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Diatoms in Saline Lakes Paleoclimate and Paleoecology Interpretations

Published online by Cambridge University Press:  21 July 2017

Erik J. Ekdahl
Erik J. Ekdahl*
Affiliation:
VESTRA Resources, Inc. 5300 Aviation Drive Redding, CA 96002
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Abstract

Average global temperatures are predicted to rise over the next century and changes in precipitation, humidity, and drought frequency will likely accompany this global warming. Understanding associated changes in continental precipitation and temperature patterns in response to global change is an important component of long-range environmental planning. For example, agricultural management plans that account for decreased precipitation over time will be less susceptible to the effects of drought through implementation of water conservation techniques.

A detailed understanding of environmental response to past climate change is key to understanding environmental changes associated with global climate change. To this end, diatoms are sensitive to a variety of limnologic parameters, including nutrient concentration, light availability, and the ionic concentration and composition of the waters that they live in (e.g. salinity). Diatoms from numerous environments have been used to reconstruct paleosalinity levels, which in turn have been used as a proxy records for regional and local paleoprecipitation. Long-term records of salinity or paleoprecipitation are valuable in reconstructing Quaternary paleoclimate, and are important in terms of developing mitigation strategies for future global climate change. High-resolution paleoclimate records are also important in groundtruthing global climate simulations, especially in regions where the consequences of global warming may be severe.

Type
Research Article
Information
The Paleontological Society Papers , Volume 13: Pond Scum to Carbon Sink: Geological and Environmental Applications of the Diatoms , October 2007 , pp. 149 - 168
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Copyright © by the Paleontological Society 

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