Riverbed Clogging Associated with a California Riverbank Filtration System: An Assessment of Mechanisms and Monitoring Approaches

Craig Ulrich, Susan S. Hubbard, Joan Florsheim, Donald Rosenberry, Sharon Borglin, Marcus Trotta, Donald Seymour

Research output: Contribution to journalArticlepeer-review

46 Scopus citations

Abstract

An experimental field study was performed to investigate riverbed clogging processes and associated monitoring approaches near a dam-controlled riverbank filtration facility in Northern California. Motivated by previous studies at the site that indicated riverbed clogging plays an important role in the performance of the riverbank filtration system, we investigated the spatiotemporal variability and nature of the clogging. In particular, we investigated whether the clogging was due to abiotic or biotic mechanisms. A secondary aspect of the study was the testing of different methods to monitor riverbed clogging and related processes, such as seepage. Monitoring was conducted using both point-based approaches and spatially extensive geophysical approaches, including: grain-size analysis, temperature sensing, electrical resistivity tomography, seepage meters, microbial analysis, and cryocoring, along two transects. The point monitoring measurements suggested a substantial increase in riverbed biomass (2 orders of magnitude) after the dam was raised compared to the small increase (~2%) in fine-grained sediment. These changes were concomitant with decreased seepage. The decreased seepage eventually led to the development of an unsaturated zone beneath the riverbed, which further decreased infiltration capacity. Comparison of our time-lapse grain-size and biomass datasets suggested that biotic processes played a greater role in clogging than did abiotic processes. Cryocoring and autonomous temperature loggers were most useful for locally monitoring clogging agents, while electrical resistivity data were useful for interpreting the spatial extent of a pumping-induced unsaturated zone that developed beneath the riverbed after riverbed clogging was initiated. The improved understanding of spatiotemporally variable riverbed clogging and monitoring approaches is expected to be useful for optimizing the riverbank filtration system operations.

Original languageEnglish
Pages (from-to)1740-1753
Number of pages14
JournalJournal of Hydrology
Volume529
DOIs
StatePublished - Oct 1 2015
Externally publishedYes

Funding

The authors would like to thank Jay Jasperse and George Lincoln (Sonoma County Water Agency) for their data and insights, and Gabriella Vozza (UC Berkeley) for her help in the rock lab sieving cores and installing instrumentation during the May campaign. We would also like to thank Baptiste Dafflon and Boris Faybishenko for insights and suggestions during the formulation of this project and publication, and John Callaway for insights and use of his cryocorer. We acknowledge the funding support by Sonoma County Water Agency. Use of brand names is for informational purposes only and does not constitute endorsement by the authors, Lawrence Berkeley National Laboratory, U.S. Geological Survey, University of California, Santa Barbara, and Sonoma County Water Agency.

FundersFunder number
Sonoma County Water Agency

    Keywords

    • Electrical resistivity
    • Riverbank filtration
    • Riverbed clogging
    • Riverbed permeability
    • Seepage meter
    • Thermal seepage

    Fingerprint

    Dive into the research topics of 'Riverbed Clogging Associated with a California Riverbank Filtration System: An Assessment of Mechanisms and Monitoring Approaches'. Together they form a unique fingerprint.

    Cite this