The Relation Between SST, Clouds, Precipitation and Wave Structures Across the Equatorial Pacific Anita D. Rapp and Chris Kummerow 14 July 2008 AMSR Science.

Slides:

Advertisements

Similar presentations

1 Dynamical Polar Warming Amplification and a New Climate Feedback Analysis Framework Ming Cai Florida State University Tallahassee, FL 32306

Advertisements

Recent Evidence for Reduced Climate Sensitivity Roy W. Spencer, Ph.D Principal Research Scientist The University of Alabama In Huntsville March 4, 2008.

Enhancement of Satellite-based Precipitation Estimates using the Information from the Proposed Advanced Baseline Imager (ABI) Part II: Drizzle Detection.

The Original TRMM Science Objectives An assessment 15 years after launch Christian Kummerow Colorado State University 4 th International TRMM/GPM Science.

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

Aerosol-Precipitation Responses Deduced from Ship Tracks as Observed by CloudSat Matthew W. Christensen 1 and Graeme L. Stephens 2 Department of Atmospheric.

Scaling Laws, Scale Invariance, and Climate Prediction

TRMM Tropical Rainfall Measurement (Mission). Why TRMM? n Tropical Rainfall Measuring Mission (TRMM) is a joint US-Japan study initiated in 1997 to study.

Variability of Liquid Water Path in Marine Boundary Layer Clouds

Wesley Berg, Tristan L’Ecuyer, and Sue van den Heever Department of Atmospheric Science Colorado State University Evaluating the impact of aerosols on.

MICROWAVE RAINFALL RETRIEVALS AND VALIDATIONS R.M. GAIROLA, S. POHREL & A.K. VARMA OSD/MOG SAC/ISRO AHMEDABAD.

Deep Tropical Convection contribution to climate change.

Applications of satellite measurements on dust-cloud-precipitation interactions over Asia arid/semi-arid region Jianping Huang Key Laboratory for Semi-Arid.

ATS 351 Lecture 8 Satellites

The Tropical Cloud Population R. A. Houze Lecture, Indian Institute of Tropical Meteorology, Pune, 9 August 2010.

Mesoscale Convective Systems in the Initiation of the MJO Jian Yuan and Robert A. Houze University of Washington CloudSat/CALIPSO Science Team Meeting.

The water holding capacity of the Earth’s atmosphere is governed by the Clausius-Clapeyron (CC) Law which states that there is approximately a 7% increase.

Profiling Clouds with Satellite Imager Data and Potential Applications William L. Smith Jr. 1, Douglas A. Spangenberg 2, Cecilia Fleeger 2, Patrick Minnis.

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

SMOS+ STORM Evolution Kick-off Meeting, 2 April 2014 SOLab work description Zabolotskikh E., Kudryavtsev V.

Precipitation Retrievals Over Land Using SSMIS Nai-Yu Wang 1 and Ralph R. Ferraro 2 1 University of Maryland/ESSIC/CICS 2 NOAA/NESDIS/STAR.

A Combined Radar/Radiometer Retrieval for Precipitation IGARSS – Session 1.1 Vancouver, Canada 26 July, 2011 Christian Kummerow 1, S. Joseph Munchak 1,2.

A NON-RAINING 1DVAR RETRIEVAL FOR GMI DAVID DUNCAN JCSDA COLLOQUIUM 7/30/15.

AGU 2002 Fall Meeting NASA Langley Research Center / Atmospheric Sciences Validation of GOES-8 Derived Cloud Properties Over the Southeastern Pacific J.

13 June, 2013 Dymecs Meeting, Reading Tropical convective organisation in the UM Chris Holloway NCAS-Climate, Dept. of Meteorology, University of Reading.

AN ENHANCED SST COMPOSITE FOR WEATHER FORECASTING AND REGIONAL CLIMATE STUDIES Gary Jedlovec 1, Jorge Vazquez 2, and Ed Armstrong 2 1NASA/MSFC Earth Science.

Estimation of Cloud and Precipitation From Warm Clouds in Support of the ABI: A Pre-launch Study with A-Train Zhanqing Li, R. Chen, R. Kuligowski, R. Ferraro,

Meteorological Data Analysis Urban, Regional Modeling and Analysis Section Division of Air Resources New York State Department of Environmental Conservation.

Volcanic Climate Impacts and ENSO Interaction Georgiy Stenchikov Department of Environmental Sciences, Rutgers University, New Brunswick, NJ Thomas Delworth.

An Intercalibrated Microwave Radiance Product for Use in Rainfall Estimation Level 1C Christian Kummerow, Wes Berg, G. Elsaesser Dept. of Atmospheric Science.

AMSR-E Ocean Rainfall Algorithm Status AMSR-E Science Team Meeting Huntsville, AL 2-3 June, 2010 C. Kummerow Colorado State University.

Matthew Miller and Sandra Yuter Department of Marine, Earth, and Atmospheric Sciences North Carolina State University Raleigh, NC USA Phantom Precipitation.

WATER VAPOR RETRIEVAL OVER CLOUD COVER AREA ON LAND Dabin Ji, Jiancheng Shi, Shenglei Zhang Institute for Remote Sensing Applications Chinese Academy of.

CCSM Atmospheric Model Working Group Summary J. J. Hack, D. A Randall AMWG Co-Chairs CCSM Workshop, 28 June 2001 CCSM Workshop, 28 June 2001.

Clouds and Precipitation Christian Kummerow Colorado State University ISCCP 25 Year Anniversary New York, NY 25 July 2008.

A New Inter-Comparison of Three Global Monthly SSM/I Precipitation Datasets Matt Sapiano, Phil Arkin and Tom Smith Earth Systems Science Interdisciplinary.

Trends & Variability of Liquid Water Clouds from Eighteen Years of Microwave Satellite Data: Initial Results 6 July 2006 Chris O’Dell & Ralf Bennartz University.

Evaluation of Passive Microwave Rainfall Estimates Using TRMM PR and Ground Measurements as References Xin Lin and Arthur Y. Hou NASA Goddard Space Flight.

Workshop on Tropical Biases, 28 May 2003 CCSM CAM2 Tropical Simulation James J. Hack National Center for Atmospheric Research Boulder, Colorado USA Collaborators:

Robert Wood, Atmospheric Sciences, University of Washington The importance of precipitation in marine boundary layer cloud.

Trends in Tropical Water Vapor ( ): Satellite and GCM Comparison Satellite Observed ---- Model Simulated __ Held and Soden 2006: Robust Responses.

Trends in Tropical Water Vapor ( ): Satellite and GCM Comparison Satellite Observed ---- Model Simulated __ Held and Soden 2006: Robust Responses.

Response of active and passive microwave sensors to precipitation at mid- and high altitudes Ralf Bennartz University of Wisconsin Atmospheric and Oceanic.

Comparison of Oceanic Warm Rain from AMSR-E and CloudSat Matt Lebsock Chris Kummerow.

Diurnal Water and Energy Cycles over the Continental United States from three Reanalyses Alex Ruane John Roads Scripps Institution of Oceanography / UCSD.

Locally Optimized Precipitation Detection over Land Grant Petty Atmospheric and Oceanic Sciences University of Wisconsin - Madison.

TRMM TMI Rainfall Retrieval Algorithm C. Kummerow Colorado State University 2nd IPWG Meeting Monterey, CA. 25 Oct Towards a parametric algorithm.

Challenges and Strategies for Combined Active/Passive Precipitation Retrievals S. Joseph Munchak 1, W. S. Olson 1,2, M. Grecu 1,3 1: NASA Goddard Space.

Madden/Julian Oscillation: Recent Evolution, Current Status and Forecasts Update prepared by Climate Prediction Center / NCEP April 5, 2005.

The Orbiting Carbon Observatory (OCO) Mission: Retrieval Characterisation and Error Analysis H. Bösch 1, B. Connor 2, B. Sen 1, G. C. Toon 1 1 Jet Propulsion.

Satellites Storm “Since the early 1960s, virtually all areas of the atmospheric sciences have been revolutionized by the development and application of.

1 Spatio-temporal Distribution of Latent Heating in the Southeast Asian Monsoon Region School of Earth and Atmospheric Sciences Georgia Institute of Technology.

An Overview of Satellite Rainfall Estimation for Flash Flood Monitoring Timothy Love NOAA Climate Prediction Center with USAID- FEWS-NET, MFEWS, AFN Presented.

COMPARING HRPP PRODUCTS OVER LARGE SPACE AND TIME SCALES Wesley Berg Department of Atmospheric Science Colorado State University.

A step toward operational use of AMSR-E horizontal polarized radiance in JMA global data assimilation system Masahiro Kazumori Numerical Prediction Division.

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.

A New Ocean Suite Algorithm for AMSR2 David I. Duncan September 16 th, 2015 AMSR Science Team Meeting Huntsville, AL.

Three-Dimensional Water Vapor and Cloud Variations Associated with the MJO during Northern Hemisphere Winter By: David S. Myers and Duane E. Waliser Presented.

Tropical Convection and MJO

GPM Microwave Radiometer Vicarious Cold Calibration

Requirements for microwave inter-calibration

Cloudsat and Drizzle: What can we learn

Characterizing the response of simulated atmospheric boundary layers to stochastic cloud radiative forcing Robert Tardif, Josh Hacker (NCAR Research Applications.

Satellite Foundational Course for JPSS (SatFC-J)

CO2 forcing induces semi-direct effects

Cloudsat and Drizzle: What can we learn

Cloudsat and Drizzle: What can we learn

Front page of the realtime GOES-12 site, showing all of the latest Sounder spectral bands (18 infrared and 1 visible) over the central and Eastern US All.

Climate sensitivity of the CCM3 to horizontal resolution and interannual variability of simulated tropical cyclones J. Tsutsui, K. Nishizawa,H. Kitabata,

Presentation transcript:

The Relation Between SST, Clouds, Precipitation and Wave Structures Across the Equatorial Pacific Anita D. Rapp and Chris Kummerow 14 July 2008 AMSR Science Team Meeting

Motivation Recent studies have shown that warm rain systems in the Tropics may be sensitive to the underlying SST There have been many studies tying cloud feedbacks to SST, but it is also important to understand the relationship between the clouds and precipitation with SST Lau and Wu (2003)

Why are warm rain systems important to the climate system? Warm rain systems are prevalent in the Tropics and contribute to the total tropical rainfall They affect the radiation budget, mostly through their interaction with shortwave radiation –In the absence of other changes, a reduction in warm rain cloud amount would allow more solar radiation to reach the surface Also affect the hydrologic cycle through their moistening of the lower troposphere which preconditions the atmosphere for deep convection –A reduction in the amount of evaporating warm rain clouds could alter the recycling timescales for deep convection

Are these systems responding to SST? Original idea was to look at retrievals from a variety of sensors and algorithms to see how warm rain systems respond to SST. No rain Rain

What to do? Modify microwave optimal estimation algorithm to - 1.Ingest deconvolved microwave Tbs 2.Take into account partially cloud-filled pixels 3.Calculate emission/scattering for raining pixels 30° S – 30° N, 130° E – 170° W Data - TMI brightness temperatures –10,19, 37, 21, 85 GHz Tbs VIRS cloud fraction PR precipitable water and rain height RSS TMI-derived SST

TMI Deconvolution Sharpened coast lines Enhanced cloud scale features Used to place all microwave channels on a common spatial resolution Method utilizes footprint overlap between adjacent pixels Modifies footprint resolution while minimizing error propagation

Establish Convergence Criteria Retrieval (Determine Validity of Retrieval)  Ingest Observed Brightness Temperatures (TBs)  Prior Knowledge of Atmospheric State (Water Vapor, Wind, Cloud Water) Adjust Water Vapor, Wind, Cloud Water Minimize Cost Function: Iterate Basic OE Algorithm Simulate TBs

Modifications to OE Algorithm New inputs - Ingest deconvolved TMI Tbs VIRS cloud fraction calculated within TMI footprint Specify the rain column from PR-derived rain water and rain height TB CLD includes scattering and extinction from calculated from PR rain water VIRS Cloud fraction within TMI footprint Modify cost function -

Results

Sensitivity to Resampling

Sensitivity to Cloud Fraction

Sensitivity to Rain Water

Results w/ SST No rain Rain

One of the most obvious deep convective events in the Tropics is the Madden-Julian Oscillation MJO identified by numerous studies in April – May 2001 Testing Influence on Deep Convective Time Scales Study time series of surface, atmospheric and cloud properties Examine the influence of properties of warm rain systems on lower tropospheric moistening

MJO Case Study Results

Further Testing Influence on Tropospheric Water Vapor From Serra et al. (2006) From Serra & Houze (2002) Examine easterly waves in the Pacific Determine whether the properties of warm rain clouds are correlated with tropospheric moistening

Tropical Disturbance Results

Summary When effects of resolution, partially cloudy pixels, and rainfall are taken into account, visible and microwave sensor retrievals show better agreement Results indicate a change in the behavior of cloud properties from non-raining to raining clouds  LWP changes little with SST for non-raining clouds, but strongly decreases with SST in warm rain clouds Microwave retrieval error diagnostics indicate that deconvolution and cloud fraction information generally improves the retrieval, but very low cloud fraction and rainfall information can influence it in either direction MJO case study suggests that warm rain systems are correlated to moistening in low - mid levels Indicates that behavior of warm rain systems may be tied to recycling timescales of deep convection

Summary and Discussion Easterly wave composites show that properties of non-raining clouds are fairly invariant with passage of wave Easterly wave composites also show that cloud properties associated with warm raining systems are correlated with moistening Need to study more equatorial wave cases to try to cement link between properties of warm rain clouds and lower tropospheric moistening Techniques used in this study could be applied to AMSR-E by combining it with other instruments in the A-Train by using information from MODIS and/or AIRS, CloudSat, and Calipso