Seasonal logging, process response, and geomorphic work

Mohr, CH; Zimmermann A.; Korup, O; Iroumé A.; Francke, T; Bronstert, A

Abstract

Deforestation is a prominent anthropogenic cause of erosive overland flow and slope instability, boosting rates of soil erosion and concomitant sediment flux. Conventional methods of gauging or estimating post-logging sediment flux often focus on annual timescales but overlook potentially important process response on shorter intervals immediately following timber harvest. We resolve such dynamics with non-parametric quantile regression forests (QRF) based on high-frequency (3 min) discharge measurements and sediment concentration data sampled every 30-60 min in similar-sized (similar to 0.1 km(2)) forested Chilean catchments that were logged during either the rainy or the dry season. The method of QRF builds on the random forest algorithm, and combines quantile regression with repeated random sub-sampling of both cases and predictors. The algorithm belongs to the family of decision-tree classifiers, which allow quantifying relevant predictors in high-dimensional parameter space. We find that, where no logging occurred, similar to 80% of the total sediment load was transported during extremely variable runoff events during only 5% of the monitoring period. In particular, dry-season logging dampened the relative role of these rare, extreme sediment-transport events by increasing load efficiency during more efficient moderate events. We show that QRFs outperform traditional sediment rating curves (SRCs) in terms of accurately simulating short-term dynamics of sediment flux, and conclude that QRF may reliably support forest management recommendations by providing robust simulations of post-logging response of water and sediment fluxes at high temporal resolution.

Más información

Título según WOS: Seasonal logging, process response, and geomorphic work
Título según SCOPUS: Seasonal logging, process response, and geomorphic work
Título de la Revista: EARTH SURFACE DYNAMICS
Volumen: 2
Número: 1
Editorial: Copernicus Gesellschaft mbH
Fecha de publicación: 2014
Página de inicio: 117
Página final: 125
Idioma: English
DOI:

10.5194/esurf-2-117-2014

Notas: ISI, SCOPUS