This project is supported by the NASA Interdisciplinary Science Program We are currently studying the role of estuarine processes in linking rivers and.

Slides:



Advertisements
Similar presentations
Geophysical Fluid Dynamics Laboratory Review June 30 - July 2, 2009 Geophysical Fluid Dynamics Laboratory Review June 30 - July 2, 2009.
Advertisements

U.S. Eastern Continental Shelf Carbon Budget: Modeling, Data Assimilation, and Analysis U.S. ECoS Science Team* ABSTRACT. The U.S. Eastern Continental.
The carbon budget for coastal waters of the eastern United States R. Najjar, M. Friedrichs, W.-J. Cai, D. Butman,K. Kroeger, W. M. Kemp, M. Herrmann, L.
How do geotechnical properties contribute to failures and resulting fluxes to the deep sea? Subsurface flows and impacts on chemical fluxes, geotechnics,
Carbon budget for the continental shelf of the Eastern United States R. Najjar, D. Butman, W.-J. Cai, M. Friedrichs, A. Mannino, P. Raymond, J. Salisbury,
Christopher W. Hunt, Doug Vandemark, Joseph Salisbury, Shawn Shellito Ocean Process Analysis Laboratory, University of New Hampshire *contact:
A biogeochemical model for the northwestern Atlantic continental shelf Katja Fennel & John Wilkin Thanks also to: Hernan Arrango, Julia Levin, Dale Haidvogel,
GOES-R 3 : Coastal CO 2 fluxes Pete Strutton, Burke Hales & Ricardo Letelier College of Oceanic and Atmospheric Sciences Oregon State University 1. The.
Temporal scales of coastal variability and land-ocean processes J. Salisbury, J. Campbell, D. Vandemark, A. Mahadevan, B. Jonsson, H. Xue, C. Hunt.
5-9 Oct 2009 Bergen Final CarboOcean Meeting 1 Continental Shelf Pump Revisited K.-K. Liu Inst. of Hydrological & Oceanic Sciences National Central University,
Effects of Climate Change on Marine Ecosystems David Mountain US CLIVAR Science Symposium 14 July 2008.
The Physical Modulation of Seasonal Hypoxia in Chesapeake Bay Malcolm Scully Outline: 1)Background and Motivation 2)Role of Physical Forcing 3)Simplified.
Relationship between Satellite-Derived Snow Cover and Snowmelt-Runoff Timing in the Wind River Range, Wyoming MODIS-derived snow cover measured on 30 April.
Biogeochemical Cycles: Integration Across the Land- Estuary-Continental Shelf-Ocean Continuum Sybil P. Seitzinger Rutgers University Institute of Marine.
Chemical Aspects of GLOBEC- China Programs and Potential to GLOBEC-IMBER Study in China Jing Zhang 1. State Key Laboratory of Estuarine and Coastal Research,
Spatial coherence of interannual variability in water properties on the U.S. northeast shelf David G. Mountain and Maureen H. Taylor Presented by: Yizhen.
Isaac (Ike) Irby 1, Marjorie Friedrichs 1, Yang Feng 1, Raleigh Hood 2, Jeremy Testa 2, Carl Friedrichs 1 1 Virginia Institute of Marine Science, The College.
Satellite observations of coastal pCO 2 and air-sea flux of carbon dioxide Presenter: Steven E. Lohrenz Department of Marine Science The University of.
Isaac (Ike) Irby 1, Marjorie Friedrichs 1, Yang Feng 1, Raleigh Hood 2, Jeremy Testa 2, Carl Friedrichs 1 1 Virginia Institute of Marine Science, The College.
INTEGRATION OF MODELING AND OBSERVING SYSTEMS BIO-PHYSICAL MODELING ATMOSPHERE-OCEAN INTERACTION DATA ASSIMILATION MODEL COUPLING AND ADAPTIVE GRIDS HURRICANE/SEVERE.
U.S. ECoS U.S. Eastern Continental Shelf Carbon Budget: Modeling, Data Assimilation, and Analysis A project of the NASA Earth System Enterprise Interdisciplinary.
U.S. ECoS U.S. Eastern Continental Shelf Carbon Budget: Modeling, Data Assimilation, and Analysis A project of the NASA Earth System Enterprise Interdisciplinary.
Continental Coastal Interactions: Integration of models across terrestrial, inland water, and coastal ocean ecosystems for diagnosis, attribution, and.
Dale haidvogel Nested Modeling Studies on the Northeast U.S. Continental Shelves Dale B. Haidvogel John Wilkin, Katja Fennel, Hernan.
History and Overview of the Coastal Carbon Synthesis activities Heather Benway (Ocean Carbon & Biogeochemistry Program) Gulf of Mexico Coastal Synthesis.
Iron and Biogeochemical Cycles
The Rutgers IMCS Ocean Modeling Group Established in 1990, the Ocean Modeling Group at Rutgers has as one of it foremost goals the development and interdisciplinary.
Joaquim I. Goes and Helga Gomes Bigelow Laboratory for Ocean Sciences Increasing productivity in the Arabian Sea linked to shrinking snow caps – How satellites.
Spatial and temporal patterns of CH 4 and N 2 O fluxes from North America as estimated by process-based ecosystem model Hanqin Tian, Xiaofeng Xu and other.
NCAR ECSA Workshop on Coastal ZonesJune 2004 Importance of study of coastal zones in the carbon cycle has been explicated by two major carbon science steering.
Dale Haidvogel, John Wilkin and Zhiren Wang Ocean Modeling Group Institute of Marine and Coastal Sciences (IMCS), Rutgers University, New Brunswick, NJ.
Interannual Time Scales: ENSO Decadal Time Scales: Basin Wide Variability (e.g. Pacific Decadal Oscillation, North Atlantic Oscillation) Longer Time Scales:
U.S. Eastern Continental Shelf Carbon Budget: Modeling, Data Assimilation, and Analysis U.S. ECoS Science Team* ABSTRACT. The U.S. Eastern Continental.
Optical Water Mass Classification for Interpretation of Coastal Carbon Flux Processes R.W. Gould, Jr. & R.A. Arnone Naval Research Laboratory, Code 7333,
U.S. ECoS U.S. Eastern Continental Shelf Carbon Budget: Modeling, Data Assimilation, and Analysis A project of the NASA Earth System Enterprise Interdisciplinary.
Working Group 3: What aspects of coastal ecosystems are significant globally? Coastal Zone Impacts on Global Biogeochemistry NCAR, June 2004 Contributed.
2006 OCRT Meeting, Providence Assessment of River Margin Air-Sea CO 2 Fluxes Steven E. Lohrenz, Wei-Jun Cai, Xiaogang Chen, Merritt Tuel, and Feizhou Chen.
Department of Environmental Earth System Science Stanford University
Impact of Watershed Characteristics on Surface Water Transport of Terrestrial Matter into Coastal Waters and the Resulting Optical Variability:An example.
Continental Coastal Interactions: Assessing carbon inventories and fluxes in watersheds, inland waters, and associated coastal margins: data sources and.
Factors contributing to variability in pCO 2 and omega in the coastal Gulf of Maine. J. Salisbury, D. Vandemark, C. Hunt, C. Sabine, S. Musielewicz and.
This project is supported by the NASA Interdisciplinary Science Program The Estuarine Hypoxia Component of the Coastal Ocean Modeling Testbed: Providing.
U.S. ECoS U.S. Eastern Continental Shelf Carbon Budget: Modeling, Data Assimilation, and Analysis A project of the NASA Earth System Enterprise Interdisciplinary.
V This project is supported by the NASA Interdisciplinary Science Program Map of the U.S. East Coast showing the Mid-Atlantic and South Atlantic Bights.
Goal: to understand carbon dynamics in montane forest regions by developing new methods for estimating carbon exchange at local to regional scales. Activities:
Marine Ecosystem Simulations in the Community Climate System Model
Primary production and the carbonate system in the Mediterranean Sea
Ocean Biological Modeling and Assimilation of Ocean Color Data Watson Gregg NASA/GSFC/Global Modeling and Assimilation Office Assimilation Objectives:
OEAS 604: Final Exam Tuesday, 8 December 8:30 – 11:30 pm Room 3200, Research Innovation Building I Exam is cumulative Questions similar to quizzes with.
U.S. Eastern Continental Shelf Carbon Budget: Modeling, Data Assimilation, and Analysis U.S. ECoS Science Team* ABSTRACT. We present results from the U.S.
Using Satellite Data and Fully Coupled Regional Hydrologic, Ecological and Atmospheric Models to Study Complex Coastal Environmental Processes Funded by.
Metrics and MODIS Diane Wickland December, Biology/Biogeochemistry/Ecosystems/Carbon Science Questions: How are global ecosystems changing? (Question.
Primary production & DOM OUTLINE: What makes the PP levels too low? 1- run Boundary conditions not seen (nudging time) - Phytoplankton parameter:
Carbon cycling and optics in the Gulf of Maine: Observations and Modeling Joe Salisbury Doug Vandemark Janet Campbell Fei Chai Huijie Xue Amala Mahatavan.
FIGURE 17.1 A simple nitrogen and water balance for ‘‘Dave the Sea Lion.’’ Both nitrogen and water flows are in units of grams per 40 days. See text for.
Ocean Carbon and Biogeochemistry Scoping Workshop on Terrestrial and Coastal Carbon Fluxes and Exchanges in the Gulf of Mexico May 6-8, 2008 St. Petersburg,
Incorporating Satellite Time-Series data into Modeling Watson Gregg NASA/GSFC/Global Modeling and Assimilation Office Topics: Models, Satellite, and In.
Ocean Sciences The oceans cover 3/4 of the Earth’s surface. They provide the thermal memory for the global climate system, and are a major reservoir of.
East (Atlantic) Coast breakout report Leader: Wei-Jun Cai Rapporteur: Kevin Kroeger ~10 people.
Sea Surface Temperature as a Trigger of Butterfish Migration: A Study of Fall Phenology Amelia Snow1, John Manderson2, Josh Kohut1, Laura Palamara1, Oscar.
An Integrated View of North American Biosphere Carbon Flux Inter-annual Variability: from satellite CO2 to phenology Junjie Liu1, Kevin Bowman1, Dave.
Reenvisioning the Ocean: The View from Space A RESPONSE
Yi Xu, Robert Chant, and Oscar Schofiled Coastal Ocean Observation Lab
Seasonal Evolution Of Dissolved Inorganic Carbon Along A Cross-shelf Transect In The Gulf Of Maine: The Influence Of Riverine Discharge. Joe Salisbury.
Coastal CO2 fluxes from satellite ocean color, SST and winds
SAB Chlorophyll Variability Local vs. Remote Forcing
Iron and Biogeochemical Cycles
Influence of land - ocean exchange on carbonate mineral saturation state Joe Salisbury, Mark Green, Doug Vandemark, Chris Hunt, Dwight Gledhill, Wade McGillis,
NASA Ocean Salinity Science Team Meeting , Santa Rosa, August 2018
Presentation transcript:

This project is supported by the NASA Interdisciplinary Science Program We are currently studying the role of estuarine processes in linking rivers and the coastal ocean. To date our efforts have been devoted towards improving our physical simulation of the Chesapeake Bay. The skill of the model is currently similar to that of other hydrodynamic models currently being used in the Bay (Fig. 3 above). We are now working towards embedding our NENA- DOM biogeochemical model (Fig. 1) in our Bay simulation. This model will be evaluated with in situ and satellite data (Fig 4, right) data in the Bay. We are currently studying the role of estuarine processes in linking rivers and the coastal ocean. To date our efforts have been devoted towards improving our physical simulation of the Chesapeake Bay. The skill of the model is currently similar to that of other hydrodynamic models currently being used in the Bay (Fig. 3 above). We are now working towards embedding our NENA- DOM biogeochemical model (Fig. 1) in our Bay simulation. This model will be evaluated with in situ and satellite data (Fig 4, right) data in the Bay. The U.S. Eastern Continental Shelf Carbon Cycling Project: U.S. ECoS Marjorie Friedrichs, Eileen Hofmann, Cathy Feng, Kimberly Hyde, Cindy Lee, Marjorie Friedrichs 1, Eileen Hofmann 2, Cathy Feng 1, Kimberly Hyde 3, Cindy Lee 4, Antonio Mannino, Ray Najjar, Sergio Signorini, Hanqin Tian, John Wilkin, Yongjin Xiao, Jianhong Xue Antonio Mannino 5, Ray Najjar 6, Sergio Signorini 5, Hanqin Tian 7, John Wilkin 8, Yongjin Xiao 1, Jianhong Xue 1 1 VIMS, College of William & Mary; 2 CCPO, Old Dominion University; 3 NOAA/NMFS Narragansett Laboratory; 4 MSRC, Stony Brook University; 5 NASA Goddard Space Flight Center; 6 Pennsylvania State University; 7 SFWS, Auburn University; 8 IMCS, Rutgers University USECoS PROJECT OVERVIEW Although the oceans play a major role in the uptake of fossil fuel CO 2 from the atmosphere, there is much debate about the contribution from continental shelves, because many key shelf fluxes are not yet well quantified: the exchange of carbon across the land-ocean and shelf-slope interfaces, air- sea exchange of CO 2, burial, and biological processes including productivity. Because of the undersampling typically associated with most observational studies, model- derived carbon flux estimates are likely to be the only viable approach for defining these fluxes in a consistent manner on annual time scales. The goal of the USECoS (U.S. Eastern Continental Shelf Carbon Cycling) project is (1) to quantify these coastal carbon fluxes in this region using models quantitatively evaluated by comparisons with observations, and (2) to establish a framework for predicting how these fluxes may be modified as a result of climate and land use change. SATELLITE DATA ASSIMILATION SIMULATED CARBON FLUXES The coupled ocean biogeochemical circulation model is now being used to compute and monitor carbon fluxes along the U.S. eastern continental shelf. Seasonal, interannual and spatial variability in the carbon budget is considerable (Fig. 8). Initial results indicate that presently this region acts as a sink of atmospheric CO 2 of roughly 8.5 TgC/year (Fig. 9). Offshore transport of POC and DOC are each roughly 10 times greater than burial on the shelf. OCEAN BIOGEOCHEMICAL CIRCULATION MODEL Schematic of the biogeochemical model that is incorporated into the Regional Ocean Modeling System (ROMS). The model is based on Fennel et al. (2008, GRL) and Druon et al. (2010). As described in Hofmann et al. (2008, 2011) the model has been modified using field studies, historical data, measurements from satellites, and one-dimensional data assimilative modeling. (For more information on the data assimilative modeling, please see poster by Y. Xiao). Dynamic Land Ecosystem Model (DLEM) simulations suggest that total carbon (TC, including DOC, POC and DIC) of about 6.9 ± 0.6 TgC yr -1 (1 Tg = g) has been exported to the Mid Atlantic Bight (MAB), Georges Bank (GB), and Gulf of Mexico coastal margins. Exported TOC increased by 11% from the 1950s to The export of total nitrogen (TN) to MAB has significant inter-annual and decadal fluctuations in the past hundred years as estimated by DLEM, which is mainly caused by increasing fertilization and nitrogen deposition. DLEM also provides information about the spatial and temporal patterns of carbon leaching from land to river networks (Fig. 2). DYNAMIC LAND ECOSYSTEM MODEL Our ocean biogeochemical circulation model is being evaluated with multiple remote-sensing products. In addition to standard products such as SST, chl and PP, we have also developed regional algorithms for species specific chlorophyll, DOC, POC and pCO 2. Using a one-dimensional framework, satellite data are also being assimilated into the biogeochemical model in order to improve the model parameterizations and select the optimal level of complexity required to constrain the carbon cycle along the U.S. eastern continental shelf. (See Xiao poster.) Our ocean biogeochemical circulation model is being evaluated with multiple remote-sensing products. In addition to standard products such as SST, chl and PP, we have also developed regional algorithms for species specific chlorophyll, DOC, POC and pCO 2. Using a one-dimensional framework, satellite data are also being assimilated into the biogeochemical model in order to improve the model parameterizations and select the optimal level of complexity required to constrain the carbon cycle along the U.S. eastern continental shelf. (See Xiao poster.) IMPACTS OF CLIMATE AND LAND USE CHANGE The sensitivity of biogeochemical cycling to changes in river discharge is examined through simulations that double and halve freshwater and nutrients individually and simultaneously. Results indicate that doubling freshwater input increases air-sea CO 2 flux but has no effect on PP. On the contrary, increases in nutrient discharge increase both air-sea CO 2 flux and PP. In general, increases in DIC riverine input results in more offshelf flux of DIC. Fig. 5: Summer anomalies of primary productivity (PP) and air-sea CO2 flux [units of gC/m2/y] generated by doubling nutrients (Nx2) and freshwater (FWx2). Fig. 6: Preliminary results for percent of total chlorophyll made up by (a) diatoms, (b) dinoflagellates and (c) picoplankton, as determined from regional species-specific algorithm (Pan et al., 2011). Fig. 7: Percent small phytoplankton (dark green), microplankton (light green) and diatoms (yellow), with total chlorophyll (blue line, axis on right) superimposed. Top panel shows satellite data, middle panel is the pre-assimilation simulation and bottom panel is the post- assimilation simulation. (a)(c)(b) This work has been supported by the NASA Ocean Biology and Biogeochemistry Program, with funding from Interdisciplinary Science, Carbon Cycle Science and the Carbon Monitoring System programs. References: Druon et al., Modeling the dynamics and export of dissolved organic matter in the northeastern U.S. continental shelf. Estuarine, Coastal and Shelf Science, 88, Fennel et al., Denitrification effects on air-sea CO2 flux in the coastal ocean: Simulations for the northwest North Atlantic, GRL, 35, L Hofmann et al., Eastern U.S. continental shelf carbon budget: integrating models, data assimilation, and analysis. Oceanog., 21(1), Hofmann et al., Modeling the dynamics of continental shelf carbon. Annual Review of Marine Science, 3, Pan et al., Remote sensing of phytoplankton community composition along the northeast coast of the United States. Remote Sensing of Environment, in press. Fig. 8: Four year time-series of the rates of carbon input to the GOM, the MAB, the SAB and total (GOM+MAB+SAB; note different scale in this case) via burial (black), air-sea CO 2 flux (magenta), and the horizontal divergence fluxes of POC (blue) and DOC (green). Net community production (NCP) is also shown (light blue.) Bottom Salinity (psu) Unbiased RMSD Bias Fig. 3: Above right: Bottom salinity simulation for ChesNENA. Above left: Target diagram illustrating model skill for bottom salinity at 40 Chesapeake Bay Program Monitoring Stations. Symbols color-coded by bottom salinity color bar. Fig. 4, Below: Surface chlorophyll in Chesapeake Bay on July 6, 2011, as derived from MODIS-Aqua data using the OC3 chl-a algorithm. This image was acquired 5 days prior to the GEO-CAPE Chesapeake cruise, and thus cruise data will be available shortly to validate these surface chlorophyll concentrations. LAND-OCEAN COUPLING Fig. 9: NENA model budgets averaged over the time period for total carbon (left), inorganic carbon (middle) and organic carbon (right) for coastal waters of the eastern U.S. “Hor Adv + Diff” represents the cross-shelf flux. Fig. 2 : DLEM-estimated changes of DOC (left), DIC (center), and POC (right) and leaching in watersheds draining to the U.S. east coast. Fig. 1 : Biogeochemical model schematic.