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

Slides:

Advertisements

Similar presentations

Mercator Ocean activity

Advertisements

Salt rejection, advection, and mixing in the MITgcm coupled ocean and sea-ice model AOMIP/(C)ARCMIP / SEARCH for DAMOCLES Workshop, Paris Oct 29-31, 2007.

© Crown copyright Met Office Decadal Climate Prediction Doug Smith, Nick Dunstone, Rosie Eade, Leon Hermanson, Adam Scaife.

Preliminary results on Formation and variability of North Atlantic sea surface salinity maximum in a global GCM Tangdong Qu International Pacific Research.

Jon Robson (Uni. Reading) Rowan Sutton (Uni. Reading) and Doug Smith (UK Met Office) Analysis of a decadal prediction system:

1 Geophysical Fluid Dynamics Laboratory Review June 30 - July 2, 2009.

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

Using High Quality SST Products to determine Physical Processes Contributing to SST Anomalies A First Step Suzanne Dickinson and Kathryn A. Kelly Applied.

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,

Response of the Atmosphere to Climate Variability in the Tropical Atlantic By Alfredo Ruiz–Barradas 1, James A. Carton, and Sumant Nigam University of.

SSH anomalies from satellite. Observed annual mean state Circulation creates equatorial cold tongues eastern Pacific Trades -> Ocean upwelling along Equator.

Thermohaline Circulation

LINKING INFORMATION FROM SSS TO OCEANIC FRESHWATER FLUXES USING NEAR-SURFACE SALINITY BUDGETS NADYA T. VINOGRADOVA 1 RUI M. PONTE 1 MARTHA W. BUCKLEY 2.

Cyclone composites in the real world and ACCESS Pallavi Govekar, Christian Jakob, Michael Reeder and Jennifer Catto.

Effects of Climate Change on Marine Ecosystems David Mountain US CLIVAR Science Symposium 14 July 2008.

The speaker took this picture on 11 December, 2012 over the ocean near Japan. 2014/07/29 AOGS 11th Annual Meeting in Sapporo.

Climate Variability and Change in the U.S. GLOBEC Regions as Simulated by the IPCC Climate Models: Ecosystem Implications PIs: Antonietta Capotondi, University.

U.S. AMOC Program A U.S. interagency program with a focus on AMOC monitoring and prediction capability NSF Geosciences program Process.

“ Combining Ocean Velocity Observations and Altimeter Data for OGCM Verification ” Peter Niiler Scripps Institution of Oceanography with original material.

Model LSW formation rate (2 yr averages) estimated from: (red) CFC-12 inventories, (black) mixed layer depth and (green) volume transport residual. Also.

Northern Hemisphere Atmospheric Transient Eddy Fluxes and their Co-variability with the Gulf Stream and Kuroshio-Oyashio Extensions Young-Oh Kwon and Terrence.

Atlantic Multidecadal Variability and Its Climate Impacts in CMIP3 Models and Observations Mingfang Ting With Yochanan Kushnir, Richard Seager, Cuihua.

Deep circulation and meridional overturning Steve Rintoul and many others ….

Transport in the Subpolar and Subtropical North Atlantic

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

Impact of partial steps and momentum advection schemes in a global ocean circulation model at eddy-premitting resolution Barnier Bernard et al.

Improved ensemble-mean forecast skills of ENSO events by a zero-mean stochastic model-error model of an intermediate coupled model Jiang Zhu and Fei Zheng.

North Atlantic Oscillation (NAO) Primary forcing mechanism of the NAO: internal atmospheric dynamics How can we account for the redness in the spectrum?

© Crown copyright Met Office Decadal predictions of the Atlantic ocean and hurricane numbers Doug Smith, Nick Dunstone, Rosie Eade, David Fereday, James.

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

Components of the Global Climate Change Process IPCC AR4.

The dynamic-thermodynamic sea ice module in the Bergen Climate Model Helge Drange and Mats Bentsen Nansen Environmental and Remote Sensing Center Bjerknes.

Combined Ocean-Geodetic Analysis of Global and Regional Ocean Mass-, and Freshwater Transport Divergences D. Stammer, A. Köhl, V. Romanova, F. Sigismund,

OCN 5401 Chapter 6 Effect of Earth’s Rotation Instructor: Dr. George A. Maul / X 7453.

“Very high resolution global ocean and Arctic ocean-ice models being developed for climate study” by Albert Semtner Extremely high resolution is required.

An evaluation of satellite derived air-sea fluxes through use in ocean general circulation model Vijay K Agarwal, Rashmi Sharma, Neeraj Agarwal Meteorology.

Hurricane Frequency and Sea Surface Temperature EAS 4803 Sheliza Bhanjee.

Role of the Gulf Stream and Kuroshio-Oyashio Systems in Large- Scale Atmosphere-Ocean Interaction: A Review Young-oh Kwon et al.

Ocean Surface heat fluxes

Group Meeting 2010/03/16 R Kirsten Feng. Coupled Decadal Variability in the North Pacific: An Observationally Constrained Idealized Model* BO.

Contributions to SST Anomalies in the Atlantic Ocean [Ocean Control of Air-Sea Heat Fluxes] Kathie Kelly Suzanne Dickinson and LuAnne Thompson University.

The CHIME coupled climate model Alex Megann, SOC 26 January 2005 (with Adrian New, Bablu Sinha, SOC; Shan Sun, NASA GISS; Rainer Bleck, LANL)  Introduction.

Numerical Investigation of Air- Sea Interactions During Winter Extratropical Storms Presented by Jill Nelson M.S. Marine Science Candidate Graduate Research.

OUTLINE Examples of AMOC variability and its potential predictability, Why we care, Characteristics of AMOC variability in a CCSM3 present-day control.

Decadal Variability, Impact, and Prediction of the Kuroshio Extension System B. Qiu 1, S. Chen 1, N. Schneider 1 and B. Taguchi 2 1. Dept of Oceanography,

By S.-K. Lee (CIMAS/UM), D. Enfield (AOML/NOAA), C. Wang (AOML/NOAA), and G. Halliwell Jr. (RSMAS/UM) Objectives: (1)To assess the appropriateness of commonly.

Sources of global warming of the upper ocean on decadal period scales Warren B. White 2010/05/18 Pei-yu Chueh.

A Green’s function optimization on the CS510 grid - develop and calibrate model configuration and parameterizations - experiment with cost function terms.

Decadal variability in the Indo-Pacific ocean inferred from satellite data and ECCO assimilation Tong Lee NASA Jet Propulsion Laboratory, California Institute.

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

Interannual to decadal variability of circulation in the northern Japan/East Sea, Dmitry Stepanov 1, Victoriia Stepanova 1 and Anatoly Gusev.

Jennifer Catto Supervisors: Len Shaffrey and Kevin Hodges Extra-tropical cyclones and Storm Tracks.

An Extreme Oceanic & Atmospheric Event in the South Pacific & Western Antarctica Associated With the El Niño Tong Lee*, Carmen Böning, Will Hobbs,

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

AOMIP WORKSHOP Ian Fenty Patrick Heimbach Carl Wunsch.

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.

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

Gent-McWilliams parameterization: 20/20 Hindsight Peter R. Gent Senior Scientist National Center for Atmospheric Research.

I. Objectives and Methodology DETERMINATION OF CIRCULATION IN NORTH ATLANTIC BY INVERSION OF ARGO FLOAT DATA Carole GRIT, Herlé Mercier The methodology.

The Ocean’s role in the climate system

A Comparison of Profiling Float and XBT Representations of Upper Layer Temperature Structure of the Northwestern Subtropical North Atlantic Robert L.

OCEAN RESPONSE TO AIR-SEA FLUXES Oceanic and atmospheric mixed

The relationship between MVT & MHT of AMOC:

Mark A. Bourassa and Qi Shi

HiGEM Ocean Surface boundary condition Freshwater balance

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

Heat Transport by the Atmosphere and ocean

Korea Ocean Research & Development Institute, Ansan, Republic of Korea

Tony Lee, NASA JPL/CalTech

Presentation transcript:

Examining the relationships between low-frequency upper ocean temperature and AMOC variability in ECCO v4 solutions Martha W. Buckley and Rui Ponte (AER) Thanks to the ECCO group, in particular Gael Forget and Patrick Heimbach

Low-frequency Atlantic SST variability Observations indicate Atlantic SSTs exhibit significant low-frequency variability (Bjerknes 1964; Kushnir 1994; Ting et al. 2009). Impacts of Atlantic SST variability include : –Temperature, precipitation over adjacent landmasses (Zhang and Delworth, 2006, 2007; Pohlman et al, 2006) –Changes in frequency/intensity of Atlantic hurricanes (Zhang and Delworth, 2006) However, the origin of SST anomalies is not understood. –Passive (local) response to atmospheric forcing (Seager, 2000). –Wind and/or buoyancy forced baroclinic Rossby waves (Sturges and Hong, 1995, 1998; Qiu 2002; Piecuch and Ponte, 2012). –Large scale changes in ocean heat transport due to changes in the AMOC (Kushnir 1994, etc.) and gyre circulations. –Lozier (2010): most significant question concerning the AMOC is role of AMOC in creating decadal SST anomalies.

Outline What is the relationship between interannual AMOC and upper-ocean heat content (UOHC) variability? I.ECCO version 4 state estimate A. Model details (G. Forget) B. Comparison to observations 1.Comparison of mean temperature to in-situ observations. 2.Comparison of SST variability to satellite SST observations. 3.Comparison of mean AMOC/OHT and AMOC and OHT variability to RAPID estimates. II.Interannual UOHC and AMOC variability A.UOHC variability in ECCO B.Associated AMOC variability C.Causality?

ECCO version 4 state estimate MITgcm least squares fit to observations, For details, see G. Forget’s talk or Forget et al, in prep. new global grid LLC_90 –includes the Arctic –telescopic resolution to 1/3 o near the Equator –meridionally isotropic in mid-latitudes 50 vertical levels with partial cells forcing using ERA-Interim state-of-the-art dynamic/thermodynamic sea ice model nonlinear free surface + real freshwater flux B.C.s third-order advection scheme removal of C-D scheme for Coriolis terms use of diffusion operator (Weaver & Courtier, 2001) for in-situ obs. all satellite data are daily along-track internal model parameters are part of the control space

Comparison of ECCO & mean in-situ temperature G. Forget et al, in prep

Variability: comparison of ECCO & satellite SST SST variability: rms(modeled – observed) (G. Forget)

Realism of ECCO: AMOC and mean OHT Estimate of Atlantic OHT from ECMWF reanalysis: Trenberth and Caron (2001)

Realism of ECCO: comparison to RAPID Correlation 0.73 No systematic offset Correlation improves with time Correlation: 0.81 ECCO systematically underestimates OHT Note: Neither Florida current transport or RAPID AMOC transport estimates are used as constraints in ECCO

ECCO: Upper-ocean temperature (UOT) variability

UOT variability  AMOC variability AMOC variability UOT variability ?? Causality? AMOC  UOT OHT anomalies associated with AMOC variability lead to UOT variability UOT  AMOC UOT anomalies reach ocean boundaries and lead to AMOC variability UOT  AMOC UOT variability results in AMOC variability which feeds back onto UOT

Conclusions ECCO v4 estimate reasonably captures mean ocean state and large-scale ocean variability. –Atlantic OHT matches Trenberth & Carone (2001) well, although somewhat too low compared to direct ocean estimates. –Mean and variability of AMOC strength at 26 o N similar to RAPID –OHT variability at 26 o N captured; mean smaller than MOCHA estimate. ECCO exhibits low-frequency upper ocean temperature (UOT) variability: large anomalies over Gulf Stream path and in subpolar gyre. Large-scale AMOC variability associated with UOT variability. Causality of relationship to be determined. –UOHC budget analyses: role of air-sea heat fluxes, advection (separately consider Ekman transports, local response to winds).

Extra slides

Baroclinic pressure: modal decompostion Equations of motion linearized about a resting mean state, flat bottom Separation of variables  eigenvalue problem for vertical structure (Gill, 1982). Vertical structure for pressure: Solve for F(z) at each horizontal location using observed N(z). Modes = complete, orthonormal basis What portion of the variability is captured by 1 st baroclinic mode? Majority of baroclinic pressure variability in upper ocean is explained by 1 st baroclinic mode