AOMIP WORKSHOP Ian Fenty Patrick Heimbach Carl Wunsch.

Slides:

Advertisements

Similar presentations

Basics of numerical oceanic and coupled modelling Antonio Navarra Istituto Nazionale di Geofisica e Vulcanologia Italy Simon Mason Scripps Institution.

Advertisements

Experiments with Monthly Satellite Ocean Color Fields in a NCEP Operational Ocean Forecast System PI: Eric Bayler, NESDIS/STAR Co-I: David Behringer, NWS/NCEP/EMC/GCWMB.

Michael Steele Polar Science Center / APL University of Washington Oct 3, 2007 SASS Mtg, Alexandria, VA Collaborative Research: A Heat Budget Analysis.

1 Evaluation of two global HYCOM 1/12º hindcasts in the Mediterranean Sea Cedric Sommen 1 In collaboration with Alexandra Bozec 2 and Eric Chassignet 2.

“Estimates of (steric) SSH rise from ocean syntheses" Detlef Stammer Universität Hamburg  SODA (J. Carton)  AWI roWE (J. Schroeter, M. Wenzel)  ECCO.

Indirect Determination of Surface Heat Fluxes in the Northern Adriatic Sea via the Heat Budget R. P. Signell, A. Russo, J. W. Book, S. Carniel, J. Chiggiato,

Ocean Heat Uptake Gregory C. Johnson 1,2, John M. Lyman 3,1, & Sarah G. Purkey 2,1 1 NOAA/Pacific Marine Environmental Laboratory, 2 University of Washington.

2005 ROMS Users Meeting Monday, October 24, 2005 Coupled sea-ice/ocean numerical simulations of the Bering Sea for the period 1996-present Enrique Curchitser.

The Global Ocean Data Assimilation System (GODAS) at NCEP

Ocean Reanalysis D. Stammer. Continued development of ocean synthesis products and reanalysis; some now are truly global, including sea.

Xingren Wu and Robert Grumbine

Ensemble-variational sea ice data assimilation Anna Shlyaeva, Mark Buehner, Alain Caya, Data Assimilation and Satellite Meteorology Research Jean-Francois.

Applications and Limitations of Satellite Data Professor Ming-Dah Chou January 3, 2005 Department of Atmospheric Sciences National Taiwan University.

1.Introduction 2.Description of model 3.Experimental design 4.Ocean ciruculation on an aquaplanet represented in the model depth latitude depth latitude.

Collaborative Research: Toward reanalysis of the Arctic Climate System—sea ice and ocean reconstruction with data assimilation Synthesis of Arctic System.

Ocean Data Variational Assimilation with OPA: Ongoing developments with OPAVAR and implementation plan for NEMOVAR Sophie RICCI, Anthony Weaver, Nicolas.

Ocean and sea-ice data assimilation and forecasting in the TOPAZ system L. Bertino, K.A. Lisæter, I. Kegouche, S. Sandven NERSC, Bergen, Norway Arctic.

IGST Meeting June 2-4, 2008 The GMAO’s Ocean Data Assimilation & SI Forecasts Michele Rienecker, Christian Keppenne, Robin Kovach Jossy Jacob, Jelena Marshak.

Inter-annual to decadal climate prediction Mojib Latif, Leibniz Institute of Marine Sciences at Kiel University.

CCSM Simulations w/CORE Forcing Some preliminary results and a discussion of dataset issues Marika Holland With much input from Bill Large Steve Yeager.

Dataset Development within the Surface Processes Group David I. Berry and Elizabeth C. Kent.

ASTE (former NOSE): An Arctic subpolar gyre State Estimate (NSF-funded) Patrick Heimbach, An T. Nguyen, Ayan Chaudhuri, Gael Forget, Rui M. Ponte, and.

Imposed versus Dynamically Modeled Sea Ice: A ROMS study of the effects on polynyas and waters masses in the Ross Sea John M. Klinck, Y. Sinan Hüsrevoglu.

Developments within FOAM Adrian Hines, Dave Storkey, Rosa Barciela, John Stark, Matt Martin IGST, 16 Nov 2005.

Southern Ocean Surface Measurements and the Upper Ocean Heat Balance Janet Sprintall Sarah Gille Shenfu Dong Scripps Institution of Oceanography, UCSD.

Regional Air-Sea Interactions in Eastern Pacific 6th International RSM Workshop Palisades, New York July 11-15, th International RSM Workshop Palisades,

The I nverse R egional O cean M odeling S ystem Development and Application to Variational Data Assimilation of Coastal Mesoscale Eddies. Di Lorenzo, E.

Research Needs for Decadal to Centennial Climate Prediction: From observations to modelling Julia Slingo, Met Office, Exeter, UK & V. Ramaswamy. GFDL,

Chris Hill, Boulder, May ECCO and associated projects :: Arctic System Model interests.

Cooling and Enhanced Sea Ice Production in the Ross Sea Josefino C. Comiso, NASA/GSFC, Code The Antarctic sea cover has been increasing at 2.0% per.

© Crown copyright Met Office The EN4 dataset of quality controlled ocean temperature and salinity profiles and monthly objective analyses Simon Good.

An Arctic Ocean/Sea Ice Reanalysis Detlef Stammer, Nikolay Koldunov, Armin Köhl Center für Erdsystemforschung und Nachhaltigkeit Universität Hamburg page.

Summary of January 2007 ECCO2 meeting Overview and Motivation ECCO, ECCO-GODAE, ECCO2 (Wunsch, MIT) The only way to understand the complete, global,

Evapotranspiration Estimates over Canada based on Observed, GR2 and NARR forcings Korolevich, V., Fernandes, R., Wang, S., Simic, A., Gong, F. Natural.

Experience with ROMS for Downscaling IPCC Climate Models 2008 ROMS/TOMS European Workshop, Grenoble, 6-8 October Bjørn Ådlandsvik, Paul Budgell, Vidar.

Ocean Surface heat fluxes Lisan Yu and Robert Weller

The passive microwave sea ice products…. ….oh well…

Examining the relationships between low-frequency upper ocean temperature and AMOC variability in ECCO v4 solutions Martha W. Buckley and Rui Ponte (AER)

Ocean Surface heat fluxes

AOMIP status Experiments 1. Season Cycle 2. Coordinated - Spinup Coordinated - Analysis Coordinated 100-Year Run.

A Brief Introduction to CRU, GHCN, NCEP2, CAM3.5 Yi-Chih Huang.

Assimilation of Sea Ice Concentration Observations in a Coupled Ocean-Sea Ice Model using the Adjoint Method.

The I nverse R egional O cean M odeling S ystem Development and Application to Variational Data Assimilation of Coastal Mesoscale Eddies. Di Lorenzo, E.

Infrared and Microwave Remote Sensing of Sea Surface Temperature Gary A. Wick NOAA Environmental Technology Laboratory January 14, 2004.

SeaWiFS Views Equatorial Pacific Waves Gene Feldman NASA Goddard Space Flight Center, Lab. For Hydrospheric Processes, This.

Adjoint modeling in cryosphere Patrick Heimbach MIT/EAPS, Cambridge, MA, USA

Validation of ORCA05 regional configuration of the Arctic North Atlantic Christophe HERBAUT and Marie-Noëlle HOUSSAIS Charles DELTEL LOCEAN, Université.

Verfasser/in Webadresse, oder sonstige Referenz GECCO ACTIVITIES (Armin Köhl, Nuno Sera, Nikolay Kuldenov) GECCO-2: Global (including Arctic), extension.

Quantifying the Mechanisms Governing Interannual Variability in Air-sea CO 2 Flux S. Doney & Ivan Lima (WHOI), K. Lindsay & N. Mahowald (NCAR), K. Moore.

Michael J. McPhaden, NOAA/PMEL Dongxiao Zhang, University of Washington and NOAA/PMEL Circulation Changes Linked to ENSO- like Pacific Decadal Variability.

The effect of tides on the hydrophysical fields in the NEMO-shelf Arctic Ocean model. Maria Luneva National Oceanography Centre, Liverpool 2011 AOMIP meeting.

GHRSST HL_TAG meeting Copenhagen, March 2010 Validation of L2P products in the Arctic Motivation: Consistent inter-satellite validation of L2p SST observations.

Progress and Assessment of the Arctic subpolar gyre State Estimate (ASTE) An T. Nguyen, Patrick Heimbach, Ayan Chaudhuri, Gael Forget, Rui M. Ponte, and.

Incorporating Satellite Time-Series data into Modeling Watson Gregg NASA/GSFC/Global Modeling and Assimilation Office Topics: Models, Satellite, and In.

Seasonal Variations of MOC in the South Atlantic from Observations and Numerical Models Shenfu Dong CIMAS, University of Miami, and NOAA/AOML Coauthors:

Towards the utilization of GHRSST data for improving estimates of the global ocean circulation Dimitris Menemenlis 1, Hong Zhang 1, Gael Forget 2, Patrick.

In order to accurately estimate polar air/sea fluxes, sea ice drift and then ocean circulation, global ocean models should make use of ice edge, sea ice.

Climate System Research Center, Geosciences Alan Condron Peter Winsor, Chris Hill and Dimitris Menemenlis Changes in the Arctic freshwater budget in response.

Michael Steele Polar Science Center / APL University of Washington Jan 14, 2009 AOMIP WHOI Mechanisms of Upper Ocean Warming in the Arctic and the Effect.

An T. Nguyen University of Texas, Austin

The Emergence of Surface-Based Arctic Amplification

A Brief Introduction to CRU, GHCN, NCEP2, CAM3.5

Recent Climate Change Modeling Results

Mark A. Bourassa and Qi Shi

Measuring Arctic amplification R. Davy, L. Chen, E. Hanna, and I. Esau

Recent Climate Change Modeling Results

Workshop 1: GFDL (Princeton), June 1-2, 2006

Y. Xue1, C. Wen1, X. Yang2 , D. Behringer1, A. Kumar1,

Joint Proposal to WGOMD for a community ocean model experiment

NASA Jet Propulsion Laboratory, California Institute of Technology

Presentation transcript:

AOMIP WORKSHOP Ian Fenty Patrick Heimbach Carl Wunsch

Claims Adjustments to initial and boundary conditions (within known uncertainties) can bring a coupled sea ice-ocean model into consistency with observations ▫“Probably all models are different and wrong” By modifying the sea ice cover these adjustments significantly affect air-sea fluxes Using the adjoint method to synthesize model and observations can reveal systematic errors and biases with both

Claim 1 Adjustments to initial and boundary conditions within known uncertainties can bring a coupled sea ice-ocean model into consistency with observations

JFM Sea ice area anomaly relative to 1978-present mean

Yashayaev 2007 LS heat content trends In last decade the upper 2000 m has an increasing temperature trend Related to lack of deep convection since mid 1990’s Interesting, but this is compiled from AR7w ctd lines, most of which is far from sea ice edge Are similar upper ocean heating trends found in the region of high sea ice variability?

Obs Model Model-Obs

ECCO project Estimation of Climate and Circulation of Ocean 1x1 degree Best possible estimate of ocean state from 1992-Present ▫Began with availability of TOPEX/Poseidon ▫Satellite and in situ observations of all sorts Estimate made by adjusting only initial and boundary conditions ▫Problem of finding ideal initial and boundary conditions which minimizes variance weighted misfit between model trajectory and observations ▫“Physically consistent” Adjustments found using sensitivities derived from adjoint method. Constrained to 80N-S No Sea Ice Observations

Labrador Sea Ice State Estimation Setup Datasets: ▫XBT, ARGO, CTD, The Levitus-Goureski Climatology ▫NCEP reanalysis ▫ECCO initial and boundary conditions (IT199) ▫Sea Ice Concentrations from Nimbus-7 SMMR and DMSP SSM/I (BOOTSTRAP algorithm) ▫Reynolds Daily 0.25 degree SST Uncertainties ▫In situ using representation method of Forget and Wunsch (2007) ▫NCEP gleaned from various sources where estimates have been made ▫Sea ice gleaned from various sources, higher for lower concentrations State Estimation Controls ▫Initial T,S ▫Time varying open boundary U,V,T,S ▫Atmospheric: T, q, U, radiation

Model configuration MITgcm ocean-sea ice model and its automatically derived adjoint SEA ICE MODEL 2 layer dynamic-thermodynamic ice + snow Hibler’s VP Dynamics Ice-Ocean coupling :Hibler + Bryan (1987) OCEAN MODEL Curvilinear grid: ~ 30 km 2 23 vertical levels 1 hour time step One year runs August-August Open boundaries supplied from ECCO global state estimate 9

In situ Observations

Uncertainties for NCEP Atmospheric Terms Kolstad (2008) Hunke and Holland (2007) Makshtas (2007) Bromwich and Wang (2005) Serreze (2005) Renfrew (2002) Ladd and Bond (2002) Curry et al (2002) Smith (2001)

NCEP Ice Mask Renfrew and Moore (1999) Gradient of SAT away from MIZ

NASATEAM – BOOTSTRAP Winter 1992

Iteration 0 Iteration 33

Claim 2 By modifying the sea ice cover these adjustments significantly affect air-sea fluxes

Mean and Total Heat Flux Differences March 10, 1993 Annual Mean 92-93

Claim 3 Using the adjoint method to synthesize model and observations can reveal systematic errors and biases with both

Atmospheric Adjustments

Conclusions The same model is shown to evolve quite differently based on reasonable adjustments to initial conditions and boundary forcing. Given the known model sensitivity to small changes to atmospheric forcing is there any information in the mean bias atmospheric adjustments that have utility beyond this specific model? ▫AOMIP participants could check this when basin-wide adjustments have been could be disseminated.

End

Credit Provided by the SeaWiFS Project, NASA/Goddard Space Flight Center, and ORBIMAGE MODIS : May 9, 1999SSM/I : May 9, /13/

Thoughts about sea ice data assimilation Data sets ▫Prescribed or assimilated Atmospheric ▫Trustworthiness of renanalyses in high latitudes. ▫Validation in lower latitudes ▫Uncertainties not provided Choice of ocean state ▫Almost certainly the biggest unknown ▫Under many conditions direct assimilation of sea ice state is incompatible with ocean heat content/stratification Sea Ice ▫Different algorithms perform better under different ice conditions ▫Uncertainties are certainly time and space dependent ▫Not provided Formulation of sea ice model ▫Not obvious that more sophisticated sea ice models’ adjoints will be useful Care of interpretation of adjustments ▫Model error is often overlooked ▫Atmospheric controls

Interpretation of Atm Controls State Estimate deficiencies ▫Too warm WGC Model deficiency: No boundary current eddies & Mixing ▫ATM wind control ▫Ekman transport of LS surface waters to LC ice edge ▫Increase the gradient so that GM can operate Model deficiency: Ice moves too easily off LC ▫ATM air temp control cools and forms more ice NCEP deficiencies ▫Low resolution, poor location of sea ice edge ▫ATM temp control ▫Warming of off-ice air temp