Six years of fluvial response to a large dam removal on the Carmel River, California, USA

Measuring river response to dam removal affords a rare, important opportunity to study fluvial response to sediment pulses on a large field scale. We present a before–after/control–impact study of the Carmel River, California, measuring fluvial geomorphic and grain‐size evolution over 8 years, six of which postdated removal of a 32 m‐high dam (one of the largest dams removed worldwide) and included 11 flow events exceeding the 2‐year flood magnitude. We find that the reservoir‐sediment pulse following dam removal was relatively small (97 000 ± 24 000 t over 4 years), owing to deliberate reservoir‐sediment stabilization. Scaled to the size of the Carmel River watershed and compared against long‐term bedrock denudation rates, the post‐dam‐removal sediment release was slightly less than the annualized long‐term sediment export from this basin. New sediment transited >30 km to the river mouth in less than 2 years, assisted by floods 2 and 4 years after dam removal. The sediment pulse fined the downstream riverbed while causing mostly low‐magnitude bed‐elevation changes: commonly 0.5 to 1 m or smaller, occurring as discontinuous sediment patches or interstitial deposits, aside from the filling and subsequent partial scour of deep pools. There was no major geomorphic reset downstream from the dam site. Geomorphic changes were driven almost entirely by flow rather than by the modest increase in sediment supply, in contrast to recent examples from other large dam removals. The relatively minor disturbance caused by dam removal on the Carmel River is likely analogous to many future dam removals: a relatively small sediment pulse after deliberate limitation of reservoir‐sediment erosion, and with an upstream dam remaining in place. Thus, a large dam removal need not lead to major downstream impacts.

[1]  D. L. Swain,et al.  Climate change is increasing the risk of a California megaflood , 2022, Science advances.

[2]  P. Ashmore,et al.  Flow Strength and Bedload Sediment Travel Distance in Gravel Bed Rivers , 2022 .

[3]  E. Langendoen,et al.  Reach-scale morphodynamics: Insights from 20 years of observations and model simulations , 2022, Geomorphology.

[4]  J. Yi,et al.  Dam Renovation to Prolong Reservoir Life and Mitigate Dam Impacts , 2022, Water.

[5]  L. Marshall,et al.  Influence of a Post-dam Sediment Pulse and Post-fire Debris Flows on Steelhead Spawning Gravel in the Carmel River, California , 2021, Frontiers in Earth Science.

[6]  Samuel J. Brenkman,et al.  Reconnecting the Elwha River: Spatial Patterns of Fish Response to Dam Removal , 2021, Frontiers in Ecology and Evolution.

[7]  A. Recking,et al.  Triggering and propagation of exogenous sediment pulses in mountain channels: insights from flume experiments with seismic monitoring , 2021, Earth Surface Dynamics.

[8]  B. Dickson,et al.  Prioritizing dams for removal to advance restoration and conservation efforts in the western United States , 2021, Restoration Ecology.

[9]  P. Belmont,et al.  Simulated Dynamics of Mixed Versus Uniform Grain Size Sediment Pulses in a Gravel‐Bedded River , 2021, Journal of Geophysical Research: Earth Surface.

[10]  C. Renshaw,et al.  A mechanistic understanding of channel evolution following dam removal , 2021, Geomorphology.

[11]  J. Dietrich,et al.  Transient versus sustained biophysical responses to dam removal , 2021 .

[12]  G. Pasternack,et al.  Flooding duration and volume more important than peak discharge in explaining 18 years of gravel–cobble river change , 2021, Earth Surface Processes and Landforms.

[13]  J. Curran,et al.  How sediment composition and flow rate influence downstream channel morphodynamics upon dam removal , 2021, Earth Surface Processes and Landforms.

[14]  A. Crosato,et al.  Validation of Model-Based Optimization of Reservoir Sediment Releases by Dam Removal , 2021, Journal of Water Resources Planning and Management.

[15]  E. Gautier,et al.  Morpho-sedimentary dynamics associated to dam removal. The Pierre Glissotte dam (central France). , 2021, The Science of the total environment.

[16]  Yuqing Lin,et al.  Removing tributary low-head dams can compensate for fish habitat losses in dammed rivers , 2021, Journal of Hydrology.

[17]  E. Wohl,et al.  Logjam attenuation of annual sediment waves in eolian-fluvial environments, North Park, Colorado, USA , 2021 .

[18]  S. W. Anderson,et al.  Channel response to a dam‐removal sediment pulse captured at high‐temporal resolution using routine gage data , 2021, Earth Surface Processes and Landforms.

[19]  D. Ralston,et al.  Watershed Suspended Sediment Supply and Potential Impacts of Dam Removals for an Estuary , 2021, Estuaries and Coasts.

[20]  S. Chalov,et al.  Dam and reservoir removal projects: a mix of social-ecological trends and cost-cutting attitudes , 2020, Scientific Reports.

[21]  P. Diplas,et al.  Modeling Hydro‐Morphodynamic Processes During the Propagation of Fluvial Sediment Pulses: A Physics‐Based Framework , 2020, Journal of Geophysical Research: Earth Surface.

[22]  J. Sankey,et al.  Geomorphic and Sedimentary Effects of Modern Climate Change: Current and Anticipated Future Conditions in the Western United States , 2020, Reviews of Geophysics.

[23]  S. Narum,et al.  Robust Recolonization of Pacific Lamprey Following Dam Removals , 2020 .

[24]  M. Collins,et al.  River channel response to dam removals on the lower Penobscot River, Maine, United States , 2020, River Research and Applications.

[25]  W. Monk,et al.  Large dam renewals and removals—Part 1: Building a science framework to support a decision‐making process , 2020, River Research and Applications.

[26]  F. Vahedifard,et al.  Preparing for proactive dam removal decisions , 2020, Science.

[27]  Douglas P. Smith,et al.  Controls on large boulder mobility in an ‘auto‐naturalized’ constructed step‐pool river: San Clemente Reroute and Dam Removal Project, Carmel River, California, USA , 2020, Earth Surface Processes and Landforms.

[28]  D. Goodman,et al.  Natural Recolonization by Pacific Lampreys in a Southern California Coastal Drainage: Implications for Their Biology and Conservation , 2020 .

[29]  K. Birnie‐Gauvin,et al.  Catchment-scale effects of river fragmentation: A case study on restoring connectivity. , 2020, Journal of environmental management.

[30]  M. Dettinger,et al.  Observations of an Extreme Atmospheric River Storm With a Diverse Sensor Network , 2020, Earth and Space Science.

[31]  M. Huijbregts,et al.  Impacts of current and future large dams on the geographic range connectivity of freshwater fish worldwide , 2020, Proceedings of the National Academy of Sciences.

[32]  L. Hubert‐Moy,et al.  Large dam removal and early spontaneous riparian vegetation recruitment on alluvium in a former reservoir: Lessons learned from the pre‐removal phase of the Sélune River project (France) , 2019, River Research and Applications.

[33]  M. Thieme,et al.  Mapping the world’s free-flowing rivers , 2019, Nature.

[34]  G. K. Gilbert Hydraulic-Mining Debris in the Sierra Nevada , 2019 .

[35]  Laura S. Craig,et al.  Conceptualizing Ecological Responses to Dam Removal: If You Remove It, What's to Come? , 2019, Bioscience.

[36]  J. Sankey,et al.  Geomorphic Evolution of a Gravel‐Bed River Under Sediment‐Starved Versus Sediment‐Rich Conditions: River Response to the World's Largest Dam Removal , 2018, Journal of Geophysical Research: Earth Surface.

[37]  A. Gray The impact of persistent dynamics on suspended sediment load estimation , 2018, Geomorphology.

[38]  G. Hilley,et al.  Millennial-scale denudation rates of the Santa Lucia Mountains, California: Implications for landscape evolution in steep, high-relief, coastal mountain ranges , 2018 .

[39]  Randall E. McCoy,et al.  Morphodynamic evolution following sediment release from the world’s largest dam removal , 2018, Scientific Reports.

[40]  J. Logan,et al.  River response to large‐dam removal in a Mediterranean hydroclimatic setting: Carmel River, California, USA , 2018, Earth Surface Processes and Landforms.

[41]  M. M. Orescanin,et al.  Observations of episodic breaching and closure at an ephemeral river , 2018, Continental Shelf Research.

[42]  Stuart N. Lane,et al.  Connectivity as an emergent property of geomorphic systems , 2018, Earth Surface Processes and Landforms.

[43]  P. Henry,et al.  Beyond equilibrium: re-evaluating physical modelling of fluvial systems to represent climate changes , 2019 .

[44]  Alex Hall,et al.  Increasing precipitation volatility in twenty-first-century California , 2018, Nature Climate Change.

[45]  G. Brierley,et al.  Reaction and relaxation in a coarse-grained fluvial system following catchment-wide disturbance , 2017 .

[46]  Randall E. McCoy,et al.  Coastal habitat and biological community response to dam removal on the Elwha River , 2017 .

[47]  Xu-dong Fu,et al.  Gravel‐bed river evolution in earthquake‐prone regions subject to cycled hydrographs and repeated sediment pulses , 2017 .

[48]  J. Moody Residence times and alluvial architecture of a sediment superslug in response to different flow regimes , 2017 .

[49]  N. Snyder,et al.  Channel response to sediment release: insights from a paired analysis of dam removal , 2017 .

[50]  Laura S. Craig,et al.  Landscape context and the biophysical response of rivers to dam removal in the United States , 2017, PloS one.

[51]  Laura S. Craig,et al.  Dam removal: Listening in , 2017 .

[52]  T. Beechie,et al.  Channel‐planform evolution in four rivers of Olympic National Park, Washington, USA: the roles of physical drivers and trophic cascades , 2017 .

[53]  D. Tullos,et al.  Geomorphic Responses to Dam Removal in the United States – a Two‐Decade Perspective , 2017 .

[54]  J. Ryan Bellmore,et al.  Status and trends of dam removal research in the United States , 2017 .

[55]  Stuart N. Lane,et al.  Sediment export, transient landscape response and catchment-scale connectivity following rapid climate warming and Alpine glacier recession , 2017 .

[56]  N. Finnegan,et al.  Interplay between grain protrusion and sediment entrainment in an experimental flume , 2017 .

[57]  J. Martín-Vide,et al.  Geomorphic monitoring and response to two dam removals: rivers Urumea and Leitzaran (Basque Country, Spain) , 2016 .

[58]  D. Tullos,et al.  Synthesis of Common Management Concerns Associated with Dam Removal , 2016 .

[59]  R. Newton,et al.  Historically unprecedented erosion from Tropical Storm Irene due to high antecedent precipitation , 2016 .

[60]  J. Hooke Variations in flood magnitude–effect relations and the implications for flood risk assessment and river management , 2015 .

[61]  P. Marra,et al.  The rapid return of marine-derived nutrients to a freshwater food web following dam removal , 2015 .

[62]  Jonathan A. Warrick,et al.  Large-scale dam removal on the Elwha River, Washington, USA: Source-to-sink sediment budget and synthesis , 2015 .

[63]  Robert C. Hilldale,et al.  Large-scale dam removal on the Elwha River, Washington, USA: fluvial sediment load , 2015 .

[64]  A. Ritchie,et al.  Large-scale dam removal on the Elwha River, Washington, USA: Erosion of reservoir sediment , 2015 .

[65]  E. Wohl Legacy effects on sediments in river corridors , 2015 .

[66]  D. Tullos,et al.  Effects of sediment pulses on bed relief in bar‐pool channels , 2015 .

[67]  G. Grant,et al.  1000 dams down and counting , 2015, Science.

[68]  A. E. Draut,et al.  Sedimentology of New Fluvial Deposits on the Elwha River, Washington, USA, Formed During Large‐Scale Dam Removal , 2015 .

[69]  Timothy J. Randle,et al.  Large-scale dam removal on the Elwha River, Washington, USA: River channel and floodplain geomorphic change , 2014 .

[70]  D. Tullos,et al.  Geomorphic and Ecological Disturbance and Recovery from Two Small Dams and Their Removal , 2014, PloS one.

[71]  J. Major,et al.  Rapid reservoir erosion, hyperconcentrated flow, and downstream deposition triggered by breaching of 38 m tall Condit Dam, White Salmon River, Washington , 2014 .

[72]  A. Wilcox,et al.  FINE SEDIMENT INFILTRATION DYNAMICS IN A GRAVEL‐BED RIVER FOLLOWING A SEDIMENT PULSE , 2014 .

[73]  T. Quinn,et al.  Re-colonization of Atlantic and Pacific rivers by anadromous fishes: linkages between life history and the benefits of barrier removal , 2014, Reviews in Fish Biology and Fisheries.

[74]  J. O’Connor,et al.  Geomorphically Effective Floods , 2013 .

[75]  Y. Lai,et al.  Sediment impacts from the Savage Rapids Dam removal, Rogue River, Oregon , 2013 .

[76]  A. Gray,et al.  The effects of wildfire on the sediment yield of a coastal California watershed , 2012 .

[77]  D. Freyberg,et al.  A comparison of past small dam removals in highly sediment-impacted systems in the U.S. , 2012 .

[78]  W. Kuo,et al.  Geomorphic Responses to a Large Check‐Dam Removal on a Mountain River in Taiwan , 2011 .

[79]  N. Snyder,et al.  Rates and processes of channel response to dam removal with a sand‐filled impoundment , 2011 .

[80]  David G. Havlick,et al.  Aging Infrastructure and Ecosystem Restoration , 2008, Science.

[81]  L. Wildman,et al.  The evolution of gravel bed channels after dam removal: Case study of the Anaconda and Union City Dam removals , 2005 .

[82]  J. Milliman,et al.  Earthquake-triggered increase in sediment delivery from an active mountain belt , 2004 .

[83]  E. Stanley,et al.  Channel adjustments following two dam removals in Wisconsin , 2003 .

[84]  James R. Thomson,et al.  AN INTEGRATIVE APPROACH TOWARDS UNDERSTANDING ECOLOGICAL RESPONSES TO DAM REMOVAL: THE MANATAWNY CREEK STUDY 1 , 2002 .

[85]  G. Tucker,et al.  Drainage basin responses to climate change , 1997 .

[86]  E. Keller,et al.  HYDROLOGICAL RESPONSE OF SMALL WATERSHEDS FOLLOWING THE SOUTHERN CALIFORNIA PAINTED CAVE FIRE OF JUNE 1990 , 1997 .

[87]  M. Madej,et al.  CHANNEL RESPONSE TO SEDIMENT WAVE PROPAGATION AND MOVEMENT, REDWOOD CREEK, CALIFORNIA, USA , 1996 .

[88]  G. Mathias Kondolf,et al.  The sizes of salmonid spawning gravels , 1993 .

[89]  H. Martinson,et al.  Rates and processes of channel development and recovery following the 1980 eruption of Mount St. Helens, Washington , 1989 .

[90]  S. Trimble Changes in Sediment Storage in the Coon Creek Basin, Driftless Area, Wisconsin, 1853 to 1975 , 1981, Science.

[91]  M. Wolman A method of sampling coarse river‐bed material , 1954 .

[92]  P. Davies,et al.  Lagoon of Islands, Tasmania: Ecosystem response to dam wall removal , 2021 .

[93]  J. Major,et al.  Sediment erosion and delivery from Toutle River basin after the 1980 eruption of Mount St. Helens: A 30-year perspective , 2018 .

[94]  J. Logan,et al.  River-channel topography, grain size, and turbidity records from the Carmel River, California, before, during, and after removal of San Clemente Dam , 2017 .

[95]  C. Renshaw,et al.  The efficacy of stream power and flow duration on geomorphic responses to catastrophic flooding , 2015 .

[96]  Gordon E. Grant,et al.  The Remains of the Dam: What Have We Learned from 15 Years of US Dam Removals? , 2015 .

[97]  K. Tockner,et al.  A global boom in hydropower dam construction , 2014, Aquatic Sciences.

[98]  P. Wilcock,et al.  Geomorphic Response of the Sandy River, Oregon, Following Removal of Marmot Dam , 2012 .

[99]  D. Montgomery,et al.  Spatial and temporal patterns in fluvial recovery following volcanic eruptions: Channel response to basin-wide sediment loading at Mount Pinatubo, Philippines , 2005 .

[100]  S. Adl,et al.  Spatial and temporal patterns. , 2003 .

[101]  of efficacy: , 2022 .