2003 Seattle Annual Meeting (November 2–5, 2003)

Paper No. 7
Presentation Time: 10:05 AM

DEBRIS FLOWS AS AGENTS OF MORPHOLOGICAL HETEROGENEITY AT LOW-ORDER CONFLUENCES, OLYMPIC MOUNTAINS, WASHINGTON


VELDHUISEN, Curt, Skagit System Cooperative, 25944 Community Plaza Way, Sedro Woolley, WA 98284, BENDA, Lee, Earth Systems Institute, 310 N. Mt. Shasta Blvd., Suite 6, Mt. Shasta, CA 96067 and BLACK, Jenelle, Pentec Environmental, Inc, 120 Third Ave. S, Suite 110, Edmonds, WA 98020, cveldhuisen@skagitcoop.org

Effect of tributary junctions on longitudinal patterns of morphological heterogeneity is relevant to both fluvial geomorphology and riverine ecology. We surveyed ten kilometers of small to moderate size mountain channels in the Olympic Peninsula, Washington to investigate how low-order confluences prone to debris flow deposition directly and indirectly influenced channel and valley morphology. In the Olympic Mountains, debris flows scour sediment and organic material from steep first- and second-order channels and create deposits (debris fans) at tributary junctions in higher-order streams. In lower-energy depositional environments, there were statistically significant relationships among debris fans at low-order confluences and gravel substrate, wide channels, and numbers of logs and large pools. Effects of debris fans on channel morphology extended upstream and downstream of fan perimeters, indicating the importance of indirect (offsite) effects of debris flows. Consequently, certain aspects of channel morphology (e.g. pool density, substrate texture, channel widths) were non-uniformly distributed, reflecting the role of network topology and disturbance history on the spatial scale of morphological heterogeneity. Moreover, heterogeneity of channel morphology increased in proximity to low-order confluences prone to debris flows. In contrast, confluence effects in higher-energy depositional environments were limited. Our field data and information from seven other studies indicate how variation in debris flow volume and composition, stream energy, and valley width at the point of deposition influence the relationship between low-order confluences and channel morphology.