A cellular model of Holocene upland river basin and alluvial fan evolution

Coulthard, T. J. and Macklin, M. G. and Kirkby, M. J. (2002) A cellular model of Holocene upland river basin and alluvial fan evolution. Earth Surface Processes and Landforms, 27 (3). pp. 269-288. ISSN 0197-9337

Full text not available from this repository.

Item Type:Article
Item Status:Live Archive

Abstract

The CAESAR (Cellular Automaton Evolutionary Slope And River) model is used to simulate the Holocene development of a small upland catchment (4.2 km2) and the alluvial fan at its base. The model operates at a 3 m grid scale and simulates every flood over the last 9200 years, using a rainfall record reconstructed from peat bog wetness indices and land cover history derived from palynological sources. Model results show that the simulated catchment sediment discharge above the alluvial fan closely follows the climate signal, but with an increase in the amplitude of response after deforestation. The important effects of sediment storage and remobilization are shown, and findings suggest that soil creep rates may be an important control on long term (> 1000 years) temperate catchment sediment yield. The simulated alluvial fan shows a complex and episodic behaviour, with frequent avulsions across the fan surface. However, there appears to be no clear link between fan response and climate or land use changes suggesting that Holocene alluvial fan dynamics may be the result of phases of sediment storage and remobilization, or instabilities and thresholds within the fan itself. Copyright © 2002 John Wiley and Sons, Ltd.

Keywords:Catchments, Creep, Deforestation, Floods, Peat, Rain, Sediments, Soils, Alluvial fans, Palynology, Rivers, alluvial fan, fluvial geomorphology, Holocene, landform evolution, river bank, sediment yield, United Kingdom
Subjects:F Physical Sciences > F840 Physical Geography
Divisions:College of Science > School of Geography
Related URLs:
ID Code:25116
Deposited On:26 Nov 2016 10:47

Repository Staff Only: item control page