisms, which are...

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Main Author: Pontefract, Alexandra Janine
Format: Text
Language:English
Published: Scholarship@Western 2013
Subjects:
Impact Crater
Endoliths
Origins of Life
Analogue
Mars
Shocked Gneiss
Biogeochemistry
Canada
Devon Island
Online Access:https://ir.lib.uwo.ca/etd/1668
https://ir.lib.uwo.ca/context/etd/article/3058/viewcontent/auto_convert.pdf
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spelling ftunivwestonta:oai:ir.lib.uwo.ca:etd-3058 2023-10-01T03:55:38+02:00 Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada Pontefract, Alexandra Janine 2013-09-25T07:00:00Z application/pdf https://ir.lib.uwo.ca/etd/1668 https://ir.lib.uwo.ca/context/etd/article/3058/viewcontent/auto_convert.pdf English eng Scholarship@Western https://ir.lib.uwo.ca/etd/1668 https://ir.lib.uwo.ca/context/etd/article/3058/viewcontent/auto_convert.pdf Electronic Thesis and Dissertation Repository Impact Crater Endoliths Origins of Life Analogue Mars Shocked Gneiss Biogeochemistry text 2013 ftunivwestonta 2023-09-03T07:18:13Z Meteorite impacts are ubiquitous throughout our solar system and are a fundamental geological process on rocky and icy planetary bodies. Though initially detrimental to biology, an impact event can favourably change the availability and habitability of a substrate for endolithic organisms, which are then able to (re)colonize micro-fractures and pore spaces created during the impact. The colonization of rocks by endolithic communities is an advantageous trait, especially in environments such as hot or cold deserts, where temperature shifts, low water availability and high UV indices pose a significant problem. On Mars, similar conditions – albeit, more extreme – prevail. In these instances, impact structures could provide refuge to endolithic organisms. Previous work has shown the increase of microbial biomass with shock level in sedimentary rocks, related to increases in porosity. However, sedimentary rocks experience a collapse of pore spaces at pressures over ~35 GPa and, thus, do not support endolithic colonization at pressures higher than this. In contrast, the porosity of crystalline rocks such as gneisses increases proportionally until vapourization. This study considers shocked gneisses from the 39 Ma, 23 km diameter Haughton impact structure, Devon Island, Canada, and investigates the relationship between shock metamorphism and microbial colonization. Utilizing a variety of microscopy techniques, the subsurface community was visualized and the biomass levels calculated with increasing shock metamorphism. Average cell abundance was found to increase with shock level, with a maximum of 108 cells/g. It was found that microbial biomass did increase with increasing porosity, and was not affected by reductions in trace element concentrations of the rock, likely being more dependent on exogenous nutrients within meteoric waters or supplied aerially. It can be concluded that crystalline substrates can become habitats for endolithic organisms through the process of impact metamorphism, providing an excellent ... Text Devon Island The University of Western Ontario: Scholarship@Western Canada Devon Island ENVELOPE(-88.000,-88.000,75.252,75.252)
institution Open Polar
collection The University of Western Ontario: Scholarship@Western
op_collection_id ftunivwestonta
language English
topic Impact Crater
Endoliths
Origins of Life
Analogue
Mars
Shocked Gneiss
Biogeochemistry
spellingShingle Impact Crater
Endoliths
Origins of Life
Analogue
Mars
Shocked Gneiss
Biogeochemistry
Pontefract, Alexandra Janine
Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada
topic_facet Impact Crater
Endoliths
Origins of Life
Analogue
Mars
Shocked Gneiss
Biogeochemistry
description Meteorite impacts are ubiquitous throughout our solar system and are a fundamental geological process on rocky and icy planetary bodies. Though initially detrimental to biology, an impact event can favourably change the availability and habitability of a substrate for endolithic organisms, which are then able to (re)colonize micro-fractures and pore spaces created during the impact. The colonization of rocks by endolithic communities is an advantageous trait, especially in environments such as hot or cold deserts, where temperature shifts, low water availability and high UV indices pose a significant problem. On Mars, similar conditions – albeit, more extreme – prevail. In these instances, impact structures could provide refuge to endolithic organisms. Previous work has shown the increase of microbial biomass with shock level in sedimentary rocks, related to increases in porosity. However, sedimentary rocks experience a collapse of pore spaces at pressures over ~35 GPa and, thus, do not support endolithic colonization at pressures higher than this. In contrast, the porosity of crystalline rocks such as gneisses increases proportionally until vapourization. This study considers shocked gneisses from the 39 Ma, 23 km diameter Haughton impact structure, Devon Island, Canada, and investigates the relationship between shock metamorphism and microbial colonization. Utilizing a variety of microscopy techniques, the subsurface community was visualized and the biomass levels calculated with increasing shock metamorphism. Average cell abundance was found to increase with shock level, with a maximum of 108 cells/g. It was found that microbial biomass did increase with increasing porosity, and was not affected by reductions in trace element concentrations of the rock, likely being more dependent on exogenous nutrients within meteoric waters or supplied aerially. It can be concluded that crystalline substrates can become habitats for endolithic organisms through the process of impact metamorphism, providing an excellent ...
format Text
author Pontefract, Alexandra Janine
author_facet Pontefract, Alexandra Janine
author_sort Pontefract, Alexandra Janine
title Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada
title_short Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada
title_full Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada
title_fullStr Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada
title_full_unstemmed Impact Craters as Habitats for Life: Endolithic Colonization of Shocked Gneiss from the Haughton Impact Structure, Devon Island, Canada
title_sort impact craters as habitats for life: endolithic colonization of shocked gneiss from the haughton impact structure, devon island, canada
publisher Scholarship@Western
publishDate 2013
url https://ir.lib.uwo.ca/etd/1668
https://ir.lib.uwo.ca/context/etd/article/3058/viewcontent/auto_convert.pdf
long_lat ENVELOPE(-88.000,-88.000,75.252,75.252)
geographic Canada
Devon Island
geographic_facet Canada
Devon Island
genre Devon Island
genre_facet Devon Island
op_source Electronic Thesis and Dissertation Repository
op_relation https://ir.lib.uwo.ca/etd/1668
https://ir.lib.uwo.ca/context/etd/article/3058/viewcontent/auto_convert.pdf
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