Grand Canyon Monitoring and Research Projects Active
River Geomorphology and Geomorphic Change
Sandbar and sediment storage monitoring and research
The Grand Canyon Monitoring and Research Center currently functions under a Triennial Work Plan (TWP) which is thoroughly reviewed and vetted both internally within the Center and through the GCDAMP Technical Work Group (TWG) and the Adaptive Management Work Group (AMWG). These advisory panels have been a part of the Glen Canyon Dam adaptive management process since the inception of the GCDAMP. For more information on the adaptive management process, please see the GCDAMP Page.
Physical Resources
GCMRC has on-going monitoring and research focused on river sediment dynamics, long-term monitoring of sediment resources in the Colorado River corridor, and understanding the connectivity of sand resources throughout the system.
Biological Resources
Several GCMRC projects focus on understanding the biological processes of the Colorado River, the effect of dam operations on both native and nonnative species, population dynamics of important species, and the terrestrial-biological interactions.
Socio-Economic and Cultural
GCMRC is also concerned with understanding the socio-economic values of the Colorado River in Grand Canyon, the unique recreational opportunites this environment offers and the cultural significance observed by the Tribal people of this the region.
Administrative History and Guidance That Informs GCMRC Projects
GCMRC'S work plan and science projects align with the needs of the GCDAMP stakeholders. Each project described is organized around monitoring and research themes that are associated with the eleven resource goals identified in the LTEMP ROD: archaeological and cultural resources, natural processes, humpback chub, hydropower and energy, other native fish, recreational experience, sediment, tribal resources, rainbow trout fishery, nonnative invasive species, and riparian vegetation (U.S. Department of the Interior, 2016a; Attachment A).
The monitoring and research projects are responsive to guidance provided in the LTEMP ROD, which, in addition to identifying the priority resources, also identifies flow and non-flow experimental actions and compliance obligations for Glen Canyon Dam operations for the 20 years of the LTEMP. Additional guidance comes from the Science Plan developed by GCMRC (VanderKooi and others, 2017) in support of the LTEMP ROD which describes a general strategy for monitoring and research needed in support of implementation of operations and experimental actions.
Projects in the current TWP have been informed by and build upon previous research and monitoring projects that were responsive to guidance vetted through the GCDAMP and the Secretary of Interior’s office. While the LTEMP ROD defines broad resource goals and identifies new experimental actions and compliance requirements, some of the older guidance continues to have relevance for certain aspects of the current science program and continues to influence current research and monitoring directions in a general sense. Among this older guidance, the following documents describe the history of GCDAMP decisions and direction and help maintain continuity with GCDAMP goals as LTEMP is implemented:
- 2001 Glen Canyon Dam Adaptive Management Program draft strategic plan (Glen Canyon Dam Adaptive Management Program, 2001),
- 2007 Strategic Science Plan and Strategic Science Questions (SSQs) (U. S. Geological Survey, 2007),
- 2011 draft Core Monitoring Plan (U. S. Geological Survey, 2011), and
- 2012 AMWG Desired Future Conditions.
Monitoring and research themes described in these and other GCDAMP administrative documents have persisted throughout the life of the GCDAMP and are carried forward into the LTEMP. They include:
(1) recovery of the endangered humpback chub (Gila cypha) and maintenance of populations of other native fish;
(2) maintenance or improvement of the physical template, especially regarding fine sediment;
(3) maintenance of culturally important sites, especially those that are of archaeological and historical significance under the National Historic Preservation Act
(4) maintenance of the food base on which the native fish community depends;
(5) maintenance of a high-quality sport fishery in the Lees Ferry reach; and
(6) maintenance of the native riparian vegetation community.
The various goals, questions, information needs, and desired future conditions developed by GCDAMP committees also recognize the importance of maintaining high quality opportunities and conditions for recreational boaters and campers, and the role played by nonnative riparian vegetation in providing habitat for some desired fauna such as the endangered Southwestern willow flycatcher.
Below are science projects associated with GCMRC work plans.
Below are data associated with GCMRC-specific projects.
These data will be updated soon - in progress.
Below are publications associated with research and projects by the Grand Canyon Monitoring and Research Center (GCMRC). Note that not all of the publications listed here are funded under the Glen Canyon Dam Adaptive Management Program (GCDAMP).
To access all of SBSC's publications, click the link below.
Historical floods and geomorphic change in the lower Little Colorado River during the late 19th to early 21st centuries
Strandlines from large floods on the Colorado River in Grand Canyon National Park, Arizona
Incorporating antenna detections into abundance estimates of fish
Spatiotemporal methane emission from global reservoirs
Hydropeaking intensity and dam proximity limit aquatic invertebrate diversity in the Colorado River Basin
Assessing the population impacts and cost‐effectiveness of a conservation translocation
A morphodynamic model to evaluate long-term sandbar rebuilding using controlled floods in the Grand Canyon
Riverine complexity and life history inform restoration in riparian environments in the southwestern U.S.
Half of global methane emissions come from highly variable aquatic ecosystem sources
The transformation of dryland rivers: The future of introduced tamarisk in the U.S.
Drivers of methane flux differ between lakes and reservoirs, complicating global upscaling efforts
Monitoring Tamarix changes using WorldView-2 satellite imagery in Grand Canyon National Park, Arizona
Below are news items about GCMRC's science.
- Overview
The Grand Canyon Monitoring and Research Center currently functions under a Triennial Work Plan (TWP) which is thoroughly reviewed and vetted both internally within the Center and through the GCDAMP Technical Work Group (TWG) and the Adaptive Management Work Group (AMWG). These advisory panels have been a part of the Glen Canyon Dam adaptive management process since the inception of the GCDAMP. For more information on the adaptive management process, please see the GCDAMP Page.
Physical ResourcesGCMRC has on-going monitoring and research focused on river sediment dynamics, long-term monitoring of sediment resources in the Colorado River corridor, and understanding the connectivity of sand resources throughout the system.
Biological ResourcesSeveral GCMRC projects focus on understanding the biological processes of the Colorado River, the effect of dam operations on both native and nonnative species, population dynamics of important species, and the terrestrial-biological interactions.
Socio-Economic and CulturalGCMRC is also concerned with understanding the socio-economic values of the Colorado River in Grand Canyon, the unique recreational opportunites this environment offers and the cultural significance observed by the Tribal people of this the region.
Administrative History and Guidance That Informs GCMRC Projects
GCMRC'S work plan and science projects align with the needs of the GCDAMP stakeholders. Each project described is organized around monitoring and research themes that are associated with the eleven resource goals identified in the LTEMP ROD: archaeological and cultural resources, natural processes, humpback chub, hydropower and energy, other native fish, recreational experience, sediment, tribal resources, rainbow trout fishery, nonnative invasive species, and riparian vegetation (U.S. Department of the Interior, 2016a; Attachment A).
The monitoring and research projects are responsive to guidance provided in the LTEMP ROD, which, in addition to identifying the priority resources, also identifies flow and non-flow experimental actions and compliance obligations for Glen Canyon Dam operations for the 20 years of the LTEMP. Additional guidance comes from the Science Plan developed by GCMRC (VanderKooi and others, 2017) in support of the LTEMP ROD which describes a general strategy for monitoring and research needed in support of implementation of operations and experimental actions.
Projects in the current TWP have been informed by and build upon previous research and monitoring projects that were responsive to guidance vetted through the GCDAMP and the Secretary of Interior’s office. While the LTEMP ROD defines broad resource goals and identifies new experimental actions and compliance requirements, some of the older guidance continues to have relevance for certain aspects of the current science program and continues to influence current research and monitoring directions in a general sense. Among this older guidance, the following documents describe the history of GCDAMP decisions and direction and help maintain continuity with GCDAMP goals as LTEMP is implemented:
- 2001 Glen Canyon Dam Adaptive Management Program draft strategic plan (Glen Canyon Dam Adaptive Management Program, 2001),
- 2007 Strategic Science Plan and Strategic Science Questions (SSQs) (U. S. Geological Survey, 2007),
- 2011 draft Core Monitoring Plan (U. S. Geological Survey, 2011), and
- 2012 AMWG Desired Future Conditions.
Monitoring and research themes described in these and other GCDAMP administrative documents have persisted throughout the life of the GCDAMP and are carried forward into the LTEMP. They include:
(1) recovery of the endangered humpback chub (Gila cypha) and maintenance of populations of other native fish;
(2) maintenance or improvement of the physical template, especially regarding fine sediment;
(3) maintenance of culturally important sites, especially those that are of archaeological and historical significance under the National Historic Preservation Act
(4) maintenance of the food base on which the native fish community depends;
(5) maintenance of a high-quality sport fishery in the Lees Ferry reach; and
(6) maintenance of the native riparian vegetation community.
The various goals, questions, information needs, and desired future conditions developed by GCDAMP committees also recognize the importance of maintaining high quality opportunities and conditions for recreational boaters and campers, and the role played by nonnative riparian vegetation in providing habitat for some desired fauna such as the endangered Southwestern willow flycatcher.
- Science
Below are science projects associated with GCMRC work plans.
Filter Total Items: 24 - Data
Below are data associated with GCMRC-specific projects.
These data will be updated soon - in progress.
- Multimedia
- Publications
Below are publications associated with research and projects by the Grand Canyon Monitoring and Research Center (GCMRC). Note that not all of the publications listed here are funded under the Glen Canyon Dam Adaptive Management Program (GCDAMP).
To access all of SBSC's publications, click the link below.
Filter Total Items: 313Historical floods and geomorphic change in the lower Little Colorado River during the late 19th to early 21st centuries
The Little Colorado River is a major tributary to the Colorado River with a confluence at the boundary between Marble and Grand Canyons within Grand Canyon National Park, Arizona. The bedrock gorge of the lower Little Colorado River is home to the largest known population of Gila cypha (humpback chub), an endangered fish endemic to the Colorado River Basin. Channel conditions might affect the spawAuthorsJoel A. Unema, David J. Topping, Keith Kohl, Michael J. Pillow, Joshua J. CasterStrandlines from large floods on the Colorado River in Grand Canyon National Park, Arizona
Strandlines of peak-stage indicators (such as driftwood logs, woody debris, and trash) provide valuable data for understanding the maximum stage and extent of inundation during floods. A series of seven strandlines have been preserved along the Colorado River in Grand Canyon National Park, Arizona, USA. A survey and analysis of these strandlines was completed from the Colorado River at Lees Ferry,AuthorsThomas A. Sabol, Ronald E. Griffiths, David J. Topping, Erich R. Mueller, Robert B. Tusso, Joseph E. HazelIncorporating antenna detections into abundance estimates of fish
Autonomous passive integrated transponder (PIT) tag antennas are commonly used to detect fish marked with PIT tags but cannot detect unmarked fish, creating challenges for abundance estimation. Here we describe an approach to estimate abundance from paired physical capture and antenna detection data in closed and open mark-recapture models. Additionally, for open models, we develop an approach thaAuthorsMaria C. Dzul, Charles Yackulic, William L. Kendall, Dana L. Winkelman, Mary M Conner, Mike YardSpatiotemporal methane emission from global reservoirs
Inland aquatic systems, such as reservoirs, contribute substantially to global methane (CH4) emissions; yet are among the most uncertain components of the total CH4 budget. Reservoirs have received recent attention as they may generate high CH4 fluxes. Improved quantification of these CH4 fluxes, particularly their spatiotemporal distribution, is key to realistically incorporating them in CH4 modeAuthorsMatthew S Johnson, E Matthews, D Bastviken, Bridget Deemer, Jinyang Du, V GenoveseHydropeaking intensity and dam proximity limit aquatic invertebrate diversity in the Colorado River Basin
River biodiversity is threatened globally by hydropower dams, and there is a need to understand how dam management favors certain species while filtering out others. We examined aquatic invertebrate communities within the tailwaters 0–24 km downstream of seven large hydropower dams in the Colorado River Basin of the western United States. We quantified aquatic invertebrate dominance, richness, abuAuthorsErin Abernathy, Jeffrey Muehlbauer, Theodore Kennedy, Jonathan D. Tonkin, Richard Van Driesche, David A. LytleAssessing the population impacts and cost‐effectiveness of a conservation translocation
Managers often move, or translocate, organisms into habitats that are assumed to be suitable, however the consequences of these translocations are usually not rigorously assessed. Robust assessment of these management experiments should consider impacts to both donor and recipient populations and compare the cost‐effectiveness of translocations to other actions.Here we evaluate translocations of aAuthorsCharles B. Yackulic, David R. Van Haverbeke, Maria C. Dzul, Lucas S. Bair, Kirk L. YoungA morphodynamic model to evaluate long-term sandbar rebuilding using controlled floods in the Grand Canyon
Controlled floods released from dams have become a common restoration strategy in river systems worldwide. Here we present a morphodynamic model of sandbar volume change for a subset of sandbars of the Colorado River in Grand Canyon National Park, where controlled floods are part of a management strategy focused on sandbar maintenance. We simulate sandbars as a triangular wedge, where deposition aAuthorsErich R. Mueller, Paul GramsRiverine complexity and life history inform restoration in riparian environments in the southwestern U.S.
Riparian habitat in the southwestern USA has undergone substantial degradation over the past century, prompting extensive management and restoration of these critical ecosystems. Most restoration efforts, however, do not account for life history traits or riverine complexity that may influence genetic diversity and structure. Here, we use simple sequence repeat (SSR) markers in four southwestern rAuthorsEmily C. Palmquist, Gerald J Allan, Kiona Ogle, Thomas G. Whitham, Bradley J. Butterfield, Patrick B. ShafrothHalf of global methane emissions come from highly variable aquatic ecosystem sources
Atmospheric methane is a potent greenhouse gas that plays a major role in controlling the Earth’s climate. The causes of the renewed increase of methane concentration since 2007 are uncertain given the multiple sources and complex biogeochemistry. Here, we present a metadata analysis of methane fluxes from all major natural, impacted and human-made aquatic ecosystems. Our revised bottom-up globalAuthorsJudith A. Rosentreter, Alberto V. Borges, Bridget Deemer, Meredith A. Holgerson, Shaoda Liu, Chunlin Song, John M. Melack, Peter A. Raymond, Carlos M. Duarte, George H. Allen, David Olefeldt, Benjamin Poulter, Tom I. Batin, Bradley D. EyreThe transformation of dryland rivers: The future of introduced tamarisk in the U.S.
Tamarix spp. (tamarisk or saltcedar), a shrub-like tree, was intentionally introduced to the U.S. from Asia in the mid-1800s. Tamarisk thrives in today’s human-altered streamside (riparian) habitats and can be found along wetlands, rivers, lakes, and streams across the western U.S. In 2001, a biological control agent, Diorhabda spp. (tamarisk leaf beetle), was released in six states, and has sinceAuthorsPamela L. Nagler, Julia B. Hull, Charles van Riper, Patrick B. Shafroth, Charles B. YackulicDrivers of methane flux differ between lakes and reservoirs, complicating global upscaling efforts
Methane is an important greenhouse gas with growing atmospheric concentrations. Freshwater lakes and reservoirs contribute substantially to atmospheric methane concentrations, but the magnitude of this contribution is poorly constrained. Uncertainty stems partially from whether the sites currently sampled represent the global population as well as incomplete knowledge of which environmental variabAuthorsBridget Deemer, Meredith A. HolgersonMonitoring Tamarix changes using WorldView-2 satellite imagery in Grand Canyon National Park, Arizona
Remote sensing methods are commonly used to monitor the invasive riparian shrub tamarisk (Tamarix spp.) and its response to the northern tamarisk beetle (D. carinulata), a specialized herbivore introduced as a biocontrol agent to control tamarisk in the Southwest USA in 2001. We use a Spectral Angle Mapper (SAM) supervised classification method with WorldView-2 (2 m spatial resolution) multispectrAuthorsNathaniel D. Bransky, Temuulen T. Sankey, Joel B. Sankey, Matthew D. Johnson, Levi R. Jamison - Web Tools
- News
Below are news items about GCMRC's science.
Filter Total Items: 14