Microbial geomorphology: A neglected link between life and landscape
- 作者:Heather A. Viles ; heather.viles@ouce.ox.ac.uk
- 关键词:Microorganisms ; Biogeomorphology ; Ecosystem engineers ; Lichens ; Fungi ; Algae ; Bacteria
- 刊名:Geomorphology
- 出版年:2012
- 期刊代码:31_0169555x
- 类别:soc
- 出版时间:1 July, 2012
- 卷:157-158
- 期:Complete
- 页码:6-16
- 文件大小:1630 K
摘要
Whilst recognition is increasing that life and landscapes are intimately related, as evidenced by growing research into ecosystem engineering, biogeomorphology and allied topics, the microbial contribution to such interactions has been relatively neglected. A revolution in environmental microbiology, based on molecular techniques, is now driving a reconsideration of the role of microbial processes in geomorphology at all scales. Recent research illustrates the hitherto unknown microbial diversity present in many extreme geomorphic environments, such as hyperarid deserts, subglacial lakes, hot springs, and much richer microbial life than previously suspected within the soils and sediments that blanket most other landscapes. Such microbial communities have been found to play important geomorphic roles across a wide range of environments, notably in weathering, precipitation of minerals and protecting surfaces from erosion. These geomorphic roles can also be conceptualised as examples of ecosystem engineering, and can pave the way for further plant-geomorphology and zoogeomorphology processes. Three key aspects which emerge from a review of microbial influences on Earth surface processes are a) that microbes play roles on a continuum from full control to passive involvement, b) that complex and widespread communities of microorganisms are involved and c) that microbial activity usually affects several Earth surface processes at once. Examples of the contribution of microbial life to geomorphology over long, medium and short timescales suggest that microorganisms play key geomorphological roles in two major situations; on the cusp between stable states, and in extreme environments where higher plant and animal life is limited and many abiotic processes are also constrained. The dominant link between microbial life and geomorphology appears to take on different forms depending on the timescale under consideration, with a stabilising microbial role apparent over short timescales being replaced by a denudational role over longer timescales. Further research involving microbiologists and geomorphologists is now needed to address three main questions, i.e. under what conditions are microbial and geomorphological processes most closely linked?, what scale issues surround links between microbes and geomorphology? And how do microbiological processes underpin broader biogeomorphological interactions?