The relationships between vegetation type and topography in Lassen Volcanic National Park

The relationships between topographic features and the relative abundances of vegetation types were analyzed for the mid-montane conifer forests, the upper montane conifer forests and the alpine areas of Lassen Volcanic National Park in the Cascade Range of northern California using Landsat Thematic...

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Veröffentlicht in:	Plant ecology 1997-07, Vol.131 (1), p.17-29
Hauptverfasser:	Pinder, J.E. III (Savannah River Ecology Lab., Aiken, SC (USA).), Kroh, G.C, White, J.D, Basham May, A.M
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Sprache:	eng
Schlagworte:	BIODIVERSIDAD BIODIVERSITE BIODIVERSITY BOSQUE DE CONIFERAS CALIFORNIA CALIFORNIE Chaparral CONIFEROUS FORESTS Coniferous trees Conifers FORET RESINEUSE Landsat Montane forests National parks Plant ecology REMOTE SENSING Slopes Sloping terrain Solar radiation Statistical significance TELEDETECCION TELEDETECTION TOPOGRAFIA Topographical aspect Topographical elevation TOPOGRAPHIE TOPOGRAPHY Valleys VEGETACION VEGETATION
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creator	Pinder, J.E. III (Savannah River Ecology Lab., Aiken, SC (USA).) Kroh, G.C White, J.D Basham May, A.M
description	The relationships between topographic features and the relative abundances of vegetation types were analyzed for the mid-montane conifer forests, the upper montane conifer forests and the alpine areas of Lassen Volcanic National Park in the Cascade Range of northern California using Landsat Thematic Mapper data. Vegetation types were identified from Landsat Thematic Mapper data and included pine, fir, montane chaparral, willow/alder and herbaceous communities. Topographic features including aspect, slope steepness, slope configuration (i.e., convex, straight or concave) and slope position (i.e., ridge top to valley bottom) were computed from USGS Digital Elevation Models. The distribution of montane chaparral was consistent with its dependency on fire with chaparral communities being more abundant on more xeric aspects and on steeper and more xeric slope configurations. Slope position was important in determining the distribution of willow/alder communities which were more abundant in valley bottom locations. Both slope steepness and slope position affected the abundance of herbaceous communities. Herbaceous communities were: (1) more prevalent on steeper slopes due to the distribution of dicotyledonous forb species; and (2) more abundant in valley bottoms due to the distribution of monocotyledonous species in wet meadows. Pines and firs were separated along a gradient of slope steepness with the firs being more abundant on steep slopes and the pines being more abundant on shallow slopes. In the alpine areas above 2350 m, the abundance of most vegetation types declined with increasingly mesic aspects. This decline may be related to the prolonged persistence of snow in areas of less intense solar radiation.
doi_str_mv	10.1023/a:1009792123571
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The distribution of montane chaparral was consistent with its dependency on fire with chaparral communities being more abundant on more xeric aspects and on steeper and more xeric slope configurations. Slope position was important in determining the distribution of willow/alder communities which were more abundant in valley bottom locations. Both slope steepness and slope position affected the abundance of herbaceous communities. Herbaceous communities were: (1) more prevalent on steeper slopes due to the distribution of dicotyledonous forb species; and (2) more abundant in valley bottoms due to the distribution of monocotyledonous species in wet meadows. Pines and firs were separated along a gradient of slope steepness with the firs being more abundant on steep slopes and the pines being more abundant on shallow slopes. In the alpine areas above 2350 m, the abundance of most vegetation types declined with increasingly mesic aspects. 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Topographic features including aspect, slope steepness, slope configuration (i.e., convex, straight or concave) and slope position (i.e., ridge top to valley bottom) were computed from USGS Digital Elevation Models. The distribution of montane chaparral was consistent with its dependency on fire with chaparral communities being more abundant on more xeric aspects and on steeper and more xeric slope configurations. Slope position was important in determining the distribution of willow/alder communities which were more abundant in valley bottom locations. Both slope steepness and slope position affected the abundance of herbaceous communities. Herbaceous communities were: (1) more prevalent on steeper slopes due to the distribution of dicotyledonous forb species; and (2) more abundant in valley bottoms due to the distribution of monocotyledonous species in wet meadows. Pines and firs were separated along a gradient of slope steepness with the firs being more abundant on steep slopes and the pines being more abundant on shallow slopes. In the alpine areas above 2350 m, the abundance of most vegetation types declined with increasingly mesic aspects. This decline may be related to the prolonged persistence of snow in areas of less intense solar radiation.</abstract><cop>Dordrecht</cop><pub>Kluwer Publishers</pub><doi>10.1023/a:1009792123571</doi><tpages>13</tpages></addata></record>
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subjects	BIODIVERSIDAD BIODIVERSITE BIODIVERSITY BOSQUE DE CONIFERAS CALIFORNIA CALIFORNIE Chaparral CONIFEROUS FORESTS Coniferous trees Conifers FORET RESINEUSE Landsat Montane forests National parks Plant ecology REMOTE SENSING Slopes Sloping terrain Solar radiation Statistical significance TELEDETECCION TELEDETECTION TOPOGRAFIA Topographical aspect Topographical elevation TOPOGRAPHIE TOPOGRAPHY Valleys VEGETACION VEGETATION
title	The relationships between vegetation type and topography in Lassen Volcanic National Park
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