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1. Comparison and Assessment of Three Advanced Land Surface Models in Simulating Terrestrial Water Storage Components over the United States

Author

Xia, Youlong, Mocko, David, Huang, Maoyi, Li, Bailing, Rodell, Matthew, Mitchell, Kenneth E, Cai, Xitian, and Ek, Michael B

Subjects
Atmospheric Sciences, Meteorology & Atmospheric Sciences
Abstract

To prepare for the next-generation North American Land Data Assimilation System (NLDAS), three advanced land surface models [LSMs; i.e., Community Land Model, version 4.0 (CLM4.0); Noah LSM with multiphysics options (Noah-MP); and Catchment LSM-Fortuna 2.5 (CLSM-F2.5)] were run for the 1979-2014 period within the NLDAS-based framework. Unlike the LSMs currently executing in the operational NLDAS, these three advanced LSMs each include a groundwater component. In this study, the model simulations of monthly terrestrial water storage anomaly (TWSA) and its individual water storage components are evaluated against satellite-based and in situ observations, as well as against reference reanalysis products, at basinwide and statewide scales. The quality of these TWSA simulations will contribute to determining the suitability of these models for the next phase of the NLDAS. Overall, it is found that all three models are able to reasonably capture the monthly and interannual variability and magnitudes of TWSA. However, the relative contributions of the individual water storage components to TWSA are very dependent on the model and basin. A major contributor to the TWSA is the anomaly of total column soil moisture content for CLM4.0 and Noah-MP, while the groundwater storage anomaly is the major contributor for CLSM-F2.5. Other water storage components such as the anomaly of snow water equivalent also play a role in all three models. For each individual water storage component, the models are able to capture broad features such as monthly and interannual variability. However, there are large intermodel differences and quantitative uncertainties, which are motivating follow-on investigations in the NLDAS Science Testbed developed by the NASA and NCEP NLDAS teams.

Published
2017

2. The Project for Intercomparison of Land-surface Parameterization Schemes (PILPS) phase 2(c) Red-Arkansas River basin experiment: 2. Spatial and temporal analysis of energy fluxes

Author

Liang, Xu, Wood, Eric F, Lettenmaier, Dennis P, Lohmann, Dag, Boone, Aaron, Chang, Sam, Chen, Fei, Dai, Yongjiu, Desborough, Carl, Dickinson, Robert E, Duan, Qingyun, Ek, Michael, Gusev, Yeugeniy M, Habets, Florence, Irannejad, Parviz, Koster, Randy, Mitchell, Kenneth E, Nasonova, Olga N, Noilhan, Joel, Schaake, John, Schlosser, Adam, Shao, Yaping, Shmakin, Andrey B, Verseghy, Diana, Warrach, Kirsten, Wetzel, Peter, Xue, Yongkang, Yang, Zong-Liang, and Zeng, Qing-cun

Subjects
PILPS, energy balance, land-surface models, Red-Arkansas River basin, Earth Sciences, Networking & Telecommunications
Abstract

The energy components of sixteen Soil-Vegetation Atmospheric Transfer (SVAT) schemes were analyzed and intercompared using 10 years of surface meteorological and radiative forcing data from the Red-Arkansas River basin in the Southern Great Plains of the United States. Comparisons of simulated surface energy fluxes among models showed that the net radiation and surface temperature generally had the best agreement among the schemes. On an average (annual and monthly) basis, the estimated latent heat fluxes agreed (to within approximate estimation errors) with the latent heat fluxes derived from a radiosonde-based atmospheric budget method for slightly more than half of the schemes. The sensible heat fluxes had larger differences among the schemes than did the latent heat fluxes, and the model-simulated ground heat fluxes had large variations among the schemes. The spatial patterns of the model-computed net radiation and surface temperature were generally similar among the schemes, and appear reasonable and consistent with observations of related variables, such as surface air temperature. The spatial mean patterns of latent and sensible heat fluxes were less similar than for net radiation, and the spatial patterns of the ground heat flux vary greatly among the 16 schemes. Generally, there is less similarity among the models in the temporal (interannual) variability of surface fluxes and temperature than there is in the mean fields, even for schemes with similar mean fields.

Published
1998

3. The Project for Intercomparison of Land-surface Parameterization Schemes (PILPS) phase 2(c) Red–Arkansas River basin experiment: 3. Spatial and temporal analysis of water fluxes

Author

Lohmann, Dag, Lettenmaier, Dennis P, Liang, Xu, Wood, Eric F, Boone, Aaron, Chang, Sam, Chen, Fei, Dai, Yongjiu, Desborough, Carl, Dickinson, Robert E, Duan, Qingyun, Ek, Michael, Gusev, Yeugeniy M, Habets, Florence, Irannejad, Parviz, Koster, Randy, Mitchell, Kenneth E, Nasonova, Olga N, Noilhan, Joel, Schaake, John, Schlosser, Adam, Shao, Yaping, Shmakin, Andrey B, Verseghy, Diana, Warrach, Kirsten, Wetzel, Peter, Xue, Yongkang, Yang, Zong-Liang, and Zeng, Qing-cun

Subjects
PILPS, water balance, routing model, continental river basin modeling, Red-Arkansas River basin, Earth Sciences, Networking & Telecommunications
Abstract

The water-balance components of 16 Soil-Vegetation Atmospheric Transfer (SVAT) schemes were evaluated by comparing predicted and observed streamflow, predicted evapotranspiration and evapotranspiration inferred from an atmospheric moisture budget analysis, and soil moisture storage changes for a seven-year period (1980-1986) using data from the Red-Arkansas River basins of the Southern Great Plains of the USA. The evaluations support the following suggestions: (a) The mean annual runoff of all models follows, at least generally, the strong climatic East-West gradient of precipitation, although most models predict too much runoff in the dry part of the basin. (b) The mean monthly storage change tends to be underestimated, even though all models capture reasonably well the seasonality of the evapotranspiration. (c) The wide range of conceptualizations used for generation of surface and subsurface runoff strongly affect runoff generation on seasonal, and shorter, time scales. Model responses to summer precipitation ranged from almost no summer runoff (one model) to the (more common) situation of persistent overprediction of summer runoff, especially in the driest part of the basin. (d) All models tended to underpredict evapotranspiration in summer and overpredict in winter. (e) Model-derived mean seasonal cycles of changes in soil moisture storage are qualitatively similar to those inferred from observations, but most models do not predict the decrease in April soil moisture storage and the increase in October that is inferred from observations.

Published
1998

9. Adjusting for long-term anomalous trends in NOAA's global vegetation index data sets

Author

Jiang, Le, Tarpley, J. Dan, Mitchell, Kenneth E., Zhou, Sisong, Kogan, Felix N., and Guo, Wei

Subjects
United States. National Oceanic and Atmospheric Administration -- Standards, Remote sensing -- Research, Algorithms -- Usage, Radiometers -- Usage, Environmental indexes -- Evaluation, Algorithm, Business, Earth sciences, Electronics and electrical industries
Abstract

The weekly 0.144[degrees] resolution global vegetation index from the National Oceanic and Atmospheric Administration (NOAA) National Environmental Satellite, Data, and Information Service (NESDIS) has a long history, starting late 1981, and has included data derived from Advanced Very High Resolution Radiometer (AVHRR) sensors onboard NOAA-7, -9, -11, -14, -16, -17, and -18 satellites. Even after postlaunch calibration and mathematical smoothing and filtering of the normalized difference vegetation index (NDVI) derived from AVHRR visible and near-infrared channels, the time series of global smoothed NDVI (SMN) still has apparent discontinuities and biases due to sensor degradation, orbital drift [equator crossing time (ECT)], and differences from instrument to instrument in band response functions. To meet the needs of the operational weather and climate modeling and monitoring community for a stable long-term global NDVI data set, we investigated adjustments to substantially reduce the bias of the weekly global SMN series by simple and efficient algorithms that require a minimum number of assumptions about the statistical properties of the interannual global vegetation changes. Of the algorithms tested, we found the adjusted cumulative distribution function (ACDF) method to be a well-balanced approach that effectively eliminated most of the long-term global-scale interannual trend of AVHRR NDV1. Improvements to the global and regional NDVI data stability have been demonstrated by the results of ACDF-adjusted data set evaluated at a global scale, on major land classes, with relevance to satellite ECT, at major continental regions, and at regional drought detection applications. Index Terms--Advanced Very High Resolution Radiometer (AVHRR), land surface, normalized difference vegetation index (NDVI), remote sensing, satellite-based vegetation, vegetation index.

Published
2008

10. Comparison and Assessment of Three Advanced Land Surface Models in Simulating Terrestrial Water Storage Components over the United States.

Author

YOULONG XIA, MOCKO, DAVID, HUANG, MAOYI, BAILING LI, RODELL, MATTHEW, MITCHELL, KENNETH E., XITIAN CAI, and EK, MICHAEL B.

Subjects
WATER storage, GROUNDWATER, RUNOFF analysis, SNOW, SOIL moisture
Abstract

To prepare for the next-generation North American Land Data Assimilation System (NLDAS), three advanced land surface models [LSMs; i.e., Community Land Model, version 4.0 (CLM4.0); Noah LSM with multiphysics options (Noah-MP); and Catchment LSM-Fortuna 2.5 (CLSM-F2.5)] were run for the 1979-2014 period within the NLDAS-based framework. Unlike the LSMs currently executing in the operational NLDAS, these three advanced LSMs each include a groundwater component. In this study, the model simulations of monthly terrestrial water storage anomaly (TWSA) and its individual water storage components are evaluated against satellite-based and in situ observations, as well as against reference reanalysis products, at basinwide and statewide scales. The quality of these TWSA simulations will contribute to determining the suitability of these models for the next phase of the NLDAS. Overall, it is found that all three models are able to reasonably capture the monthly and interannual variability and magnitudes of TWSA. However, the relative contributions of the individual water storage components to TWSA are very dependent on the model and basin. A major contributor to the TWSA is the anomaly of total column soil moisture content for CLM4.0 and Noah-MP, while the groundwater storage anomaly is the major contributor for CLSM-F2.5. Other water storage components such as the anomaly of snow water equivalent also play a role in all three models. For each individual water storage component, the models are able to capture broad features such as monthly and interannual variability. However, there are large intermodel differences and quantitative uncertainties, which are motivating follow-on investigations in the NLDASScience Testbed developed by the NASA and NCEP NLDAS teams. [ABSTRACT FROM AUTHOR]

Published
2017
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11. The community Noah land surface model with multiparameterization options (Noah-MP): 1. Model description and evaluation with local-scale measurements

Author

Niu, Guo-Yue, Yang, Zong-Liang, Mitchell, Kenneth E., Chen, Fei, Ek, Michael B., Barlage, Michael, Kumar, Anil, Manning, Kevin, Niyogi, Dev, Rosero, Enrique, Tewari, Mukul, Xia, Youlong, Niu, Guo-Yue, Yang, Zong-Liang, Mitchell, Kenneth E., Chen, Fei, Ek, Michael B., Barlage, Michael, Kumar, Anil, Manning, Kevin, Niyogi, Dev, Rosero, Enrique, Tewari, Mukul, and Xia, Youlong

Abstract

This first paper of the two-part series describes the objectives of the community efforts in improving the Noah land surface model (LSM), documents, through mathematical formulations, the augmented conceptual realism in biophysical and hydrological processes, and introduces a framework for multiple options to parameterize selected processes (Noah-MP). The Noah-MP's performance is evaluated at various local sites using high temporal frequency data sets, and results show the advantages of using multiple optional schemes to interpret the differences in modeling simulations. The second paper focuses on ensemble evaluations with long-term regional (basin) and global scale data sets. The enhanced conceptual realism includes (1) the vegetation canopy energy balance, (2) the layered snowpack, (3) frozen soil and infiltration, (4) soil moisture-groundwater interaction and related runoff production, and (5) vegetation phenology. Sample local-scale validations are conducted over the First International Satellite Land Surface Climatology Project (ISLSCP) Field Experiment (FIFE) site, the W3 catchment of Sleepers River, Vermont, and a French snow observation site. Noah-MP shows apparent improvements in reproducing surface fluxes, skin temperature over dry periods, snow water equivalent (SWE), snow depth, and runoff over Noah LSM version 3.0. Noah-MP improves the SWE simulations due to more accurate simulations of the diurnal variations of the snow skin temperature, which is critical for computing available energy for melting. Noah-MP also improves the simulation of runoff peaks and timing by introducing a more permeable frozen soil and more accurate simulation of snowmelt. We also demonstrate that Noah-MP is an effective research tool by which modeling results for a given process can be interpreted through multiple optional parameterization schemes in the same model framework. Copyright © 2011 by the American Geophysical Union.

Published
2011

12. Estimation of the minimum canopy resistance for croplands and grasslands using data from the 2002 international H2O project

Author

Alfieri, Joseph G., Niyogi, Dev, Blanken, Peter D., Chen, Fei, LeMone, Margaret A., Mitchell, Kenneth E., Ek, Michael B., Kumar, Anil, Alfieri, Joseph G., Niyogi, Dev, Blanken, Peter D., Chen, Fei, LeMone, Margaret A., Mitchell, Kenneth E., Ek, Michael B., and Kumar, Anil

Abstract

Vegetated surfaces, such as grasslands and croplands, constitute a significant portion of the earth's surface and play an important role in land-atmosphere exchange processes. This study focuses on one important parameter used in describing the exchange of moisture from vegetated surfaces: the minimum canopy resistance (rcmin). This parameter is used in the Jarvis canopy resistance scheme that is incorporated into the Noah and many other land surface models. By using an inverted form of the Jarvis scheme, rcmin is determined from observational data collected during the 2002 International H2O Project (IHOP_2002). The results indicate that rcmin is highly variable both site to site and over diurnal and longer time scales. The mean value at the grassland sites in this study is 96 s m-1 while the mean value for the cropland (winter wheat) sites is one-fourth that value at 24 s m-1. The mean rcmin for all the sites is 72 s m-1 with a standard deviation of 39 s m-1. This variability is due to both the empirical nature of the Jarvis scheme and a combination of changing environmental conditions, such as plant physiology and plant species composition, that are not explicitly considered by the scheme. This variability in rcmin. has important implications for land surface modeling where rcmin is often parameterized as a constant. For example, the Noah land surface model parameterizes rcmin for the grasslands and croplands types in this study as 40 s m-1. Tests with the coupled Weather Research and Forecasting (WRF)-Noah model indicate that the using the modified values of rcmin from this study improves the estimates of latent heat flux; the difference between the observed and modeled moisture flux decreased by 50% or more. While land surface models that estimate transpiration using Jarvis-type relationships may be improved by revising the rcmin values for grasslands and croplands, updating the rcmin will not fully account for the variability in rcmin observed in this study. As

Published
2008

16. Assessment of the land surface and boundary layer models in two operational versions of the NCEP Eta Model using FIFE data

Author

Betts, Alan K., Chen, Fei, Mitchell, Kenneth E., Janjić, Zaviša I., Betts, Alan K., Chen, Fei, Mitchell, Kenneth E., and Janjić, Zaviša I.

Abstract

Data from the 1987 summer FIFE experiment for four pairs of days are compared with corresponding 48·h forecasts from two different versions of the Eta Model, both initialized from the NCEP-NCAR (National Centers for Environmental Prediction-National Center for Atmospheric Research) global reanalysis. One used the late 1995 operational Eta Model physics, the second, with a new soil and land surface scheme and revisions to the surface layer and boundary layer schemes, used the physics package that became operational on 31 January 1996. Improvements in the land surface parameterization and its interaction with the atmosphere are one key to improved summer precipitation forecasts. The new soil thermal model is an improvement over the earlier slab soil model, although the new skin temperature generally now has too large a diurnal cycle (whereas the old surface temperature had too small a diurnal cycle) and is more sensitive to net radiation errors. The nighttime temperature minima are often too low, because of a model underestimate of the downwelling radiation, despite improvements in the coupling of the surface and boundary layer at night. The daytime incoming solar radiation has a substantial high bias in both models, because of some coding errors (which have now been corrected), insufficient atmospheric shortwave absorption, and underestimates of cloud. The authors explore evaporation before and after a midsummer heavy rain event with the two models. The late 1995 operational model uses a soil moisture bucket physics, with a specified annual-mean fixed field soil moisture climatology, to the surface evaporation responds primarily to the atmospheric forcing. While the surface fluxes in the new model show this strong rain event more dramatically, because its soil moisture comes from the global reanalysis rather than climatology, there remain problems with soil moisture initialization. It appears that a fully continuous Eta data assimilation system (wihch is under develo

Published
1997

20. Changes to NMC's Regional Analysis and Forecast System

Author

DiMego, Geoffrey J., primary, Mitchell, Kenneth E., additional, Petersen, Ralph A., additional, Hoke, James E., additional, Gerrity, Joseph P., additional, Tuccillo, James J., additional, Wobus, Richard L., additional, and Juang, Hann-Ming H., additional

Published
1992
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21. Changes to NMC's Regional Analysis and Forecast System

Author

Petersen, Ralph A., primary, DiMego, Geoffrey J., additional, Hoke, James E., additional, Mitchell, Kenneth E., additional, Gerrity, Joseph P., additional, Wobus, Richard L., additional, Juang, Hann-Ming H., additional, and Pecnick, Michael J., additional

Published
1991
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22. Adjusting for Long-Term Anomalous Trends in NOAA's Global Vegetation Index Data Sets.

Author

Le Jiang, Tarpley, J. Dan, Mitchell, Kenneth E., Sisong Zhou, Kogan, Felix N., and Wei Guo

Subjects
EMISSIVITY, RADIOMETERS, ADVANCED very high resolution radiometers, ARTIFICIAL satellites, RADIATION, REMOTE sensing, THERMOGRAPHY, INFRARED photography, EARTH sciences
Abstract

The weekly 0.144° resolution global vegetation index from the National Oceanic and Atmospheric Administration (NOAA) National Environmental Satellite, Data, and Information Service (NESDIS) has a long history, starting late 1981, and has included data derived from Advanced Very High Resolution Radiometer (AVHRR) sensors onboard NOAA-7, -9, -11, -14, -16, -17, and -18 satellites. Even after postlaunch calibration and mathematical smoothing and filtering of the normalized difference vegetation index (NDVI) derived from AVHRR visible and near-infrared channels, the time series of global smoothed NDVI (SMN) still has apparent discontinuities and biases due to sensor degradation, orbital drift [equator crossing time (ECT)], and differences from instrument to instrument in band response functions. To meet the needs of the operational weather and climate modeling and monitoring community for a stable long-term global NDVI data set, we investigated adjustments to substantially reduce the bias of the weekly global SMN series by simple and efficient algorithms that require a minimum number of assumptions about the statistical properties of the interannual global vegetation changes. Of the algorithms tested, we found the adjusted cumulative distribution function (ACDF) method to be a well-balanced approach that effectively eliminated most of the long-term global-scale interannual trend of AVHRR NDVI. Improvements to the global and regional NDVI data stability have been demonstrated by the results of ACDF-adjusted data set evaluated at a global scale, on major land classes, with relevance to satellite ECT, at major continental regions, and at regional drought detection applications. [ABSTRACT FROM AUTHOR]

Published
2008
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23. Assessment of Dynamic Downscaling of the Continental U.S. Regional Climate Using the Eta/SSiB Regional Climate Model.

Author

Yongkang Xue, Vasic, Ratko, Janjic, Zavisa, Mesinger, Fedor, and Mitchell, Kenneth E.

Subjects
CLIMATOLOGY, METEOROLOGICAL precipitation, WEATHER, PRECIPITATION anomalies, SIMULATION methods & models, SPECTRUM analysis, ATMOSPHERIC waves
Abstract

This study investigates the capability of the dynamic downscaling method (DDM) in a North American regional climate study using the Eta/Simplified Simple Biosphere (SSiB) Regional Climate Model (RCM). The main objective is to understand whether the Eta/SSiB RCM is capable of simulating North American regional climate features, mainly precipitation, at different scales under imposed boundary conditions. The summer of 1998 was selected for this study and the summers of 1993 and 1995 were used to confirm the 1998 results. The observed precipitation, NCEP–NCAR Global Reanalysis (NNGR), and North American Regional Reanalysis (NARR) were used for evaluation of the model’s simulations and/or as lateral boundary conditions (LBCs). A spectral analysis was applied to quantitatively examine the RCM’s downscaling ability at different scales. The simulations indicated that choice of domain size, LBCs, and grid spacing were crucial for the DDM. Several tests with different domain sizes indicated that the model in the North American climate simulation was particularly sensitive to its southern boundary position because of the importance of moisture transport by the southerly low-level jet (LLJ) in summer precipitation. Among these tests, only the RCM with 32-km resolution and NNGR LBC or with 80-km resolution and NARR LBC, in conjunction with appropriate domain sizes, was able to properly simulate precipitation and other atmospheric variables—especially humidity over the southeastern United States—during all three summer months—and produce a better spectral power distribution than that associated with the imposed LBC (for the 32-km case) and retain spectral power for large wavelengths (for the 80-km case). The analysis suggests that there might be strong atmospheric components of high-frequency variability over the Gulf of Mexico and the southeastern United States. [ABSTRACT FROM AUTHOR]

Published
2007
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24. The Operational Eta Model Precipitation and Surface Hydrologic Cycle of the Columbia and Colorado Basins.

Author

Yan Luo, Berbery, Ernesto H., and Mitchell, Kenneth E.

Subjects
METEOROLOGICAL precipitation, HYDROLOGIC cycle, RUNOFF, WEATHER forecasting, HYDROLOGIC models, HYDROMETEOROLOGY
Abstract

The surface hydrology of the United States’ western basins is investigated using the National Centers for Environmental Prediction operational Eta Model forecasts. During recent years the model has been subject to changes and upgrades that positively affected its performance. These effects on the surface hydrologic cycle are discussed by analyzing the period June 1995–May 2003. Prior to the model assessment, three gauge-based precipitation analyses that are potential sources of model validation are appraised. A fairly large disparity between the gridded precipitation analyses is found in the long-term area averages over the Columbia basin (∼23% difference) and over the Colorado basin (∼12% difference). These discrepancies are due to the type of analysis scheme employed and whether an orographic correction was applied. The basin-averaged Eta Model precipitation forecasts correlate well with the observations at monthly time scales and, after 1999, show a small bias. Over the Columbia basin, the model precipitation bias is typically positive. This bias is significantly smaller with respect to orographically corrected precipitation analyses, indicating that the model’s large-scale precipitation processes respond reasonably well to orographic effects, though manifesting a higher bias during the cool season. Over the Colorado basin, the model precipitation bias is typically negative, and notably more so with respect to 1) the orographically corrected precipitation analyses and 2) the warm season, indicating shortfalls in the convection scheme over arid high mountains. The mean fields of the hydrological variables in the Eta Model are in qualitative agreement with those from the Variable Infiltration Capacity (VIC) macroscale hydrologic model at regional-to-large scales. As expected, the largest differences are found near mountains and the western coastline. While the mean fields of precipitation, evaporation, runoff, and normalized soil moisture are in general agreement, important differences arise in their mean annual cycle over the two basins: snowmelt in the Eta Model precedes that of VIC by 2 months, and this phase shift is also reflected in the other variables. In the last 3–4 yr of the study period, notable improvements are evident in the quality of the model’s precipitation forecast and in the reduction of the residual term of the surface water balance, suggesting that at least similar (or better) quality will be found in studies based on NCEP’s recently completed Eta Model–based North American regional reanalysis. [ABSTRACT FROM AUTHOR]

Published
2005
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25. Evaluation of Soil Moisture in the NCEP–NCAR and NCEP–DOE Global Reanalyses.

Author

Cheng-Hsuan Lu, Kanamitsu, Masao, Roads, John O., Ebisuzaki, Wesley, Mitchell, Kenneth E., and Lohmann, Dag

Subjects
SOIL moisture, ATMOSPHERIC models, ATMOSPHERIC research, HYDROMETEOROLOGY
Abstract

This study compares soil moisture analyses from the National Centers for Environmental Prediction–National Center for Atmospheric Research (NCEP–NCAR) global reanalysis (R-1) and the later NCEP– Department of Energy (DOE) Atmospheric Model Intercomparison Project (AMIP) global reanalysis (R-2). The R-1 soil moisture is strongly controlled by nudging it to a prescribed climatology, whereas the R-2 soil moisture is adjusted according to differences between model-generated and observed precipitation. While mean soil moisture fields from R-1 and R-2 show many geographic similarities, there are some major differences. This study uses in situ observations from the Global Soil Moisture Data Bank to evaluate the two global reanalysis products. In general, R-2 does a better job of simulating interannual variations, the mean seasonal cycle, and the persistence of soil moisture, when compared to observations. However, the R-2 reanalysis does not necessarily represent observed soil moisture characteristics well in all aspects. Sometimes R-1 provides a better soil moisture analysis on monthly time scales, which is likely a consequence of the deficiencies in the R-2 surface water balance. [ABSTRACT FROM AUTHOR]

Published
2005
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26. Development of a Cloud Forecast Scheme for the GL Baseline Global Spectral Model

Author

AIR FORCE SYSTEMS COMMAND HANSCOM AFB MA GEOPHYSICS LAB, Mitchell, Kenneth E., Hahn, Douglas C., AIR FORCE SYSTEMS COMMAND HANSCOM AFB MA GEOPHYSICS LAB, Mitchell, Kenneth E., and Hahn, Douglas C.

Abstract

Using forecast relative humidity (RH) from a global model, several pre-existing diagnostic RH-to-cloud schemes were tested to forecast global fractional cloud cover in a postprocessor format. Since none of the schemes tested provided a superior cloud forecast when compared to Air Force Global Weather Central's (AFGWC) operational 5LAYER cloud forecasts, a new RH-to-cloud scheme was developed by relating cumulative frequencies of forecast RH to cumulative frequencies of analyzed cloud cover from the AFGWC RTNEPH cloud analysis. This scheme creates a series of forecast time dependent RH-to-cloud curves that can be temporally updated to account for changes in season, cloud analysis, or forecast model, The global model used was a spectral-type developed by the Geophysics Laboratory (GL) using parameterized diabatic physics presently incorporated in the operational GSM (global spectral model) at AFGWC.

Published
1989

27. Diagnostics for and Evaluations of New Physical Parameterization Schemes for Global NWP Models.

Author

GEOPHYSICS LAB (AFSC) HANSCOM AFB MA, Yang, Chien-Hsiung, Mitchell, Kenneth E., Norquist, Donald C., Yee, Samuel Y., GEOPHYSICS LAB (AFSC) HANSCOM AFB MA, Yang, Chien-Hsiung, Mitchell, Kenneth E., Norquist, Donald C., and Yee, Samuel Y.

Abstract

The procedures and results of a study undertaken to evaluate and assess the impacts of three new parameterization schemes for the GL global spectral model as a 3-4 day range forecast model are described. The tree parameterization schemes are one each for the boundary-layer physics, moist convection and heating due to solar and terrestrial radiations. These schemes are incorporated either singly or jointly into a rhomboidal-30, 12-layer global spectral model for four-day simulations using FGGE III- a data as input. Evaluation and assessment are made on the basis of two kinds of global statistics: mean and root-mean-square errors, and on their magnitudes and distributions. The statistics are generated for both the primary, that is, prognostic, variables, and supplementary variables such as zonal-mean and zonal-eddies energy densities. The new moist convection scheme has been found to increase convective activity significantly and maintain it throughout the four-day period. It also warms and dries the middle troposphere, but produces rainfall far in excess of the climatology. The radiation parameterization has been found to cool the atmosphere and reduce its specific humidity. It counterbalances enhanced heating and moistening brought about by the new boundary-layer and moist convection schemes and eliminates the systematic warming of the old model.

Published
1989

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