A GLOBAL PERSPECTIVE ON THE LINKAGE BETWEEN EUTROPHICATION AND HYPOXIA Robert Diaz College of William and Mary Virginia Institute of Marine Science

Slides:

Advertisements

Similar presentations

Chesapeake Bay Environmental Model Package A coupled system of watershed, hydrodynamic and eutrophication models The same package used for the 2002 load.

Advertisements

Hypoxia: Problems and Scientific Challenges Hypoxia: Problems and Scientific Challenges Prof. Rudolf Wu School of Biological Sciences The University of.

Ecological Systems Maintaining and Enhancing Natural Features and Minimizing Adverse Impacts of Infrastructure Projects Course Review.

Economics of Nitrogen and Water Quality Anthony Dvarskas Stony Brook University May 19,

1 Europe’s water – an indicator-based assessment Niels Thyssen.

Eutrophication of the Black Sea

US GLOBEC Before and After

OMSAP Public Meeting September 1999 The Utility of the Bays Eutrophication Model in the Harbor Outfall Monitoring Program James Fitzpatrick HydroQual,

Nitrogen and Ecosystem Nutrient Cycling Nicole and Sarah Biogeochemistry of Northern Ecosystems March 2005.

Nutrient Cycles Eutrophication Nitrogen –Chemical Forms in the Aquatic Environment –Chemical Transformations –Cycle f-ratio Carbon.

How does excessive nitrogen loading effect the health and resiliency of Long Island’s coastal ecosystems? Christopher J. Gobler.

Food webs and trophic cascades in lakes. How to represent trophic relationships? (Paine 1980) 1.Connectedness Based on observations 2.Energy flow web.

Estuaries and Fish Ecology Tim Essington School of Aquatic and Fishery Sciences.

Carbon Cycle and Ecosystems Important Concerns: Potential greenhouse warming (CO 2, CH 4 ) and ecosystem interactions with climate Carbon management (e.g.,

Stream Ecology (NR 280) Chapter 1 – Introduction to Fluvial Systems Basic Concepts.

Ecology Biomes and Ecosystems. 2 Ecosystems- Matter and Energy.

NCCOS Centers Center for Coastal Monitoring and Assessment, Silver Spring, MD CCEHBR - Cooperative Oxford Laboratory Branch, Oxford, MD Center for Sponsored.

Eutrophication of coastal systems 1.Our evolving conceptual model of the coastal eutrophication problem; James E.Cloern; Submerged aquatic vegetation.

The Importance of Coastal Waters - Recent Reports National Coastal Condition Report National Coastal Condition Report Heinz Center’s State of the Nation’s.

NCCOS Centers Center for Coastal Monitoring and Assessment, Silver Spring, MD CCEHBR - Cooperative Oxford Laboratory Branch, Oxford, MD Center for Sponsored.

Hypoxia. Nutrient Enrichment has two main effects 1.Hypoxia 2.Change of community structure.

Integrated Ecosystem Assessment for the Gulf of Mexico Becky Allee Gulf Coast Services Center.

Food Webs in the Ocean Andrew W Trites Marine Mammal Research Unit University of British Columbia Who eats whom and how much?

Ecosystem processes and heterogeneity Landscape Ecology.

All about “Dead Zones”. Zones of Oxygen Depletion.

The Physical Modulation of Seasonal Hypoxia in Chesapeake Bay Malcolm Scully Outline: 1)Background and Motivation 2)Role of Physical Forcing 3)Simplified.

Examining Human Impacts on Global Biogeochemical Cycling via the Coastal Zone & Ocean Margins L. Talaue-McManus Rosenstiel School of Marine & Atmospheric.

Types of Water Pollution Sewage Disease-causing agents Sediment pollution Inorganic plant and algal nutrients Organic compounds Inorganic chemicals Thermal.

Estuary Productivity & Complexity Evaluating Human Impacts.

Adam M. Davis Center for Geospatial Data Analysis Indiana University, Bloomington, IN Studying geological controls on succession in an old field: Progress.

KATLYND REESE AQUATIC ECOLOGY 9 NOVEMBER 2011 Hypoxia or “Dead Zones” in Aquatic Systems.

Currents of Change Workshop Currents of Change Environmental Status & Trends of the Narragansett Bay Region May 1, 2009.

Extended Council Context for the NMN Design Management Questions Objectives Environments Resources of Primary Concern Stressors affecting resources Core.

Secondary Production of Infaunal Benthic Communities in Chesapeake Bay in Comparison to Restored Oyster Reefs Amanda Lawless and Dr. Rochelle Seitz Virginia.

Coastal development impacts on biological communities in the Chesapeake Bay Examples from the Atlantic Slope Consortium R

Or Export of Secondary Production in Ecosystems.

Freshwater Pollution Tuesday 2/4/2014. Warm-up  Define a point and nonpoint source of pollution.  Label if the below examples are point or nonpoint.

Draft Report Breakout Session III-5 Ecosystem Consequences of Climate Change Ecosystem Impacts & Feedbacks Effects on Biodiversity, Invasions, Protected.

Estuaries 101 A Brief Introduction to Natural and Human-Induced Processes in Estuaries Jonathan Pennock University of New Hampshire Marine Program, NH.

Hypoxia Management tools: indicators & models Bob Wood John Jacobs Heath Kelsey Xinsheng Zhang Cooperative Oxford Lab

Objectives: 1.Enhance the data archive for these estuaries with remotely sensed and time-series information 2.Exploit detailed knowledge of ecosystem structure.

Impacts of hypoxia on key benthic infauna and their predators in Chesapeake Bay Rochelle D. Seitz & W. Chris Long Virginia Institute of Marine Science,

Assessing Linkages between Nearshore Habitat and Estuarine Fish Communities in the Chesapeake Bay Donna Marie Bilkovic*, Carl H. Hershner, Kirk J. Havens,

Why Does NOAA Need a Climate & Ecosystem Demonstration Project in the California Current System? Capabilities and Drivers La Jolla, CA 6 June, 2005.

Ecosystem Based Modeling for Sustainable Regional Development of the Marine and Estuarine Resources in Coastal NSW Philip Gibbs Karen Astles.

Application of the ASSETS eutrophication assessment methodology to four contrasting Chinese coastal systems ASLO Summer Meeting 2005, Santiago de Compostela.

Pg. 82 RTW: Break apart the word “biogeochemical”. What definition can you make for biogeochemical cycle? Objective: I will be able to diagram and explain.

Gulf of Mexico Hypoxia and Nutrient Management in the Mississippi River Basin Herb Buxton, U.S. Geological Survey.

This project is supported by the NASA Interdisciplinary Science Program The Estuarine Hypoxia Component of the Coastal Ocean Modeling Testbed: Providing.

Great Lakes Environmental Research Laboratory Review – Ann Arbor, MI November 15-19, Click to edit Master text styles –Second level Third level.

Indirect effects of coastal hypoxia on planktivore habitat: implications for pelagic food webs and fisheries Stuart Ludsin, Stephen Brandt & Doran Mason.

Food Systems in the Coastal Zone: A LOICZ Perspective L. Talaue-McManus Rosenstiel School of Marine & Atmospheric Science University of Miami.

Changes in the Global Nitrogen Cycle: Causes and Consequences Taken largely from Human Alteration of the Global Nitrogen Cycle:Causes and Consequences.

NOAA Chesapeake Bay Office Fisheries Ecosystem Modeling Efforts Howard Townsend, Hongguang Ma, and Maddy Sigrist NOAA Chesapeake Bay Office National Ecosystem.

Ch. 1: “Watersheds and Wetlands” Lesson 1.5: “Factors That Affect Wetlands and Watersheds” Part 2.

Oceans. Why is the Ocean Salty? 1. The ocean is salty because of dissolved chemicals eroded from the Earth's crust and washed into the sea. 2. Ejections.

Aquatic Biodiversity G. Tyler Miller’s Living in the Environment 14 th Edition Chapter 7 G. Tyler Miller’s Living in the Environment 14 th Edition Chapter.

Or Export of Secondary Production in Ecosystems.

Eutrophication, Hypoxia, and Ocean Acidification Puget Sound Oceanography 2011.

Metrics and MODIS Diane Wickland December, Biology/Biogeochemistry/Ecosystems/Carbon Science Questions: How are global ecosystems changing? (Question.

Ecology Chesapeake Bay Ecosystem Issue: Submerged Aquatic Vegetation.

Nitrogen loading from forested catchments Marie Korppoo VEMALA catchment meeting, 25/09/2012 Marie Korppoo, Markus Huttunen 12/02/2015 Open DATA: Nutrient.

Hypoxia Forecasts as a Tool for Chesapeake Bay Fisheries

Concept of Ecosystem Carrying Capacity for Marine Ecosystem Management

Global Nitrogen Cycle, Eutrophication, and Coastal Hypoxia: State of Knowledge and Management Robert J Díaz

Regime Shifts and Leading Indicators

EFFECT OF ALGAL BLOOM ON FRESHWATER ECOSYSTEMS

Environmental Systems

US Environmental Protection Agency

Laura Boicenco National Institute for Marine Research and Development

Presentation transcript:

A GLOBAL PERSPECTIVE ON THE LINKAGE BETWEEN EUTROPHICATION AND HYPOXIA Robert Diaz College of William and Mary Virginia Institute of Marine Science

Outline Global picture on development of anthroprogenic low dissolved oxygen. Consequences low dissolved oxygen to ecosystems.

Production Benthic/ Pelagic Energy Flow HypoxiaGeochem. Predator/ Prey Nutrient Cycling Yield (1) Filter (2) Multiple Stressors (3) Coastal Ecosystem Responses Social and Economic Costs Human Health Costs Other Impacts Climate System Impetus to Build Science-Based (5) Tools (4) Impacts on the Earth System Rehabilitation/Restoration Actions Nutrient Enrichment Climate Change Fishing Harvest Toxic Contaminants Exotic Species Aquaculture Hydrologic Manipulations How Nutrient Enrichment and Other Stressors are Connected: Cloern 2001, Marine Ecology Progress Series

Bottom Line: Seriousness of low Dissolved Oxygen best expressed by old motto of American Lung Association: “When You Can’t Breathe, Nothing Else Matters.”

How Eutrophication/Hypoxia Became A Global Problem The increasing input of nutrients to coastal areas over the last 50 years resulted in system overload. Strong correlation through time between: –population growth. –increased nutrient discharges –increased primary production –increased occurrence of hypoxia and anoxia. N N   People  Standard of Living  Agriculture & Industry Boesch 2002, Estuaries

Eutrophication/Hypoxia Now a Global Problem: Reviewed literature for eutrophication related hypoxia (+700 articles) About 200 sites found. Listed contributing factors: Rising level of nutrients Blooms Discharge of organic matter Hydrological changes

Eutrophication/Hypoxia Now a Global Problem: Decade for First Report of Hypoxia Doubling of sites first reporting hypoxia started in 1960s. OMZ and Upwelling areas not included.

Eutrophication/Hypoxia is now a Global Problem: Tokyo Bay (Kodama et al. 2002) Time Fisheries & WQ <1930  Mid 30s  Late 40s  Early 70s 

Nutrients are one of many human related factor in development of oxygen depletion. For marine systems Nitrogen is primary problem. Current knowledge restricted by lack of scientific investigation. Li and Daler ,000 km 2 Annual Hypoxia

The Size of the Problem

Eutrophication/Hypoxia Consequences to Benthos  Eutrophication increases organic Carbon:  Increases secondary production  Favors opportunistic species  Hypoxia becomes a key factor in regulating energy flow:  Forcing ecosystem to pulse through Mortality  Favors opportunistic species Diaz&Rosenberg 1995

Interaction of Eutrophication/Hypoxia and Energy Example from Chesapeake Bay Benthic Monitoring Program Random Sampling in MD and VA Summer Sampling from 1996 to 2004 Assumptions: DO measured at time of sampling is representative of station’s annual condition. Daily production estimated from individual species AFDW and Edgar (1990). Productivity provides an index of community processes proportional to total community respiration and consumption.

Interaction of Eutrophication/Hypoxia and Energy Daily production was related to DO.

Interaction of Eutrophication/Hypoxia and Energy On an annual, Bay wide basis hypoxia reduces secondary production by: Annual, Bay wide secondary production (Diaz and Schaffner 1990): 17 g C/m 2 /year or mt C for entire Bay (11,427 km 2 ) Hypoxia interferes with 1 to 5 % of total production. Hypoxia creates a separation between pelagic and benthic systems. Questions: Is the Bay really 1 to 5 % less productive of benthos? Is this level of production shifted to normoxic period? Is this energy required for this production shifted to microbes?

Interaction of Eutrophication/Hypoxia and Energy

Interaction between Benthic Production, Dissolved Oxygen, and degree of Eutrophication:

Global Summary l Up to the 1950s, reports of mass mortality of marine animals caused by lack of oxygen were limited to small systems that had histories of oxygen stress. l 1960s the number of systems with reports of hypoxia related problems increased. Start of decadal doubling for first reports. l 1970s many large systems report hypoxia. l 1980s with increased awareness more reports of hypoxia. l 1990s most estuarine and marine systems in close proximity to population centers report oxygen depletion. First report of coastal upwelling hypoxia being worsened by additional nutrients. l 2000s will doubling continue?

Global Summary l Low dissolved oxygen has potential to be driver for regime shift. l 1990s some improvement in hypoxia was observed in large systems: l Black Sea, Gulf of Finland l Improvement seen in some systems from nutrient regulation: l Hudson River, Delaware River, East River l Mersey Estuary, Elbe Estuary, Idefjord l No improvement in some systems with nutrient regulation: l Chesapeake Bay, Lake Erie, Tokyo Bay

Ecosystem response to Eutrophication/Hypoxia l Increased organic matter leads to increase biomass, but Hypoxia/Anoxia tend to reduce biomass. l Opportunistic species favored, lower species diversity, and increased importance of microbes. l Response to hypoxia related to: l Concentration of dissolved oxygen l Duration Nestlerode&Diaz 1998