Focus Group Meeting: September 27, 2013
Truckee River Water Quality Standards Review
Overview of Topics for Discussion• Feedback from previous workshop?• Review of flow regime development– Adjustment to 10th percentile flow regime
• Preliminary WQ results • Interpretation of Results– Integration of results over range of flows
• Preliminary climate change sensitivity runs• Next steps
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Feedback from Previous Workshop
Topics for Comment from August 2013 Focus Group Meeting• Approach for applying WARMF and TRHSPF to
evaluate potential changes to the Truckee River Nutrient Water Quality standards
• Approach for establishing a flow regime based on TROM Future No Action scenario
• Approach for analysis and interpretation of model results
• Any overarching concerns regarding the water quality standards review process?
Review of Flow Regime Development
Selection of Representative Flow Conditions
• Derived “target flows” based on TROM Future No Action output
• Two representative flow regimes selected to date– Low Flow (10th percentile) – Average Flow (50th percentile)
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1977 FNA Comparison of TROM, 10th percentile flows, and TRHSPF
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• Only adjusted summer period for lower river
ONLY Adjusted at TCID
Refining 10th Percentile Flow Regime Closer to Target• Preliminary runs performed with only minor
adjustment to 1977 FNA (at Derby Dam) • Working Group recommended further
adjustment for 1977 above Derby Dam• Final results with adjusted flows are
“in process”• Single test run completed– Biggest change in Reach 1
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1977 FNA Comparison of TROM, 10th percentile flows, and TRHSPF
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• Adjusted at WARMF-TRHSPF interface– July, August decreased flow– September increased flow
• Adjusted summer period for lower river
ONLY Adjusted at TCID
Adjusted at Sparks Jul - Sep Adjusted at TCID
Single Test Run with Adjusted 10th Percentile Low Flow
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Proceeding with running adjusted 10th percentile flow for full suite of constituent concentrations
Ortho-P TN
1985 FNA Comparison of TROM, 50th percentile flows, and TRHSPF
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• No additional adjustment
Preliminary Results of 10th Percentile Low Flow Condition
(Does not include adjusted flow regime)
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Set of Simulations Orthophosphate (mg/L)
Total
Nitrogen
(mg/L)
0.030 0.040 0.050
PLPT std0.075 0.100
0.55 x0.65 x0.75
NDEP/PLPT std x x x x x0.85 x1.00 x
Total Phosphorus (mg/L)
Total Nitrogen
(mg/L)
0.030 0.040 0.050
NDEP std0.075 0.100 0.125
0.55 x 0.65 x 0.75
NDEP/PLPT std x x x x x x0.85 x 1.00 x
Options for Calculating Percent Violation of DO WQS
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% of Hours: attainment is aggregation of all hours that have violated WQS
X hours violated 8760 hours/yr
% of Days: if 1+ hours violate WQS on a given day, that day is not in attainment
X days violated365 days/yr
Reviewing attainment as “% of days” is more
conservative approach
Spatial Aggregation for WQS Modeling
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Preliminary Results Total P10th Percentile Flow: Reach Averaged
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% of Days % of Hours
TN = 0.75 TN = 0.75
Preliminary Results Ortho-P10th Percentile Flow: Reach Averaged
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% of Days % of Hours
TN = 0.75 TN = 0.75
Preliminary Results Total Nitrogen10th Percentile Flow: Reach Averaged
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% of Days % of Hours
Preliminary Results: Longitudinal PlotsTN = 0.75 mg/L, OP = 0.05 mg/L
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Preliminary Results Total P50th Percentile Flow: Reach Averaged
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% of Days % of Hours
TN = 0.75 TN = 0.75
Preliminary Results Ortho P50th Percentile Flow: Reach Averaged
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% of Days % of Hours
TN = 0.75 TN = 0.75
Preliminary Results Total N50th Percentile Flow: Reach Averaged
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% of Days % of Hours
Preliminary Results: Longitudinal PlotsTN = 0.75 mg/L, OP = 0.05 mg/L
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Preliminary Observations• Reaches 1, 2, 3 show low level of DO violation• Reach 4 is most critical at 10th percentile flow – Sensitive to the phosphorus concentration– Not sensitive to the TN concentration – No violations for 50th percentile flows
• Need further investigation of Reach 4 response
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Integration of Results Over Full Flow Regime• Working Group discussed potential merit of running
a 90th percentile (high flow) regime • Could consider an “integration” of DO violations
across all flow regimes• Spreadsheet calculation based on preliminary results• 90th percentile year not simulated– Conservative assumption: high flow violations same as
average year
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Integration Over Flow Regimes: Compare Target Flows
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Comparison of 10th and 50th Flow Regime Results: Total P
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10th Percentile Flow 50th Percentile Flow
TN = 0.75 TN = 0.75
Preliminary Climate Change Scenario• Identified by Focus Group as important consideration for
sensitivity analysis• Focus only on temperature increase
– Given highly managed system, reservoir management could override climate change influences in upper watershed
– Climate models predict wide variation in precipitation changes• General approach for sensitivity runs
– Only adjust TRHSPF air temperature inputs – air water exchange– Apply a 1° F air temperature increase across entire year– Present the results on a "per degree" basis– Although linear response not expected, reasonable first step
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Basis for 1° F Temperature Increase• USBR Truckee River Basin Study (2012-2014)
– Evaluate range of potential changes in water demands due growing population
– Compare demands to existing supply under potential future uncertainties, including climate change
• Will include use of climate model projections
29SOURCE: USBR, 2013. Truckee Basin Study, Technical Advisory Group Water Supply Workshop, June 24, 2013 http://www.usbr.gov/mp/TBStudy/
Approximate 1° F increase over 20 years
TP Climate Sensitivity Example: 10th Percentile Flow (TN 0.75 / TP 0.05)
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Geomorphology Considerations• Potential relationship between channel geometry and
most critical segments• Mapped selected parameters for each model
segment– Reach slope– Water depth (summer average; 10th percentile year)– Water velocity (summer average; 10th percentile year)
• Developed an “indicator” of segment-specific diurnal swing– Calculated for two-segment average to account for
influence by the diurnal in the prior segment
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Justification for Indicator
• Violations are caused primarily by the magnitude of the diurnal swing• Diurnal swing at steady state directly proportional to:
gross plant productivity (g O2/m3/day) / [reaeration rate]
• Gross plant productivity = areal productivity (g O2/m2/day) / [water depth]
• Reaeration proportional to:[velocity * slope]
• Diurnal swing = areal productivity / [depth * velocity * slope]
•With similar periphyton productivity across segments, [depth * velocity * slope] should be a good indicator of segment-specific diurnal
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Visually Determined “Bins” for Mapping Parameters
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Average Depth (Summer Mean)
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Vista (304)
Tracy (315)
Marble Bluff Dam (343)
Below Derby Dam (320)
Channel Slope
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Vista (304)
Tracy (315)
Marble Bluff Dam (343)
Below Derby Dam (320)
Average Velocity (Summer Mean)
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Vista (304)
Tracy (315)
Marble Bluff Dam (343)
Below Derby Dam (320)
Reach Geometry Index
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Vista (304)
Tracy (315)
Marble Bluff Dam (343)
Below Derby Dam (320)
Next Steps
• Focus Group comments / feedback:– Technical approach
• Finalization of WQS model runs/output interpretation– Finalize “adjusted” 10th percentile flow runs with all
constituent concentrations– Climate sensitivity simulations
• Development of Technical Rationale Report
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Upcoming Focus Group Workshops
• Early Nov, 2013 (TBD) *NEW DATE*– Final modeling results
• Jan 15, 2014 (W)– Technical Rationale document
• Additional Stakeholder / Focus Group meetings TBD in 2014
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