Difference between revisions of "WATER QUALITY"

From Glen Canyon Dam AMP
Jump to: navigation, search
Line 89: Line 89:
 
*[http://www.tandfonline.com/doi/abs/10.1080/07438141.2011.632705 Wildman and Hering. 2011. Potential for release of sediment phosphorus to Lake Powell (Utah and Arizona) due to sediment resuspension during low water level. Lake and Reservoir Management, 27:4, 365-375]
 
*[http://www.tandfonline.com/doi/abs/10.1080/07438141.2011.632705 Wildman and Hering. 2011. Potential for release of sediment phosphorus to Lake Powell (Utah and Arizona) due to sediment resuspension during low water level. Lake and Reservoir Management, 27:4, 365-375]
 
'''USGS Data Series, Circulars, and other Reports'''
 
'''USGS Data Series, Circulars, and other Reports'''
 
+
*[http://gcdamp.com/images_gcdamp_com/2/26/GCDAMP_FY_2017_Knowledge_Assessment-Science_Advisor_Program_Final_Report_2017-04-30.pdf GCDAMP FY 2017 Knowledge Assessment: Final Report from the Executive Coordinator for the Science Advisors Program]
 +
*[https://www.usbr.gov/uc/rm/amp/twg/mtgs/14apr08/TWP_14jun06.pdf?bcsi_scan_cf0ea36431a6106e=xBHF7QVHXt6Zx5nJZ4cG0wktr3sHAAAA6aC3BQ==&bcsi_scan_filename=TWP_14jun06.pdf Glen Canyon Dam Adaptive Management Program Triennial Budget and Work Plan— Fiscal Years 2018–2020]
 +
*[https://pubs.usgs.gov/of/2008/1153/ USGS Workshop on Scientific Aspects of a Long-Term Experimental Plan for Glen Canyon Dam, April 10–11, 2007, Flagstaff, Arizona]
 +
*[[Media:Jones 2001 Final report PEP GCMRC IWQP.pdf| Final report of the Protocol Evaluation Panel for the Grand Canyon Monitoring and Research Center Integrated Water Quality Program (IWQP)]]
 +
*[https://pubs.usgs.gov/ds/471/pdf/ds471.pdf Historical Physical and Chemical Data for Water in Lake Powell and from Glen Canyon Dam Releases, Utah-Arizona, 1964–2013]
 +
*[https://pubs.usgs.gov/circ/1282/ The State of the Colorado River Ecosystem in Grand Canyon: A report of the Grand Canyon Monitoring and Research Center 1991-2004]
 +
*[https://pubs.er.usgs.gov/publication/ds959 Biological Data for Water in Lake Powell and from Glen Canyon Dam Releases, Utah and Arizona, 1990–2009]
 +
'''Water Quality and Glen Canyon Dam Management'''
 +
*[http://onlinelibrary.wiley.com/doi/10.1890/1051-0761(2001)011%5B0644:EFEOTL%5D2.0.CO;2/full Hueftle and Stevens. 2001. Experimental flood effects on the limnology of Lake Powell Reservoir, Southwestern USA. Ecological Applications, 11(3), pp. 644–656]
 +
*[https://pubs.usgs.gov/of/2010/1159/ Effects of the 2008 High-Flow Experiment on Water Quality in Lake Powell and Glen Canyon Dam Releases, Utah-Arizona]
 +
'''Water Quality and Metabolism in the Colorado River below Glen Canyon Dam'''
 +
*[http://azmemory.azlibrary.gov/cdm/ref/collection/statepubs/id/3854 Water quality investigation of seventeen Grand Canyon tributaries: July 2004 - May 2005]
 +
*[https://pubs.er.usgs.gov/publication/70154774 Hall et al. 2015. Turbidity, light, temperature, and hydropeaking control primary productivity in the Colorado River, Grand Canyon. Limnol. Oceanogr. 60, 512–526]
 +
*[http://onlinelibrary.wiley.com/doi/10.1215/21573689-1572535/full Hall et al. 2012. Air–water oxygen exchange in a large whitewater river. Limnology and Oceanography: Fluids and Environments]
 +
*[http://onlinelibrary.wiley.com/doi/10.4319/lo.2004.49.6.1992/full Larned et al. 2004. Mass-transfer–limited nitrogen and phosphorus uptake by stream periphyton: A conceptual model and experimental evidence. Limnol. Oceanogr., 49(6), 1992–2000]
 +
*[https://pubs.er.usgs.gov/publication/70192253 Payn et al. 2017. A coupled metabolic-hydraulic model and calibration scheme for estimating whole-river metabolism during dynamic flow conditions. Limnol. Oceanogr.]
  
 
|}
 
|}

Revision as of 11:31, 31 October 2017


ForebayWaterQuality.jpg

Desired Future Condition for Water Quality

Water quality with regards to dissolved oxygen, nutrient concentrations and cycling, turbidity, temperature, etc., is sufficient to support natural ecosystem functions, visitor safety and visitor experience to the extent feasible and consistent with the life history requirements of focal aquatic species.
• Ecosystem-sustaining nutrient distribution, flux, and cycling.
• Hydro-physical conditions and characteristics of the CRE necessary to sustain aquatic biota.
• Acceptable water quality for human health and visitor experience.

---
---
---

Updates

2017 Water Quality PEP

Reading List

Adaptive Management

Calcite Coprecipitation

CE-QUAL Modeling

Contaminants

General Lake Powell Limnology

Long-term Water Quality Trends

P Biogeochemistry

USGS Data Series, Circulars, and other Reports

Water Quality and Glen Canyon Dam Management

Water Quality and Metabolism in the Colorado River below Glen Canyon Dam


Water Quality Gages

Papers and presentations

2017

2016

2015

2014

2012

2010

2006

2005

Modifying releases at Glen Canyon Dam to improve water quality in the Lees Ferry reach

Rough operation of the turbines

Increases the oxygenation of water going through the power plant Is damaging to the turbines

Oxygenation of the tailwater using the bypass tubes

The Basin States have maintained that according to Sec 602a of the Colorado River Basin Project Act (1968), the bypass tubes at Glen Canyon Dam can only be used to avoid anticipated spills from Lake Powell. The Basin States have agreed to bypass at Glen Canyon Dam for HFEs on the condition that it be done as part of an experiment and not a management action or operational decision. Costs associated with any release that bypasses the powerplant for reasons other than to avoid a spill or for experimentation relating to HFEs would have to be borne by the GCDAMP (see DOI determination for costs of the 2004 BHBF).

Adding power generation to the bypass tubes

Allows for drawing water from deeper in Lake Powell: colder and water may be more oxygenated

Other methods:

  • Forebay diffusers
  • Side Stream Super-Saturation
  • Aeration
  • Turbine Venting
  • Surface Water Pumps (impellers)

(Mobley Engineering: Hydropower Enhancement Technologies)

Other Stuff