Modeling and Analysis of the Earth’s Hydrologic Cycle Donald R. Johnson Tom H. Zapotocny Todd K. Schaack Allen J. Lenzen Space Science and Engineering.

Slides:

Advertisements

Similar presentations

3) Empirical estimate of surface longwave radiation Use an empirical estimate of the clear-sky surface downward longwave radiation (SDLc) to estimate the.

Advertisements

Links Between Clear-sky Radiation, Water Vapour and the Hydrological Cycle Richard P. Allan 1, Viju O. John 2 1 Environmental Systems Science Centre, University.

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

Spatial and Temporal Variability of GPCP Precipitation Estimates By C. F. Ropelewski Summarized from the generous input Provided by G. Huffman, R. Adler,

Analysis of Eastern Indian Ocean Cold and Warm Events: The air-sea interaction under the Indian monsoon background Qin Zhang RSIS, Climate Prediction Center,

Shortwave Radiation Options in the WRF Model

Seasonal Climate Predictability over NAME Region Jae-Kyung E. Schemm CPC/NCEP/NWS/NOAA NAME Science Working Group Meeting 5 Puerto Vallarta, Mexico Nov.

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

Potential Predictability and Extended Range Prediction of Monsoon ISO’s Prince K. Xavier Centre for Atmospheric and Oceanic Sciences Indian Institute of.

Jiangfeng Wei Center for Ocean-Land-Atmosphere Studies Maryland, USA.

Isentropic Diagnostic Assessments and Modeling Strategies Appropriate to the Development of Weather and Climate Models Donald R. Johnson Emeritus Professor.

CO 2 in the middle troposphere Chang-Yu Ting 1, Mao-Chang Liang 1, Xun Jiang 2, and Yuk L. Yung 3 ¤ Abstract Measurements of CO 2 in the middle troposphere.

Richard P. Allan 1 | Brian J. Soden 2 | Viju O. John 3 | Igor I. Zveryaev 4 Department of Meteorology Click to edit Master title style Water Vapour (%)

Using observations to reduce uncertainties in climate model predictions Maryland Climate Change Workshop Prof. Daniel Kirk-Davidoff.

The importance of clouds. The Global Climate System

Modes of Pacific Climate Variability: ENSO and the PDO Michael Alexander Earth System Research Lab michael.alexander/publications/

THE GLOBAL ATMOSPHERIC HYDROLOGICAL CYCLE: Past, Present and Future (What do we really know and how do we know it?) Phil Arkin, Cooperative Institute for.

The impact of cloud water schemes on seasonal prediction Introduction Clouds are one of the most uncertain components in climate models. The model results.

Potential Predictability of Drought and Pluvial Conditions over the Central United States on Interannual to Decadal Time Scales Siegfried Schubert, Max.

The CrIS Instrument on Suomi-NPP Joel Susskind NASA GSFC Sounder Research Team (SRT) Suomi-NPP Workshop June 21, 2012 Washington, D.C. National Aeronautics.

SHNHCEF EI ind c-5.3±0.24.5±0.1−0.8±0.1 EI dir c-5.4±0.24.8± ±0.2 E40 ind c−5.7±0.34.9±0.3−0.9±0.2 E40 dir c-4.9±0.64.7± ±0.2 FT08−4.9±0.25.1±0.5-

Using GPS data to study the tropical tropopause Bill Randel National Center for Atmospheric Research Boulder, Colorado “You can observe a lot by just watching”

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

Use of CCSM3 and CAM3 Historical Runs: Estimation of Natural and Anthropogenic Climate Variability and Sensitivity Bruce T. Anderson, Boston University.

A Comparison of the Northern American Regional Reanalysis (NARR) to an Ensemble of Analyses Including CFSR Wesley Ebisuzaki 1, Fedor Mesinger 2, Li Zhang.

Slide 1 Impact of GPS-Based Water Vapor Fields on Mesoscale Model Forecasts (5th Symposium on Integrated Observing Systems, Albuquerque, NM) Jonathan L.

Impact Of Surface State Analysis On Estimates Of Long Term Variability Of A Wind Resource Dr. Jim McCaa

Non-hydrostatic Numerical Model Study on Tropical Mesoscale System During SCOUT DARWIN Campaign Wuhu Feng 1 and M.P. Chipperfield 1 IAS, School of Earth.

Modern Era Retrospective-analysis for Research and Applications: Introduction to NASA’s Modern Era Retrospective-analysis for Research and Applications:

11 Predictability of Monsoons in CFS V. Krishnamurthy Center for Ocean-Land-Atmosphere Studies Institute of Global Environment and Society Calverton, MD.

Precipitation source/sink connections between the Amazon and La Plata River basins A Sudradjat*, K L Brubaker**, P A Dirmeyer*** Abstract This study examines.

Introduction 1. Climate – Variations in temperature and precipitation are now predictable with a reasonable accuracy with lead times of up to a year (

1 JRA-55 the Japanese 55-year reanalysis project - status and plan - Climate Prediction Division Japan Meteorological Agency.

Assessing Heating in Climate Models  Top: Atmospheric diabatic heating estimates from the TRMM satellite quantify the response of regional energy budgets.

Figure (a-c). Latitude-height distribution of monthly mean ozone flux for the months of (a) January, (b) April and (c) July averaged over years 2000 to.

Stratosphere and Troposphere Exchange (STE) Above the Tibetan Plateau Wenshou Tian, Min Zhang, Hongying Tian Lanzhou University, Lanzhou, China Martyn.

Incorporation of Stable Water Isotopes in GSM and Spectrum-Nudged 28-year Simulation Kei YOSHIMURA 1,2 1: Scripps Institution of Oceanography, University.

3. Products of the EPS for three-month outlook 1) Outline of the EPS 2) Examples of products 3) Performance of the system.

The European Heat Wave of 2003: A Modeling Study Using the NSIPP-1 AGCM. Global Modeling and Assimilation Office, NASA/GSFC Philip Pegion (1), Siegfried.

Alan Robock Department of Environmental Sciences Rutgers University, New Brunswick, New Jersey USA

Large Eddy Simulation of Low Cloud Feedback to a 2-K SST Increase Anning Cheng 1, and Kuan-Man Xu 2 1. AS&M, Inc., 2. NASA Langley Research Center, Hampton,

Camp et al. (2003) illustrated that two leading modes of tropical total ozone variability exhibit structrures of the QBO and the solar cycle. Figure (1)

The lower boundary condition of the atmosphere, such as SST, soil moisture and snow cover often have a longer memory than weather itself. Land surface.

An Atmosphere-Ocean coupled model Morris, A., Bender and Isaac Ginis, 2000 : Real-case simulations of hurricane-ocean interaction using a high-resolution.

Climate Modeling Research & Applications in Wales John Houghton C 3 W conference, Aberystwyth 26 April 2011.

Fig Decadal averages of the seasonal and annual mean anomalies for (a) temperature at Faraday/Vernadsky, (b) temperature at Marambio, and (c) SAM.

This study compares the Climate System Forecast Reanalysis (CFSR) tropospheric analyses to two ensembles of analyses. The first ensemble consists of 12.

How accurately we can infer isoprene emissions from HCHO column measurements made from space depends mainly on the retrieval errors and uncertainties in.

Assessing the Influence of Decadal Climate Variability and Climate Change on Snowpacks in the Pacific Northwest JISAO/SMA Climate Impacts Group and the.

One-year re-forecast ensembles with CCSM3.0 using initial states for 1 January and 1 July in Model: CCSM3 is a coupled climate model with state-of-the-art.

Of what use is a statistician in climate modeling? Peter Guttorp University of Washington Norwegian Computing Center

© Oxford University Press, All rights reserved. 1 Chapter 3 CHAPTER 3 THE GLOBAL ENERGY SYSTEM.

1 Xiong Liu Harvard-Smithsonian Center for Astrophysics K.V. Chance, C.E. Sioris, R.J.D. Spurr, T.P. Kurosu, R.V. Martin, M.J. Newchurch,

Chemistry-Climate Interaction Studies in Japan Hajime Akimoto Atmospheric Composition Research Program Frontier Research System for Global Change Chemistry.

Impact of OMI data on assimilated ozone Kris Wargan, I. Stajner, M. Sienkiewicz, S. Pawson, L. Froidevaux, N. Livesey, and P. K. Bhartia   Data and approach.

ESSL Holland, CCSM Workshop 0606 Predicting the Earth System Across Scales: Both Ways Summary:Rationale Approach and Current Focus Improved Simulation.

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

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.

Oliver Elison Timm ATM 306 Fall 2016

University Allied Workshop (1-3 July, 2008)

Impact of the vertical resolution on Climate Simulation using CESM

Modeling the Atmos.-Ocean System

Effects of Temperature and Precipitation Variability on Snowpack Trends in the Western U.S. JISAO/SMA Climate Impacts Group and the Department of Civil.

Extratropical stratoshere-troposphere exchange in a 20-km-mesh AGCM

Project Title: The Sensitivity of the Global Water and Energy Cycles:

Predictability and Model Verification of the Water and Energy Cycles:

Case Studies in Decadal Climate Predictability

Understanding and forecasting seasonal-to-decadal climate variations

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

Fig. 1 a) All-India Summer (JJAS) Monsoon rainfall anomalies (% of mean) during The 31-yr sliding mean of the anomalies is shown in.

Presentation transcript:

Modeling and Analysis of the Earth’s Hydrologic Cycle Donald R. Johnson Tom H. Zapotocny Todd K. Schaack Allen J. Lenzen Space Science and Engineering Center, University of Wisconsin – Madison Introduction A. Design of Model Vertical Coordinate Selected References Schaack, T. K., T. H. Zapotocny, A. J. Lenzen and D. R. Johnson, 2004: Global climate simulation with the University of Wisconsin global hybrid isentropic coordinate model. Accepted for publication in Journal of Climate. Johnson, D. R., A. J. Lenzen, T. H. Zapotocny and T. K. Schaack, 2002: Entropy, numerical uncertainties and modeling of atmospheric hydrologic processes: Part B. J. Climate, 15, Johnson, D. R., A. J. Lenzen, T. H. Zapotocny, and T. K. Schaack, 2000: Numerical uncertainties in the simulation of reversible isentropic processes and entropy conservation. J. Climate, 13, Johnson, D. R., 2000: Entropy, the Lorenz Energy Cycle and Climate. In “General Circulation Model Development: Past, Present and Future” (D. A. Randall, ed.), Academic Press, pp Reames, F. M. and T. H. Zapotocny, 1999a: Inert trace constituent transport in sigma and hybrid isentropic-sigma models. Part I: Nine advection algorithms. Mon. Wea. Rev., 127, Reames, F. M. and T. H. Zapotocny, 1999b: Inert trace constituent transport in sigma and hybrid isentropic-sigma models. Part II: Twelve semi-Lagrangian algorithms. Mon. Wea. Rev., 127, Johnson, D. R., 1997: On the "General Coldness of Climate Models" and the Second Law: Implications for Modeling the Earth System. J. Climate, 10, Zapotocny, T. H., A. J. Lenzen, D. R. Johnson, F. M. Reames, and T. K. Schaack, 1997a: A comparison of inert trace constituent transport between the University of Wisconsin isentropic- sigma model and the NCAR community climate model. Mon. Wea. Rev., 125, Zapotocny, T. H., D. R. Johnson, T. K. Schaack, A. J. Lenzen, F. M. Reames, and P. A. Politowicz, 1997b: Simulations of Joint Distributions of Equivalent Potential Temperature and an Inert Trace Constituent in the UW  Model and CCM2. Geophys. Res. Let., 24, Zapotocny, T. H., A. J. Lenzen, D. R. Johnson, F. M. Reames, P. A. Politowicz, and T. K. Schaack, 1996: Joint distributions of potential vorticity and inert trace constituent in CCM2 and UW  model simulations. Geophys. Res. Let., 23, Zapotocny, T. H., D. R. Johnson, and F. M. Reames, 1994: Development and initial test of the University of Wisconsin global isentropic-sigma model. Mon. Wea. Rev., 122, Fig. 1. Schematic of meridional cross sections along 104E for 05 August The red lines represent potential temperature; the black lines represent UW  model surfaces; the green lines represent scaled sigma model surfaces. A key aim of this research is to further understanding of global water vapor and inert trace constituent transport in relation to climate change through analysis of simulations produced by the global University of Wisconsin (UW) hybrid isentropic-sigma coordinate models. Advancing the accuracy of the simulation of water substances, aerosols, chemical constituents, potential vorticity and stratospheric-tropospheric exchange are all critical to DOE’s goal of accurate climate prediction on decadal to centennial time scales and assessing anthropogenic effects. Research has established that simulations of the transport of water vapor, and inert and chemical constituents are remarkably more accurate in hybrid isentropic coordinate models than in corresponding sigma coordinate models. Primary Objectives:  Advance the modeling of climate change by developing an isentropic hybrid model for global and regional climate simulations.  Advance the understanding of physical processes involving water substances and the transport of trace constituents.  Diagnostically examine the limits of global and regional climate predictability imposed by inherent limitations in the simulation of trace constituent transport, hydrologic processes and cloud life-cycles. Key Findings:  The results demonstrate the viability of the UW  model for long term climate integration, numerical weather prediction and chemistry.  The studies document that no insurmountable barriers exist for realistic simulations of the climate state with the hybrid vertical coordinate.  Experiments reported here demonstrate a high degree of numerical accuracy for the UW  model in simulating reversibility and potential vorticity transport over 10 day period that corresponds to the global residence time of water vapor.  The UW hybrid  model simulates seasonally varying and interannual climate scales realistically, including monsoonal circulations associated with El Nino/La Nina events. Fig. 9. Fifteen month record of Anomaly Correlation from the UW  model and NCEP Global Forecast System. Fig. 3. Same as Fig. 2 except for CCM3 running at T42 horizontal resolution. NI Fig. 6. Global distributions of the difference (DJF minus DJF ) between seasonally average precipitation for DJF and DJF (mm/day) from the (A) Xie and Arkin (1997) climatology and (B) UW  model climate simulation. Fig. 7. The distribution of annual vertically averaged heating (10 -1 K/Day) from the last 13 years of a 14 year climate run with UW  model. Fig. 2. The top two panels show zonal cross sections of the difference between  e and trace  e (CI=2 K) from the UW  model at day 10. Panel C shows a bivariate distribution of  e and trace  e at day 10, panel D shows a relative frequency distribution of simulated differences between  e and trace  e at days 2.5, 5, 7.5 and 10, and panel E shows a vertical profile of the differences at day 10. A. UW  model along 24S CI=2 K Fig. 4. Bivariate distributions of ozone and a proxy trace ozone. The “Day 10” distributions from the UW  model, UW  model, and T42 CCM3 are shown in panels (A)-(C) respectively. Fig. 8. The time averaged distributions of precipitation (mm/day) from the 13 year UW  model climate simulation for DJF (A) and JJA (B) and from the Xie and Arkin precipitation climatology for for DJF (C) and JJA (D). Fig. 5. The time averaged mean sea-level pressure distributions from the 13 year UW  model climate simulation for DJF (A) and JJA (B) as well as differences from the NCEP/NCAR reanalysis climatology (UW- NCEP/NCAR) for DJF (C) and JJA (D). Fig 10. The UW hybrid model forms the global component of the RAQMS data assimilation system. Figure B shows tropospheric ozone burden (DU) for June-July 1999 from the RAQMS assimilation while Fig. A is the satellite observed estimate. Table 2. A comparison of annually averaged fields from the 13-year UW  model climate simulation to observed values. Observational estimates are from a summary by Hack et al FieldObserved UW  model All sky OLR (W m -2 ) Clear sky OLR (W m -2 ) Total cloud forcing (W m -2 ) Longwave cloud forcing (W m -2 ) Shortwave cloud forcing (W m -2 ) Total Cloud fraction (%)52.2 to Precipitable water (mm) Precipitation (mm day -1 ) Latent heat flux (W m -2 ) Sensible heat flux (W m -2 ) B. Accuracy Analysis of Transport and Reversibility C. UW  Climate Simulations D. NCEP and NASA Collaborative Studies Table 1. Results from analysis of variance globally for the difference of equivalent potential temperature minus its trace (  e-t  e) and three components at day 10. Units of variance are the square of Kelvin temperature (K 2 ). Quantity in parenthesis is the RMS temperature difference (±K). B. UW  model along 59S CI=2 K A Day 10 UW  B Day 10 UW  C Day 10 CCM3 AB CD A A B The first three columns respectively list the variances of 1) the differences about the area mean difference, 2) area mean differences about the grand mean difference and 3) the variance of the grand mean difference. The last column lists the total variance of the differences.