论文信息 - Effects of frozen soil on soil temperature, spring infiltration, and runoff: Results from the PILPS 2(d) experiment at Valdai, Russia - 字舞流文

Effects of frozen soil on soil temperature, spring infiltration, and runoff: Results from the PILPS 2(d) experiment at Valdai, Russia

The Project for Intercomparison of Land-Surface Parameterization Schemes phase 2(d) experiment at Valdai, Russia, offers a unique opportunity to evaluate land surface schemes, especially snow and frozen soil parameterizations. Here, the ability of the 21 schemes that participated in the experiment to correctly simulate the thermal and hydrological properties of the soil on several different timescales was examined. Using observed vertical profiles of soil temperature and soil moisture, the impact of frozen soil schemes in the land surface models on the soil temperature and soil moisture simulations was evaluated. It was found that when soil-water freezing is explicitly included in a model, it improves the simulation of soil temperature and its variability at seasonal and interannual scales. Although change of thermal conductivity of the soil also affects soil temperature simulation, this effect is rather weak. The impact of frozen soil on soil moisture is inconclusive in this experiment due to the particular climate at Valdai, where the top 1mo fsoil is very close to saturation during winter and the range for soil moisture changes at the time of snowmelt is very limited. The results also imply that inclusion of explicit snow processes in the models would contribute to substantially improved simulations. More sophisticated snow models based on snow physics tend to produce better snow simulations, especially of snow ablation. Hysteresis of snowcover fraction as a function of snow depth is observed at the catchment but not in any of the models.

R. Dickinson | P. Cox | E. Kowalczyk | A. Pitman | Y. Xue | A. Henderson‐sellers | A. Robock | K. Mitchell | Q. Duan | A. Slater | P. Rosnay | J. Schaake | F. Habets | L. Luo | Yongjiu Dai | Zong‐Liang Yang | T. Smirnova | N. Gedney | J. Noilhan | A. Boone | K. Vinnikov | P. Etchevers | P. Wetzel | Q. Zeng | O. Nasonova | Jinwon Kim | C. Schlosser | A. Shmakin | H. Braden | Ye. M. Gusev | Sellers | N. | Andrew | Robert | Olga | Q. Duan | B. | Slater | Nasonova | Shmakin | C. | M. | Y. | J. | E. | G. | Smirnova | Yevgeniy | Konstantin | Tatiana | Zong | Liang Yang | Dickinson | Andrey | Adam Schlosser | Pitman | Vinnikov | Ann Henderson | Gusev

[1] CLIMATE AND THE OCEAN CIRCULATION’ 1. THE ATMOSPHERIC CIRCULATION AND THE HYDROLOGY OF THE EARTH’S SURFACE , 2004 .

[2] D. Mocko,et al. Simulation of high-latitude hydrological processes in the Torne-Kalix basin: PILPS phase 2(e) - 1: Experiment description and summary intercomparisons , 2003 .

[3] D. Mocko,et al. Simulation of high latitude hydrological processes in the Torne-Kalix basin : PILPS phase 2(e) - 2: Comparison of model results with observations , 2003 .

[4] R. Koster,et al. Simulation of high-latitude hydrological processes in the Torne-Kalix basin: PILPS Phase 2(e) 3: Equivalent model representation and sensitivity experiments , 2003 .

[5] Michael Bruen,et al. Impact of a physically based soil water flow and soil-plant interaction representation for modeling large-scale land surface processes , 2002 .

[6] R. Dickinson,et al. The Representation of Snow in Land Surface Schemes: Results from PILPS 2(d) , 2001 .

[7] Paul J. Valdes,et al. Characterizing GCM land surface schemes to understand their responses to climate change. , 2000 .

[8] Stanley G. Benjamin,et al. Parameterization of cold-season processes in the MAPS land-surface scheme , 2000 .

[9] Zong-Liang Yang,et al. Simulations of a boreal grassland hydrology at Valdai, Russia: PILPS phase 2(d). , 2000 .

[10] Guy W. Prettyman,et al. Environmental Soil Physics , 1999 .

[11] Dennis P. Lettenmaier,et al. Hydrologic effects of frozen soils in the upper Mississippi River basin , 1999 .

[12] A. Pitman,et al. Uncertainty in the simulation of runoff due to the parameterization of frozen soil moisture using the Global Soil Wetness Project methodology , 1999 .

[13] R. Betts,et al. The impact of new land surface physics on the GCM simulation of climate and climate sensitivity , 1999 .

[14] Jared Entin,et al. Evaluation of the AMIP soil moisture simulations , 1998 .

[15] A. Pitman,et al. The BASE land surface model , 1998 .

[16] A. Shmakin. The updated version of SPONSOR land surface scheme: PILPS-influenced improvements , 1998 .

[17] A. Pitman,et al. The validation of a snow parameterization designed for use in general circulation models , 1998 .

[18] R. Dickinson,et al. 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 , 1998 .

[19] Takahiro Kohno,et al. Soil carbon cycling at a black spruce (Picea mariana) forest stand in Saskatchewan, Canada , 1997 .

[20] Darrel L. Williams,et al. BOREAS in 1997: Experiment overview, scientific results, and future directions , 1997 .

[21] Y. Xue,et al. 18-Year Land-Surface Hydrology Model Simulations for a Midlatitude Grassland Catchment in Valdai, Russia , 1997 .

[22] Zeng Qingcun,et al. A land surface model (IAP94) for climate studies part I: Formulation and validation in off-line experiments , 1997 .

[23] Stanley G. Benjamin,et al. Performance of Different Soil Model Configurations in Simulating Ground Surface Temperature and Surface Fluxes , 1997 .

[24] Zong-Liang Yang,et al. Validation of the Snow Submodel of the Biosphere-Atmosphere Transfer Scheme with Russian Snow Cover and Meteorological Observational Data , 1997 .

[25] J. Mahfouf,et al. The ISBA land surface parameterisation scheme , 1996 .

[26] A. Robock,et al. Scales of temporal and spatial variability of midlatitude soil moisture , 1996 .

[27] Jinwon Kim,et al. A simulation of the surface energy budget and soil water content over the Hydrologic Atmospheric Pilot Experiments‐Modélisation du Bilan Hydrique forest site , 1995 .

[28] H. Giordani,et al. The Land Surface Scheme ISBA within the Météo-France Climate Model ARPEGE. Part I. Implementation and Preliminary Results , 1995 .

[29] A. Boone,et al. A Parameterization for Land–Atmosphere-Cloud Exchange (PLACE): Documentation and Testing of a Detailed Process Model of the Partly Cloudy Boundary Layer over Heterogeneous Land , 1995 .

[30] Y. Xue,et al. Use of midlatitude soil moisture and meteorological observations to validate soil moisture simulations with biosphere and bucket models , 1995 .

[31] R. Dickinson,et al. The Project for Intercomparison of Land Surface Parameterization Schemes (PILPS): Phases 2 and 3 , 1993 .

[32] E. Brun,et al. A numerical model to simulate snow-cover stratigraphy for operational avalanche forecasting , 1992, Journal of Glaciology.

[33] D. Verseghy,et al. CLASS-A Canadian Land Surface Scheme for GCMs , 1993 .

[34] Piers J. Sellers,et al. A Simplified Biosphere Model for Global Climate Studies , 1991 .

[35] J. Mitchell,et al. C02 and climate: a missing feedback? , 1989, Nature.

[36] Robert E. Dickinson,et al. The Force–Restore Model for Surface Temperatures and Its Generalizations , 1988 .

[37] J. Mitchell,et al. Summer dryness in northern mid-latitudes due to increased CO2 , 1987, Nature.

[38] Stephen G. Warren,et al. Optical Properties of Snow , 1982 .

[39] S. Warren,et al. A Model for the Spectral Albedo of Snow. II: Snow Containing Atmospheric Aerosols , 1980 .

[40] S. Manabe. CLIMATE AND THE OCEAN CIRCULATION1 , 1969 .

[41] M. Budyko,et al. Heat balance of the Earth , 1964 .

[42] M. Budyko. The heat balance of the earth's surface , 1958 .