LONG-TERM COTTONWOOD FOREST DYNAMICS ALONG THE UPPER MISSOURI RIVER, USA

ABSTRACT The upper Missouri River bottomland in north‐central Montana, USA, retains much of the physical character it had when traversed by Lewis and Clark around 1805. We used geospatial data to quantify long‐term changes in the distribution of bottomland vegetation, land use patterns and channel p...

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Bibliographic Details
Published in:	River research and applications Vol. 29; no. 8; pp. 1016 - 1029
Main Authors:	Scott, M. L., Auble, G. T., Dixon, M. D., Carter Johnson, W., Rabbe, L. A.
Format:	Journal Article
Language:	English
Published:	Chichester Blackwell Publishing Ltd 01-10-2013 Wiley Wiley Subscription Services, Inc
Subjects:	Animal and plant ecology Animal, plant and microbial ecology Biological and medical sciences channel narrowing cottonwood dams Deforestation forest dynamics Forests Fresh water ecosystems Fundamental and applied biological sciences. Psychology GIS Missouri River state and transition models Studies Synecology vegetation cover types United States North America America channel narrowing Missouri River cottonwood Missouri Basin Environmental factor forest dynamics Vegetation dynamics vegetation cover types River basins Long term dams GIS Dam state and transition models Vegetation type Geographic information system Plant cover Models
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Summary:	ABSTRACT The upper Missouri River bottomland in north‐central Montana, USA, retains much of the physical character it had when traversed by Lewis and Clark around 1805. We used geospatial data to quantify long‐term changes in the distribution of bottomland vegetation, land use patterns and channel planform for a 257‐rkm segment of the Missouri River above Fort Peck Reservoir. This segment is less ecologically altered than downstream segments, but two dams completed in the mid‐1950s have decreased the frequency and magnitude of floods. The area of forest is sparse because of geomorphic setting but, contrary to public perception, has remained relatively constant during the past century. However, the stability of forest area obscures its spatial and temporal dynamics. We used state and transition models to quantify fates and sources of forest during two periods: 1890s–1950s and 1950s–2006. Total forest area was 6% greater in 2006 than it was in the 1890s, largely due to reduced forest loss to erosional processes and gains related to progressive channel narrowing. Channel narrowing resulted in part from human‐caused peak flow attenuation. A modified transition matrix, used to examine future steady‐state conditions, projected little change in forest area; however, these projections are likely an overestimate. The extent to which 2006 forest area represents a transient adjustment to a new flow regime versus a dynamic, quasi–steady state will be determined by the long‐term interplay among hydrologic factors, channel processes, water management and land use practices. Published 2012. This article is a U.S. Government work and is in the public domain in the USA.
Bibliography:	ark:/67375/WNG-FH71RX8J-Z istex:28B393B1843D5E8BC477E0D60E49138C85BA1090 ArticleID:RRA2588
ISSN:	1535-1459 1535-1467
DOI:	10.1002/rra.2588