High-Resolution Climate Data from Research and Volunteer Observing Ships: A Strategic Intercalibration and Quality Assurance Program A Joint ETL/WHOI Initiative.

Slides:

Advertisements

Similar presentations

Meteorological Observatory Lindenberg – Richard Assmann Observatory The GCOS Reference Upper Air Network.

Advertisements

OOPC and OCG, April 2002 * OOPC Pilot Projects * Other OOPC Initiatives * OceanObs99 St. Raphael * CEOS/IGOS Ocean Theme * Toward a products/system approach.

A thermodynamic model for estimating sea and lake ice thickness with optical satellite data Student presentation for GGS656 Sanmei Li April 17, 2012.

1 st Joint GOSUD/SAMOS Workshop The Florida State University 1 Sensitivity of Surface Turbulent Fluxes to Observational Errors  or.

Hurricanes and Atlantic Surface Flux Variability Mark A. Bourassa 1,2, Paul J. Hughes 1,2, Jeremy Rolph 1, and.

Air-sea heat fluxes in the stratocumulus deck / cold tongue / ITCZ complex of the eastern tropical Pacific Meghan F. Cronin (NOAA PMEL) Chris Fairall (NOAA.

Lesson 2: Common Sensors and Measurements Systems If only it were this simple!

Will Pendergrass NOAA/ARL/ATDD OAR Senior Research Council Meeting Oak Ridge, TN August 18-19, 2010 Boundary–Layer Dispersion Urban Meteorology 5/20/2015Air.

1 Variability of sea surface temperature diurnal warming Carol Anne Clayson Florida State University Geophysical Fluid Dynamics Institute SSTST Meeting.

Using Scatterometers and Radiometers to Estimate Ocean Wind Speeds and Latent Heat Flux Presented by: Brad Matichak April 30, 2008 Based on an article.

Princeton University Global Evaluation of a MODIS based Evapotranspiration Product Eric Wood Hongbo Su Matthew McCabe.

November 9, 2010 Diurnal Warming and Associated Uncertainties Gary A. Wick NOAA ESRL/PSD New Chair, GHRSST DVWG.

Lesson 2: Common Sensors and Measurements Systems If only it were this simple!

Climate quality data and datasets from VOS and VOSClim Elizabeth Kent and David Berry National Oceanography Centre, Southampton.

Meteorological Observatory Lindenberg – Richard Assmann Observatory The GCOS Reference Upper Air Network.

CALWATER2 Field Study of Air-Sea Interaction and AR dynamics in Midlatitude Pacific Storms Ship (NOAA Brown) Ship Field Duration – 30 days Time Window.

The NOAA Portable Seagoing Air-Sea Flux Standard C. W. Fairall, S. Pezoa, and D. E. Wolfe, NOAA Earth System Research Laboratory, PSD3, 325 Broadway, Boulder,

Evaporation Slides prepared by Daene C. McKinney and Venkatesh Merwade

National Center for Atmospheric Research * ASP Summer Colloquium * Boulder Colorado * June 1, 2009 University of Colorado at Boulder Boundary Layer Lecture.

Section 12.3 Gathering Weather Data

Ship-based measurements of cloud microphysics and PBL properties in precipitating trade cumulus clouds during RICO Allen White and Jeff Hare, University.

Evaporation What is evaporation? How is evaporation measured? How is evaporation estimated? Reading: Applied Hydrology Sections 3.5 and 3.6 With assistance.

Ocean Synthesis and Air-Sea flux evaluation Workshop Global Synthesis and Observations Panel (GSOP) Organized by Lisan Yu, Keith Haines, Tony Lee WHOI,

IORAS activities for DRAKKAR in 2006 General topic: Development of long-term flux data set for interdecadal simulations with DRAKKAR models Task: Using.

Comparison of Surface Turbulent Flux Products Paul J. Hughes, Mark A. Bourassa, and Shawn R. Smith Center for Ocean-Atmospheric Prediction Studies & Department.

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

Recommendations from the High-Resolution Marine Meteorology Workshop 3-5 March 2003 Center for Ocean-Atmospheric Prediction Studies Florida State University.

High-Resolution Climate Data from Research and Volunteer Observing Ships: A Strategic Intercalibration and Quality Assurance Program A Joint ETL/WHOI Initiative.

Automated Weather Observations from Ships and Buoys: A Future Resource for Climatologists Shawn R. Smith Center for Ocean-Atmospheric Prediction Studies.

Upper ocean heat budget in the southeast Pacific stratus cloud region using eddy-resolving HYCOM Yangxing Zheng (University of Colorado) Toshi Shinoda.

Why We Care or Why We Go to Sea.

Synthesis NOAA Webinar Chris Fairall Yuqing Wang Simon de Szoeke X.P. Xie "Evaluation and Improvement of Climate GCM Air-Sea Interaction Physics: An EPIC/VOCALS.

Three Lectures on Tropical Cyclones Kerry Emanuel Massachusetts Institute of Technology Spring School on Fluid Mechanics of Environmental Hazards.

Air – Sea Measurements from Ships: Fluxes, Time Series, Remote Sensing Dr. Jeff Hare CIRES – University of Colorado and NOAA Earth Systems Research Lab.

Bulk Parameterizations for Wind Stress and Heat Fluxes (Chou 1993; Chou et al. 2003) Outlines: Eddy correlation (covariance) method Eddy correlation (covariance)

Investigation of Mixed Layer Depth in the Southern Ocean by using a 1-D mixed layer model Chin-Ying Chien & Kevin Speer Geophysical Fluid Dynamics Institute,

Shipboard Automated Meteorological and Oceanographic System (SAMOS) Initiative: A Key Component of an Ocean Observing System Shawn R. Smith Center for.

The Ocean Observations panel for Physics and Climate (OOPC) Mark Bourassa, Toshio Suga (OOPC co-chairs) Katy Hill (OOPC Secretariat)

Evaluation of the Accuracy of in situ Sources of Surface Flux Observations for Model Validation: Buoys and Research Vessels in the Eastern Pacific C. W.

Ocean Surface heat fluxes Lisan Yu and Robert Weller

Characterization of Errors in Turbulent Heat Fluxes Caused by Different Heat and Moisture Roughness Length Parameterizations 1. Background and Motivation.

A Seven-Cruise Sample of Clouds, Radiation, and Surface Forcing in the Equatorial Eastern Pacific J. E. Hare, C. W. Fairall, T. Uttal, D. Hazen NOAA Environmental.

Height Matters. Wind, Temperature, and Humidity.

The Character of North Atlantic Subtropical Mode Water Potential Vorticity Forcing Otmar Olsina, William Dewar Dept. of Oceanography, Florida State University.

Ocean Surface heat fluxes

An evaluation of a hybrid satellite and NWP- based turbulent fluxes with TAO buoys ChuanLi Jiang, Kathryn A. Kelly, and LuAnne Thompson University of Washington.

4. Intensive field programs and extended monitoring In this research we use different types of observations for instrument development or characterization,

Ship-board Flux Measurements made during CalNex 2010 C.W. Fairall, D.E. Wolfe, S. Pezoa, L. Bariteau, B. Blomquist, C. Sweeney Air-Sea flux measurements.

Evaporation What is evaporation? How is evaporation measured?

November 28, 2006 Representation of Skin Layer and Diurnal Warming Effects Gary Wick 1 and Sandra Castro 2 1 NOAA Earth System Research Laboratory 2 CCAR,

Evaluation of Satellite-Derived Air-Sea Flux Products Using Dropsonde Data Gary A. Wick 1 and Darren L. Jackson 2 1 NOAA ESRL, Physical Sciences Division.

Guðrún Nína Petersen and Ian A. Renfrew Aircraft-based observations of air-sea fluxes over Denmark Strait and the Irminger Sea during high wind speed conditions.

A New Climatology of Surface Energy Budget for the Detection and Modeling of Water and Energy Cycle Change across Sub-seasonal to Decadal Timescales Jingfeng.

Meteorological Variables 1. Local right-hand Cartesian coordinate 2. Polar coordinate x y U V W O O East North Up Dynamic variable: Wind.

Recommendations from the High-Resolution Marine Meteorology Workshop

Status and Outlook Evaluating CFSR Air-Sea Heat, Freshwater, and Momentum Fluxes in the context of the Global Energy and Freshwater Budgets PI: Lisan.

Remote Sensing ET Algorithm— Remote Evapotranspiration Calculation (RET) Junming Wang,

A Fear-Inspiring Intercomparison of Monthly Averaged Surface Forcing

CLIMODE surface mooring

PACS/EPIC Enhanced Monitoring

Marine Meteorology Quality Control at the Florida State University

Annual cycle of cloud fraction and surface radiative cloud forcing in the South-East Pacific Stratocumulus region Virendra P. Ghate and Bruce A. Albrecht.

The HOAPS-3 climatology

Global Warming Problem

Comparison of Aircraft Observations With Surface Observations from

Assessment of the Surface Mixed Layer Using Glider and Buoy Data

Total surface flux (+up) from models

Operational Oceanography

Weather Day 2 Weather Day 2.

Presentation transcript:

High-Resolution Climate Data from Research and Volunteer Observing Ships: A Strategic Intercalibration and Quality Assurance Program A Joint ETL/WHOI Initiative C. Fairall and R. Weller Requirement: There is a need for air-sea flux measurements of high accuracy and high time resolution Intensive field programs Satellite retrievals NWP/Climate model products Climate monitoring Relevant quantities: Turbulent fluxes (stress, sensible and latent heat), radiative fluxes (solar and IR), precipitation, bulk meteorology. Potential: Present technology allows measurements of net heat input to the ocean from ships and buoys to an accuracy of about 10 W/m^2, but this accuracy is not being realized on most platforms Solution: Implement a multi-faceted program of quality assurance, intercalibration, and data archiving. Research Vessels (NOAA, UNOLS, Navy, Coast Guard,..) VOSClim Strategy: Create a ship flux measurement group Construct a state-or-the-art portable flux standard that can be installed on any ship to obtain best possible characterization of the relevant variables Construct a distributed set of sensors to be place with ship sensors for side-by-side intercomparison Work with each ship operator to improve sensor suite, placement, connection methods, processing, etc Perform a computational fluid dynamics ICFD) assessment of the flow distortion effects for specific sensor locations Set up a web site with a Flux Manual detailing procedures and best practices for measurements from ships and flux estimation methods

How Good Do We Need to Be? GOAL-1: Measure net surface heat flux to ±10 Wm-2

Sample Bias Estimates for Mean Temperature and Humidity Comparison of Vaisala against hand-held standard: bias corrections on the order of 0.2 C and 0.3 g/kg.

NOAA SHIP Ronald H. Brown Wind Speed Measurements Wind speed measurements with IMET (left) and ETL (right). Blue line is ship speed.

Simple Flow Distortion Corrections ETL sonic anemometer wind speed after simple flow distortion corrections. Corrected ETL sonic winds compared to raw IMET winds: left panel, all data; right panel, with ship stopped.

Evaluation of Distortion Effects on Wind Speed from the Ronald H. Brown Mean wind speed divided by inertial-dissipation friction velocity measurements. The surface stress is air density times u*2 . ID friction velocity is relatively unaffected by flow distortion. Upper panel is uncorrected IMET data and the lower panel is the distortion-corrected ETL sonic anemometer. Flow distortion effects are apparent as local extrema at about ±25 deg. The variance of the upper signal is about twice that of the lower.

Recent sample comparison from the R/V Roger Revelle: upper left, wind speed; upper right, wind direction; lower left, water temperature.; lower right, air temperature

High-Resolution Climate Data from Research and Volunteer Observing Ships Portable Flux Standard: Essentially an improved, user-friendly, easy to install version of the existing ETL ship flux system High-speed motion-corrected turbulence sensors (sonic anemometers, IR hygrometers) Pitch-roll stabilized radiative flux sensors Well characterized, well placed precipitation sensors High quality aspirated mean T/RH, IR ocean skin temperature, seasnake SST Full navigation system and 6 DOF ship motions Measurements of surface waves Calibrations by national facilities Principally ETL Distributed side-by-side sensor suite: Based on IMET sets Wireless local network Principally WHOI Schedule for Flux Standard: FY04 Test concept on NOAA ship Ronald H. Brown using existing ETL flux system FY05 Begin construction of flux standard. Field test on UNOLS ship FY06 Complete construction of flux standard. Perform intercalibration study on one ship Intensive Field Study: Suggest a field study with FLIP, a typical R/V, and a buoy to investigate ship flow distortion, CFD solutions, and the distortion effects on bulk meteorological variables and turbulent fluxes.

Upper: R/V Roger Revelle and WHOI Flux buoy. Lower left: R/P FLIP Upper: R/V Roger Revelle and WHOI Flux buoy. Lower left: R/P FLIP. Lower right: direct flux sensors.