Presentation is loading. Please wait.

Presentation is loading. Please wait.

Design Workgroup Jeffrey L. ArmstrongOrange County Sanitation Distric Tyler BakerTVA Jerad BalesUSGS David BayneAuburn University Joe BoyerFlorida International.

Published byLoren Sanders Modified over 8 years ago

Similar presentations

Presentation on theme: "Design Workgroup Jeffrey L. ArmstrongOrange County Sanitation Distric Tyler BakerTVA Jerad BalesUSGS David BayneAuburn University Joe BoyerFlorida International."— Presentation transcript:

1 Design Workgroup Jeffrey L. ArmstrongOrange County Sanitation Distric Tyler BakerTVA Jerad BalesUSGS David BayneAuburn University Joe BoyerFlorida International University Charles DvorskyTexas Don DycusTennessee Valley Authority Art GarceauIndiana George HarmanMaryland Mike Hemsley Ocean.US Steven R. Johnston Galveston Bay Estuary Program Steve JordanEPA Ron KleinAlaska Chris KnoppU.S. Forest Service

2 Design Workgroup Alfred Korndoerfer, Jr.New Jersey Gail MallardFED-U.S. Geological Survey Thomas C. MaloneIOOS Dan McKenzieEPA Brian D. Melzian, Ph.D.EPA Tony OlsenEPA Steven G. Paulsen, Ph.D.EPA Robert P. SchreiberASCE Gene Lynn SiskAlabama GeneTurner & Eric SwensonLouisiana State University Robert WardColorado State University Dave Whitall, Ph.D.NOAA

3 Management Issues Oxygen depletion Nutrient enrichment Toxic contamination Sedimentation Harmful algal blooms Habitat degradation Invasions by exotic species Status of coastal habitats Sources and quantities of marine debris Coral communities

4 Components of These Issues Defined in some (often tacit) conceptual model Sources Causes Primary Effects Secondary Effects Issue

5 Example: Excess Nutrients Harmful Algal Blooms conceptual model Sources Causes: Excess Nutrients Primary Effects HABs Elevated Temperatures Secondary Effects: A.Benthic Mortalities B.Fish Kills C.Human Health Effects Excess Nutrients

6 Exclusive Economic Zones

7 National Estuary Programs

8 NERR: small blue in Delaware Bay

9 NCA Estuary and Marine

10 NPS: Assateague Island (pink)

11 HUC Regions

12 HUC Subregions (4-digit): coastal

13 HUC 6-digit: coastal

14 HUC 8-digit: Gulf Coast

15 HUC 8-digit: rivers in one

16 Matrix Coverage Exclusive Economic Zone Estuaries Ocean- State & Territorial Rivers –Level 1 –Level 2 –Level 3 –Level 4

17 ResourceParameterFrequencySpatial Density Vertical resolutionComments Estuaries Water temp.ContinuousDefine longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible Fixed buoys or platfroms. Spatial gradients measured using monthly discrete data at dense sampling grid compared to fixed stations which define the backbone gradient DOContinuous with probe? There are calibratuion issues Define longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible Fixed buoys or platfroms. Spatial gradients measured using monthly discrete data at dense sampling grid compared to fixed stations which define the backbone gradient TurbidityContinuous with fluorescence probe? There are calibratuion issues Define longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible Fixed buoys or platfroms. Satellite sensors (calibration issues). Spatial gradients measured using monthly discrete data at dense sampling grid compared to fixed stations which define the backbone gradient NutrientsMonthly at first to establish seasonal patterns Define longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible

18 NATIONAL MONITORING NETWORK DESIGN MATRIX E. M. Swenson 4/8/2005 ResourceParameterFrequencySpatial Density Vertical resolutionComments Estuaries Water temp.ContinuousDefine longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible Fixed buoys or platfroms. Spatial gradients measured using monthly discrete data at dense sampling grid compared to fixed stations which define the backbone gradient SalinityContinuousDefine longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible Fixed buoys or platfroms. Spatial gradients measured using monthly discrete data at dense sampling grid compared to fixed stations which define the backbone gradient DOContinuous with probe? There are calibratuion issues Define longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible Fixed buoys or platfroms. Spatial gradients measured using monthly discrete data at dense sampling grid compared to fixed stations which define the backbone gradient

19 ResourceParameterFrequencySpatial Density Vertical resolutionComments Contaminants Define longitudinal and transverse gradients Benthos Define longitudinal and transverse gradients Probabilistic Chlorophyll aContinuous with probe? There are calibratuion issues Define longitudinal and transverse gradients Surface, mid- depth, bottom. May only need short term checks for vertical startification then change to single depth if possible Fixed buoys or platfroms. Satellite sensors (calibration issues). Spatial gradients measured using monthly discrete data at dense sampling grid compared to fixed stations which define the backbone gradient Phytoplankton Zooplankton

20 ResourceParameterFrequencySpatial Density Vertical resolutionComments Shellfish Target harvest areas Fish community Pathogens Recreational areas Invasive species CurrentsContinuousDefine longitudinal and transverse gradients, major flow routes Upward looking ADCP or side looking ADCP in channels Fixed buoys or platfroms. Water levelContinuous Fixed buoys or platforms. Met station, winds, precipitation, pressure, PAR ContinuousFill in gaps in existing networks. Provide better data for model boundary conditions Fixed buoys or platfroms.

Download ppt "Design Workgroup Jeffrey L. ArmstrongOrange County Sanitation Distric Tyler BakerTVA Jerad BalesUSGS David BayneAuburn University Joe BoyerFlorida International."

Similar presentations

Water-Quality Measurements in San Francisco Bay – a component of ~ 40,000 measurements per year.

Water-Quality Measurements in San Francisco Bay – a component of ~ 40,000 measurements per year.
Information Needs for the Integrated F&W Program (ESA and Power Act) Jim Geiselman - BPA.

Information Needs for the Integrated F&W Program (ESA and Power Act) Jim Geiselman - BPA.
Massachusetts Water Resources Authority Proposed Revisions to MWRA’s Ambient Monitoring Plan: Introduction Andrea Rex Director Environmental Quality Dept.

Massachusetts Water Resources Authority Proposed Revisions to MWRA’s Ambient Monitoring Plan: Introduction Andrea Rex Director Environmental Quality Dept.
Nutrient Cycles Eutrophication Nitrogen –Chemical Forms in the Aquatic Environment –Chemical Transformations –Cycle f-ratio Carbon.

Nutrient Cycles Eutrophication Nitrogen –Chemical Forms in the Aquatic Environment –Chemical Transformations –Cycle f-ratio Carbon.
Compare and Contrast What are some ways in which life in an aphotic zone might differ from life in a photic zone Apply Concepts What is a wetland and.

Compare and Contrast What are some ways in which life in an aphotic zone might differ from life in a photic zone Apply Concepts What is a wetland and.
Aquatic Biodiversity Chapter 8. Core Case Study: Why Should We Care about Coral Reefs? (1)  Biodiversity  Formation  Important ecological and economic.

Aquatic Biodiversity Chapter 8. Core Case Study: Why Should We Care about Coral Reefs? (1)  Biodiversity  Formation  Important ecological and economic.
Aquatic Ecosystems Monday, August 22nd Reminder: HW3 Part II due Wednesday! Midterm Thursday.

Aquatic Ecosystems Monday, August 22nd Reminder: HW3 Part II due Wednesday! Midterm Thursday.
Spatial and temporal trends in dissolved oxygen concentrations and dissolved oxygen depletion (hypoxia) in the Delaware River Basin Demonstration Area.

Spatial and temporal trends in dissolved oxygen concentrations and dissolved oxygen depletion (hypoxia) in the Delaware River Basin Demonstration Area.
Population/Economic Growth and the Marine Environment Daniel Huppert School of Marine Affairs University of Washington.

Population/Economic Growth and the Marine Environment Daniel Huppert School of Marine Affairs University of Washington.
Chesapeake Bay Program Presented by: Elizabeth Mills, Heather Plumridge, Elizabeth Repko Possibilities, Problems, and Promise.

Chesapeake Bay Program Presented by: Elizabeth Mills, Heather Plumridge, Elizabeth Repko Possibilities, Problems, and Promise.
IOOS Application to Harmful Algal Blooms and Ecosystem Health Monitoring Josh Kohut Rutgers University, Institute of Marine & Coastal Science Bob Connell.

IOOS Application to Harmful Algal Blooms and Ecosystem Health Monitoring Josh Kohut Rutgers University, Institute of Marine & Coastal Science Bob Connell.
1 Issue: Society Depends on Ecosystem Modeling to Predict Threats and Minimize Risk.

1 Issue: Society Depends on Ecosystem Modeling to Predict Threats and Minimize Risk.
The Importance of Coastal Waters - Recent Reports National Coastal Condition Report National Coastal Condition Report Heinz Center’s State of the Nation’s.

The Importance of Coastal Waters - Recent Reports National Coastal Condition Report National Coastal Condition Report Heinz Center’s State of the Nation’s.
Use of Remote Sensing for Routine Coastal Water Monitoring by a State Agency Bob Connell New Jersey Department of Environmental Protection Bureau of Marine.

Use of Remote Sensing for Routine Coastal Water Monitoring by a State Agency Bob Connell New Jersey Department of Environmental Protection Bureau of Marine.
Aquatic Ecosystems Determining factors:

Aquatic Ecosystems Determining factors:
AQUATIC BIODIVERSITY IMPACTS 13.1 & 12.3. How much do we know? We have explored about 5% of the earth’s global ocean and the world’s interconnected oceans.

AQUATIC BIODIVERSITY IMPACTS 13.1 & How much do we know? We have explored about 5% of the earth’s global ocean and the world’s interconnected oceans.
Biomes Biotic & Abiotic Factors Terrestrial Biomes Aquatic Biomes Biotic & Abiotic Factors Terrestrial Biomes Aquatic Biomes.

Biomes Biotic & Abiotic Factors Terrestrial Biomes Aquatic Biomes Biotic & Abiotic Factors Terrestrial Biomes Aquatic Biomes.
Aquatic Biodiversity Ocean 91% of all water Polar ice caps and glaciers 2.3% Lakes, streams, and rivers 2.8% Rest largely groundwater.

Aquatic Biodiversity Ocean 91% of all water Polar ice caps and glaciers 2.3% Lakes, streams, and rivers 2.8% Rest largely groundwater.
Coastal Water Quality Remote Sensing Welcome Dr. Jeff Payne Deputy Director NOAA Coastal Services Center October 7, 2003.

Coastal Water Quality Remote Sensing Welcome Dr. Jeff Payne Deputy Director NOAA Coastal Services Center October 7, 2003.
Water for Virginia Master Naturalists: Estuaries & Coasts.

Water for Virginia Master Naturalists: Estuaries & Coasts.

Similar presentations

Ads by Google