Dr. Frank Herr Ocean Battlespace Sensing S&T Department Head Dr. Scott L. Harper Program Officer Team Lead, 322AGP Dr. Martin O. Jeffries Program Officer.

Slides:



Advertisements
Similar presentations
Future Directions and Initiatives in the Use of Remote Sensing for Water Quality.
Advertisements

World Meteorological Organization Working together in weather, climate and water WMO Global Integrated Polar Prediction System (GIPPS) Peter Lemke (on.
N84 UNCLASSIFIED Rear Admiral Dave Titley, Ph.D. Oceanographer of the Navy / Director Task Force Climate Change October 15, 2009 This Presentation is Unclassified.
Collaborative Research on Sunlight and the Arctic Atmosphere-Ice-Ocean System (AIOS) Hajo Eicken Univ. of Alaska Fairbanks Ron Lindsay Univ. of Washington.
Collaborative Investigation of Climate Cryosphere Interaction 3 (CICCI 3) Rune Storvold, Norut/NTNU NySMAC, Helsinki, April 7 th -8 th, 2014.
Discussion about two papers concerning the changing Arctic sea ice GEO6011Seminar in Geospatial Science and Applications Wentao Xia 11/19/2012.
Ocean Group Question (s) Will an ice reduced Arctic become more productive and what are the consequences of this to other components of the system? – Is.
Robbie Hood NOAA UAS Program Director 20 June 2013.
Carbon Cycle and Ecosystems Important Concerns: Potential greenhouse warming (CO 2, CH 4 ) and ecosystem interactions with climate Carbon management (e.g.,
Modeling circulation and ice in the Chukchi and Beaufort Seas
Environmental Data Collection Using Autonomous Wave Gliders Qing Wang, Dick Lind, Kate Hermsdorfer Meteorology Department Kevin B. Smith, Joe Rice Physics.
0 Future NWS Activities in Support of Renewable Energy* Dr. David Green NOAA, NWS Office of Climate, Water & Weather Services AMS Summer Community Meeting.
Parameters and instruments A. Proshutinsky, Woods Hole Oceanographic Institution Science and Education Opportunities for an Arctic Cabled Seafloor Observatory.
Chukchi Sea and Beaufort Sea Weather Research and Forecasting WRF Mesoscale Meteorology Model Mid-Term Project Meeting Funded by Bureau of Ocean Energy.
Southern Ocean Air-Sea Flux Observations Eric Schulz, CAWCR, BoM.
Ocean-Ice Interaction Measurements Using Autonomous Ocean Flux Buoys in the Arctic Observing System Toward Developing an Arctic Observing Network: An Array.
National Ice Center Science and Applied Technology Program Dr. Michael Van Woert, Chief Scientist.
Challenges in Urban Meteorology: A Forum for Users and Providers OFCM Panel Summaries Bob Dumont Senior Staff Meteorologist OFCM.
IARPC Sea Ice Collaboration Team: Organizing, Tracking, Modifying & Creating Milestones There is a large number IARPC Sea Ice milestones and at first glance.
U.S. Navy & Marine Corps Program
Science Needs for Arctic Operations. Randall Luthi– Moderator – National Ocean Industries Association Erik Milito – American Petroleum Institute Gary.
1 U.S. Navy Arctic Roadmap Implementation Sea, Air, Space Exposition RADM Jonathan White Oceanographer and Navigator of the Navy 15 April 2015.
Numerical International Polar Year Andrey Proshutinsky and AOMIP group, Woods Hole Oceanographic Institution NOAA Arctic Science Priorities Workshop, February.
Arctic ROOS contributions
Report on Ice Sheet Modelling Activities David Holland Courant Institute of Mathematical Sciences New York University, NY USA Jonathan Gregory Walker Institute,
Sea Ice Deformation Studies and Model Development
The polar sea ice covers are large Tens of millions of square kilometers, and empty.
SMHI in the Arctic Lars Axell Oceanographic Research Unit Swedish Meteorological and Hydrological Institute.
The U.S. Inter-agency Arctic Research Policy Committee (IARPC) 5-year Research Plan, FY13-FY17 1.Understand sea-ice dynamics, ecosystem processes, ecosystem.
1 NOS Coastal Ocean Operational Forecast Systems Presented By: Patrick Burke (NOS/CO-OPS) Contributors: Aijun Zhang (CO-OPS), Peter Stone (CO-OPS), Edward.
Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Image: MODIS Land Group, NASA GSFC March 2000 Commerce and Transportation.
The GEOSS Portfolio for Science and Technology Produced by ST Featuring: Climate: Capacity Building of Operational Oceanography and Climate Adaptation.
Collaborative Research: Toward reanalysis of the Arctic Climate System—sea ice and ocean reconstruction with data assimilation Synthesis of Arctic System.
Integrated Ocean Observing System -- IOOS -- United States Contribution to the Global Ocean Observing System Kurt Schnebele Ocean.US Deputy of Data Management.
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.
Translation to the New TCO Panel Beverly Law Prof. Global Change Forest Science Science Chair, AmeriFlux Network Oregon State University.
SCCOOS Goals and Efforts Within COCMP, SCCOOS aims to develop products and procedures—based on observational data—that effectively evaluate and improve.
Symposium on multi-hazard early warning systems for integrated disaster risk management A JCOMM perspective Enhanced early warning for better coastal or.
Alaska Ocean Observing System Regional association under IOOS Part of coastal GOOS Ocean component of GEOSS IPY opportunity.
Office of Science Office of Biological and Environmental Research DOE Workshop on Community Modeling and Long-term Predictions of the Integrated Water.
Modern Era Retrospective-analysis for Research and Applications: Introduction to NASA’s Modern Era Retrospective-analysis for Research and Applications:
Validation of US Navy Polar Ice Prediction (PIPS) Model using Cryosat Data Kim Partington 1, Towanda Street 2, Mike Van Woert 2, Ruth Preller 3 and Pam.
© Crown copyright Met Office The Role of Research Aircraft in YOPP Chawn Harlow, YOPP Summit, WMO, Geneva 13 July 2015.
Annu Oikkonen University of Helsinki Mesoscale dynamic- thermodynamic modelling of sea ice Supervisor Prof. Matti Leppäranta.
Towards development of a Regional Arctic Climate System Model --- Coupling WRF with the Variable Infiltration Capacity land model via a flux coupler Chunmei.
IGY and the Origins of El Niño/Southern Oscillation (ENSO) Research
The Science Requirements for Coastal and Marine Spatial Planning Dr. Robert B. Gagosian President and CEO September 24, 2009.
Evaluation of the Real-Time Ocean Forecast System in Florida Atlantic Coastal Waters June 3 to 8, 2007 Matthew D. Grossi Department of Marine & Environmental.
AOMIP status Experiments 1. Season Cycle 2. Coordinated - Spinup Coordinated - Analysis Coordinated 100-Year Run.
Ice-Based Observatories network in the Arctic Ocean Andrey Proshutinsky, Woods Hole Oceanographic Institution NOAA Arctic Science Priorities Workshop,
Vision of an Integrated Global Observing System Gregory W. Withee Assistant Administrator for Satellite and Information Services National Oceanic and Atmospheric.
The Multidisciplinary drifting Observatory
U.S. Integrated Ocean Observing System (IOOS ® ) Z Improve safetyEnhance our economyProtect our environment CIMAR-GOMC meeting – 25 Feb 2015 Zdenka Willis.
RIME A possible experiment for Advancing Antarctic Weather Prediction David H. Bromwich 1, John J. Cassano 1, Thomas R. Parish 2, Keith M. Hines 1 1 -
EuroGOOS Arctic Task Team Workshop September 2006 Satellite data portals for Arctic monitoring Stein Sandven Nansen Environmental and Remote Sensing.
Future needs and plans for ocean observing in the Arctic AOOS Arctic Town Hall Futur Zdenka Willis Integrated Ocean Observing System National Program Office.
SPURS Synthesis Research Objectives: Budget calculations Resolve important terms of the freshwater and heat budgets of the upper 1000 m on temporal scales.
Polar Research Thesis Topics Associate Research Professor Tim Stanton X3144 Spanegal 329 Comparisons of ocean heat fluxes.
THEME#4: Are predicted changes in the arctic system detectable? OAII Focus on: Detecting Change(s) in the Arctic System - Ocean (heat, salt/freshwater,
Assessing the U.S. Navy Coupled Ice-Ocean Model vs. Recent Arctic Observations David A. Hebert 1, Richard Allard 1, Pamela Posey 1, E. Joseph Metzger 1,
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.
ICE AND OCEAN ACTIVITIES
Demonstrate the performance of the IAOS towards stakeholders
Terrestrial-atmosphere (1)
Vasily Smolyanitsky – AARI, St.Petersburg
AOMIP and FAMOS are supported by the National Science Foundation
Shuyi S. Chen, Ben Barr, Milan Curcic and Brandon Kerns
GEO - Define an Architecture Integrated Solutions
CRITICAL GAPS: OCEANS IN THE EARTH SYSTEM
Presentation transcript:

Dr. Frank Herr Ocean Battlespace Sensing S&T Department Head Dr. Scott L. Harper Program Officer Team Lead, 322AGP Dr. Martin O. Jeffries Program Officer Arctic Science Advisor

2  How little sea ice will there be, and when will the key changes occur? Need better prediction capability underpinned by basic research  How is the Arctic region as a whole going to be different? Need research into how the entire Arctic environmental system functions  What does the Navy need to know to operate in the Arctic? Need sustained observations and improved predictions of the state of the Arctic  How will the changing Arctic affect the rest of the earth, and vice-versa? Need an Arctic environmental system model integrated within global prediction models Naval Needs and Key Questions… Task Force Climate Change “Arctic Roadmap”: Must have Arctic environmental information and predictions to support investment and policy decisions, and future operations NORTHCOM: Must improve ability to observe and predict the Arctic environment N2N6E Capabilities Based Assessment: Capability Gap in Provision of Environmental Information Insufficient ability to provide oceanographic information, ice reports, accurate navigation charts, meteorological analysis and forecasts The Changing Arctic

Emerging Dynamics of the Marginal Ice Zone: DRI Department Research Initiative (DRI): FY12-FY16 Main field experiment in spring-summer-early autumn 2014 in the Beaufort Sea. Components: Deployment of acoustic navigation and communication array, under-ice gliders and floats, ice-tethered profilers, ice mass balance buoys, wave buoys on ice and in open water. Development of the Marginal Ice Zone Modeling and Assimilation System (MIZMAS) and Arctic-Cap Nowcast/Forecast System for improved sea ice prediction. Objectives: Collect and analyze a benchmark data set that resolves the key processes controlling the evolution of the “new” MIZ. Identify key interactions and feedbacks in the ice-ocean- atmosphere system and investigate how these might change with the predicted increased seasonality of the Arctic sea ice cover. Evaluate the ability of existing models to predict the seasonal evolution of the MIZ. Improve parameterization of key processes with the goal of enhancing seasonal forecast capability. August 1990August 2012

Sea State and Boundary Layer Physics of the Emerging Arctic Ocean: DRI Department Research Initiative (DRI): FY13-FY17 Main field experiment in summer-early autumn 2015 in the Beaufort and Chukchi seas. Proposals are currently under review Anticipate deployment of moorings with upward-looking acoustic wave profilers, drifting wave and meteorological buoys in open water and in the marginal ice zone, synthetic aperture radar (SAR) remote sensing of wind and wave spectra, and efforts to improve wave models for both open ocean and sea ice cover in the Arctic. Objectives: Understand the physics of heat and mass transfer from the ocean to the atmosphere, and the seasonal variability of fluxes during summer ice retreat and autumn ice advance. Develop a new sea state climatology, identify factors affecting the spatial and temporal variability of sea state, and improve forecasting of waves on the open ocean and in the marginal ice zone in the Arctic. Develop a climatology of and improve theory of wave attenuation and scattering in the sea ice cover. Use wave scattering theory directly in integrated Arctic system models, and indirectly to define an ice rheology for use in Arctic system models.

High-Resolution Arctic Prediction Assimilating SAR Data Merging of data from multiple platforms will provide daily coverage of the Arctic at high spatial resolution. Algorithm development for data assimilation into predictive models: Ice concentration and dynamics Ice ridges Ice types Open water waves Data collections are beginning now, with a focus on the Bering Strait, Beaufort and Chukchi Sea areas in preparation to support the DRI field efforts in 2014 and Develop an improved modeling capability for the Arctic for both basic understanding and prediction Coupling ocean models with ice, wave, and atmospheric models in the Arctic Data assimilation techniques for the Arctic Ocean Building tools to help optimize the Arctic observing system Role of remote sensing and in situ data in constraining Arctic models Improved models and methods for prediction of sea ice (nowcast to 6+ months) Example of daily coverage from COSMO-SkyMed

~ end ~