U.S. Department of the Interior U.S. Geological Survey Sandbars and Floods in Grand Canyon: Current Research and Monitoring Paul Grams, USGS.

Slides:

Advertisements

Similar presentations

Action Effectiveness Monitoring in the Upper Columbia (Chapter 4) Karl M. Polivka, Pacific Northwest Research Station, USDA Forest Service.

Advertisements

Bay Sediment Budgets: Sediment Accounting 101 David Schoellhamer Megan Lionberger Bruce Jaffe Neil Ganju Scott Wright Greg Shellenbarger U.S. Geological.

Trends in Suspended Sediment Input to the San Francisco Bay from Local Tributaries Presented by Setenay Bozkurt Philip Williams &

Ecosystem Flows Hydrology and Connectivity Joe Trungale October 2, 2006.

Planning for fish bearing waters between Glen Canyon Dam and Lake Mead.

Sediment budget for the 2000 LSSF Experiment, in context of the last half century David J. Topping, David M. Rubin, Nancy J. Hornewer, Gregory G. Fisk,

Geomorphic Context for Sediment Sources, Movement, and Deposition in the Bad River, Bad River Reservation, Wisconsin By Faith Fitzpatrick 1, Kirsten Cahow-Scholtes.

Glen Canyon Dam Adaptive Management Program WY 2000 Low Steady Summer Flow Randy Peterson, BOR Barry D. Gold, GCMRC A Test of Concept.

US Army Corps of Engineers BUILDING STRONG ® Mid-West Electric Consumers Association September 16, 2014 Corps of Engineers US Army Missouri River Mainstem.

Proposed Research and Monitoring Plan for Evaluating Trout Management Flows below Glen Canyon Dam AZDFG, USFWS, GCRMC, Reclamation, Western.

In-Stream PIT-Tag Detection of Resident Salmonids in Washington's White Salmon River Watershed: One System ’ s Saga. Ian G. Jezorek 1, Patrick J. Connolly.

Assessment of gravel transport characteristics of the upper Santa Ana River Scott Wright and Toby Minear USGS California Water Science Center Sacramento,

Module 3 Counterpart Regulations Standards of Review for Determining Project Effects.

Glen Canyon Dam and the Colorado River: Diseases in the Grand Canyon. By Stephanie Boone.

Geomorphic Effects of Dams on Rivers Gordon Grant.

31 DECEMBER VARIABLE FLOOD CONTROL DRAFT FOR LIBBY RESERVOIR U.S. Army Corps of Engineers Northwestern Division, North Pacific Region.

Part 3 RECURRENCE FREQUENCY OF FLOODING. River flow data can be shown in a variety of formats on probability plots like that shown here, which relates.

A Preliminary Analysis of the Impacts of Climate Change on the Reliability on West Side Water Supplies Richard Palmer and Margaret Hahn Department of Civil.

Biological Objectives Tied to Physical Processes Dr. William Trush Scott McBain Arcata, CA.

Yellowtail Dam & Bighorn Lake Billings, Montana January 2011 RECLAMATION Managing Water in the West.

Yellowstone River Compact Commission Technical Committee Discussions Sheridan County Courthouse Sheridan, WY April 24, 2007 Bighorn Reservoir operations.

Fundamentals of River Restoration and Salmonid Fisheries OWEB, 1999, Fundamentals of River Restoration and Salmonid Fisheries OWEB, 1999, Fundamentals.

Rivers and Streams Chapter 18. Hydrologic Cycle Streams A stream is a body of water that is confined in a channel and moves downhill under the influence.

CRFS Technical Committee Fall Meeting LC Operations Update November 20, 2014.

Side-scanning sonar data collected prior to and immediately following the 31,000- cfs Spike-flow of September 2000 between miles 63 to 65 of the Colorado.

USGS Water Resource Monitoring and Assessment Activities Salinity and other topics presented to the Garfield County Energy Advisory Board Dec. 1, 2005.

Sand Transport in the San Francisco Bay Coastal System Patrick Barnard 1, Daniel Hanes 1, Li Erikson 1, Sand Transport in the San Francisco Bay Coastal.

Marmot Dam Removal Predictions and Observations Yantao Cui 1, Bruce Orr 1, Andrew Wilcox 2, Jen Vick 3, Charles Podolak 4, and Peter Wilcock 4 1.Stillwater.

Documenting O. mykiss life histories in the White Salmon River prior to the reintroduction of anadromous fish above Condit Dam. Brady Allen and Patrick.

Suggested Guidelines for Geomorphic aspects of Anadromous Salmonid Habitat Restoration proposals G. Mathias Kondolf.

Materials Transport & NSCD Material Classes Velocity to Transport Relationships York NSCD Restoration PSY CCREP.

February 05, 2015 Agenda Go over Chapter 9 Test

IRP Approach to Water Supply Alternatives for Duck River Watershed: Presentation to XII TN Water Resources Symposium William W. Wade Energy and Water.

Processing of a Fine Sediment Pulse after Dam Removal Sediment Budget and Longitudinal Trends Chiloquin Dam Removal – Sprague River Matt Cox, Desiree Tullos,

Bed-sediment grain-size change, and implications for sediment management David M. Rubin 1, David J. Topping 2, Henry Chezar 3, Brian Lockwood 4, James.

U.S. Department of the Interior U.S. Geological Survey Modeling sand transport and sandbar evolution along the Colorado River below Glen Canyon Dam.

WRU Workshop: Modeling Flow, Sediment Transport and Bed Evolution in Vietnamese Rivers October 29-30, 2008 Jonathan Nelson USGS Geomorphology and Sediment.

Development of a Geomorphic Model to Predict Erosion of Pre-Dam Colorado River Terraces Containing Archaeological Resources Kate Thompson and Andre Potochnik.

Managing Western Water as Climate Changes Denver, CO February 20-21, 2008.

Channel and Habitat Monitoring in the Countyline Reach of the Lower White River Presented by Sarah McCarthy and Terry Butler River and Floodplain Management.

Peabody Coal Lower Basin Pipeline Engineering Appraisal Study Bureau of Reclamation September 18, 2002.

1 State of San Lorenzo River Symposium Nicole Beck, PhD 2NDNATURE April San Lorenzo Lagoon A Decade of Dry Season WQ Monitoring.

Alan F. Hamlet, Philip W. Mote, Nate Mantua, Dennis P. Lettenmaier JISAO/CSES Climate Impacts Group Dept. of Civil and Environmental Engineering University.

SEDIMENT DELIVERY FROM UNGAGED TRIBUTARIES TO THE COLORADO RIVER IN GRAND CANYON Robert H. Webb Peter G. Griffiths U.S. Geological Survey 1675 W. Anklam.

Changes in Fine-Sediment Storage During the LSSF Matt Kaplinski, Joe Hazel, Mark Manone, Rod Parnell, Joe Cain, John Souter Northern Arizona University.

Are Kootenai River White Sturgeon Bad Parents or Have We Just Messed Up Their Habitat?

1 Columbia River Sediment Supply and Dredging Volumes David A. Jay Department of Environmental Science and Engineering, Oregon Graduate Institute.

Comparison of Benthic Invertebrate Communities Upstream and Downstream of Proposed Culvert Installations in Alabama Amy C. Gill USGS, Alabama Water Science.

October 28, 2015 Yuba River Development Project Slide 1 Licensee Response to Relicensing Participant Tunnel Closure Proposal Yuba County Water Agency Yuba.

Aquatic Resources Work Group Meeting December 18, 2008.

11/31/08 South Feather Power Project (FERC Project No. 2088) PM&E Proposal January 31, 2008 Plumas National Forest, Oroville, CA.

US Army Corps of Engineers BUILDING STRONG ® Mark Twain Lake Water Control Manual Update Joan Stemler St. Louis District Water Control.

A Sediment Budget for Two Reaches of Alameda Creek (1900s through 2006) Paul Bigelow, Sarah Pearce, Lester McKee, and Alicia Gilbreath.

US Army Corps of Engineers ® Engineer Research and Development Center West Bay Diversion Evaluation Integration of Results 6 Month Progress ERDC West Bay.

Natural and artificial hydromorphological changes in Norway Agnès Moquet-Stenback – Section for erosion and sediment transport – Hydrology.

Middle Fork Project AQ 3 – Macroinvertebrate and Aquatic Mollusk Technical Study Report Overview May 5, 2008.

U.S. Department of the Interior U.S. Geological Survey Monitoring Surface-Water-Quality in the Tongue River Watershed of Montana and Wyoming Stacy Kinsey.

Yellowtail Dam & Bighorn Lake Reservoir Operating Criteria Proposed Modifications Lovell, Wyoming July 29, 2008 RECLAMATION Managing Water in the West.

11 October 2011 JANE MOON IMPACT OF THE TERMINAL GROYNE ON SEDIMENT TRANSPORT IN MINEHEAD BAY SENIOR GEOMORPHOLOGIST.

U.S. Department of the Interior U.S. Geological Survey Dammed and Adrift: Patterns of invertebrate drift throughout Colorado River Basin tailwaters Jeff.

Estimating Annual Sediment Yield and a Sediment Delivery Ratio for Red Creek, Utah and Wyoming Paul Grams Department of Geography and Earth Resources.

Native and Wild Trout Conference April 21, 2016 Phoenix AZ

Management to Mitigate Environmental Effects of Dams

Overview of Spokane- Coeur d’Alene Hydrology

Evaluating the long-term future of fine sediment in Lake Powell

Morphodynamic and Sediment Tracers in One-Dimension

Do we focus too much on flows

photo : Michael Collier

Mississippi River Hydrodynamic and Delta Management Study

Study Update Tailrace Slough Use by Anadromous Salmonids

Presentation transcript:

U.S. Department of the Interior U.S. Geological Survey Sandbars and Floods in Grand Canyon: Current Research and Monitoring Paul Grams, USGS

Overview  What have we learned?  When will we have another flood?  How will we know if floods are working to rebuild sandbars?  What do floods have to do with trout and chub? 2

What do Floods do?  Floods do build sandbars and there has been some net gain since before the first flood in  Floods do cause net export of sand (more sand goes downstream than goes up on the banks).  Sandbars erode following floods.  Spring floods benefit rainbow trout populations as a result of improvements in spawning and rearing habitat (uncertainty exists for floods at other times)  Floods have had no measurable positive impacts on humpback chub populations (High Flow Circular, chapters 3 and 4)

Floods build sandbars 4 (in lots of places)

Floods build sandbars (not everywhere) 5 Pre-2008 HFE – RM 6 Post-2008 HFE – RM 6

Changes in Sandbar Size in Marble Canyon and Eastern Grand Canyon, /20 bars are the same or larger in size than the 1996 pre-HFE condition Adapted from Hazel and others, 2010

Changes in Sandbar Size in Central and Western Grand Canyon, /20 bars are the same or larger in size than the 1996 pre-HFE condition Adapted from Hazel and others, 2010

Floods do export sand 8 EventSand accumulated before flood Sand exported during flood 2004 flood 0.64 ± 0.3 million tons0.69 ± 0.3 million tons 2008 flood 3.5 ± 2.0 million tons1.1 ± 0.1 million tons  If conducted following periods of sand input from the tributaries, they don’t have to export more than was accumulated Adapted from Topping and others, 2010

Where is the sand? ~50 to 90% of the sand in Marble Canyon is stored in eddies. About 90% of the sand in eddies is stored below the stage elevation reached by a flow of 8,000 ft 3 /s (Hazel et al., 2006, J. Geophys. Res., 11).

Deposition dominates above 8,000 cfs level, often at expense of erosion below Demonstrates the difference between high- and low- elevation response “Response below 8,000 cfs” gainloss “Response above 8,000 cfs” lossgain Hazel and others (2010) 10

Conceptual model for interpretation of repeat channel mapping information “Channel and eddies below 8,000 cfs” gainloss “Sandbars above 8,000 cfs” lossgain Probably good news! Mining sand from storage Mining sand and losing sandbars Accumulating sand, not building bars - Could be having more floods! 11 Long-term monitoring designed to evaluate whether dam operations (including floods) result in declines in sand storage in the channel

12 Long-term monitoring designed to evaluate whether dam operations (including floods) result in declines in sand storage in the channel 2011 channel mapping trip (launching next Saturday) is collecting these data between the LCR and Phantom Ranch

May 2009 near RM 36  There is a lot of sand on the bed in some locations –Is the amount increasing or decreasing? –See Kaplinski talk this afternoon!

From Korman and Melis (2011) Discussed in High flow circular ch. 4 Most Significant Biological Response: More Trout

How do we determine when to have high flows?  USGS Sediment Flux Monitoring Program in Grand Canyon  Shifting rating curve sand routing model 15 Tracks tributary sediment inputs and mainstem transport at five locations to track status of the sediment “bank account.” Provides the information needed to time high flows for building sandbars to follow periods of sand accumulation.

How do we determine when to have high flows?  USGS Sediment Flux Monitoring Program in Grand Canyon  Shifting rating curve sand routing model 16 Tracks tributary sediment inputs and mainstem transport at five locations to track status of the sediment “bank account.” Provides the information needed to time high flows for building sandbars to follow periods of sand accumulation.

Sand budget from end of 2008 HFE to August 17, 2010 Preliminary results – subject to review and revision

Sand Input Triggering Strategy Suggests that HFEs follow Historical Timing of Paria and Little Colorado River Floods (Fall & Spring) From High Flow Circular Chapter 5, figure 5) Paria River Little Colorado River

Fall & Spring Timing Associated with Suggested Triggering Strategy has Historical Precedent in Pattern of Natural Floods during Pre-Dam Record From High Flow Circular Chapter 5, figure 6)

FREQUENCY OF HFE TRIGGERING?  The 85-year record of Paria River flow suggests that about 2/3 of HFEs are likely to be triggered in the Fall season – following sand inputs that occur from July into October  In some years, but rarely, Paria River floods have occurred in winter, but LCR flooding is more common in that season  Perhaps 1/3 of the HFEs triggered would occur in spring in response to LCR and/or Paria River sand inputs that occur between December and March  In some years HFEs might be triggered in both spring and fall

UNCERTAINTIES STILL REMAIN  It is unknown whether the suggested triggering option for long-term experimentation can rebuild & maintain sandbars at desired levels (desired conditions remain unclear)  Factors influencing rainbow trout response in the Lees Ferry tailwater reach are still poorly understood – tests of alternative timing are needed  Consistent long-term monitoring is critical for reducing the above uncertainties about future HFEs  HFEs are the only known means for rebuilding eroded sandbars - without sand-enriched high flows, sandbar size will decrease through time

? Pre-2008 HFE – RM 6 Post-2008 HFE – RM 6 Result of Delayed HFE Release in March 2008 following large Fall sand inputs in 2006 & 07? From Chapter 5, Wright and Kennedy, 2011

Monitoring for high flows What questions will we want to answer if there are repeated high flows over the next 10 years? 1.Will multiple high flows conducted over a period of several years result in net increases in sandbar area and volume? Addressed by monitoring sandbars above 8,000 cfs stage. Annual to every-other year monitoring of long-term sandbar monitoring sites. Systemwide monitoring every 4 years by remote sensing overflights. 2.With the available sand supply (i.e. tributary inputs) is the approach of using repeated floods to build sandbars sustainable? Addressed by repeat mapping of the channel bed by multibeam sonar (bathymetric remote sensing). 3.How will the aquatic food web and fish populations respond?

Acknowledgements 24 David Topping, USGS Joe Hazel, NAU Matt Kaplinski, NAU Jack Schmidt, USU Scott Wright, USGS Ted Kennedy, USGS Barbara Ralston, USGS Lara Schmit, NAU Ted Melis, USGS Josh Korman, Ecometric