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Evaluation of climate change over the continental United States using a moisture index

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Abstract

This paper uses a modified form of Thornthwaite’s moisture index to better quantify climate variability by integrating the effects of temperature and precipitation. Using the moisture index, trends were evaluated over the last 112 years (1895–2006), when unique changes in temperature and precipitation have been documented to have occurred. In addition, data on potential evapotranspiration and the moisture index were used to investigate changing climate and vegetation regions. The results show that the eastern half of the country has been getting wetter, even as temperatures have continued to increase in many areas. In particular, conditions have become wetter in the South, Northeast, and East North Central regions. The changing climate is illustrated by computing climate and vegetation regions for three 30-year periods (1910–1939, 1940–1969, and 1970–1999). Climate regions based on the moisture index show an expansion of the Humid region (where precipitation vastly exceeds climatic demands for water) across the East as well as a westward shift in the zero moisture index line. In terms of vegetation zones, the most dramatic change occurs across the Midwestern prairie peninsula where the wetter conditions lead to a westward expansion of conditions favorable for oak–hickory–pine vegetation.

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Authors and Affiliations

  1. Climatology Research Laboratory, Department of Geography, University of Georgia, Athens, GA, 30602-2502, USA

    Andrew Grundstein

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  1. Andrew Grundstein
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Correspondence to Andrew Grundstein.

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Grundstein, A. Evaluation of climate change over the continental United States using a moisture index. Climatic Change 93, 103–115 (2009). https://doi.org/10.1007/s10584-008-9480-3

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  • DOI: https://doi.org/10.1007/s10584-008-9480-3

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