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Your search keyword '"Lijuan WEN"' showing total 7 results
Start Over Author "Lijuan WEN" Publisher american geophysical union (agu)
7 results on '"Lijuan WEN"'

3. Ice‐Covered Lakes of Tibetan Plateau as Solar Heat Collectors

Author

Tom Shatwell, Georgiy Kirillin, and Lijuan Wen

Subjects
geography, Geophysics, Plateau, geography.geographical_feature_category, Thermal, Solar heat, General Earth and Planetary Sciences, Lake ice, Atmospheric sciences, Geology
Abstract

The Qinghai-Tibet Plateau possesses the largest alpine lake system, which plays a crucial role in the land-atmosphere interaction. We report first observations on the thermal and radiation regime u...

Published
2021
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4. Effects of the Largest Lake of the Tibetan Plateau on the Regional Climate

Author

Xingyu Song, Lijuan Wen, Georgiy Kirillin, Dongsheng Su, Qianqian Shi, Matti Leppäranta, Xiaoqing Gao, and Institute for Atmospheric and Earth System Research (INAR)

Subjects
1171 Geosciences, Atmospheric Science, QINGHAI LAKE, 010504 meteorology & atmospheric sciences, IMPACT, 0207 environmental engineering, 02 engineering and technology, 01 natural sciences, VALIDATION, parasitic diseases, Earth and Planetary Sciences (miscellaneous), Qinghai lake, LAURENTIAN GREAT-LAKES, 020701 environmental engineering, Shallow lake, ICE COVER, TEMPERATURE, 0105 earth and related environmental sciences, geography, Plateau, geography.geographical_feature_category, EFFECT PRECIPITATION, 15. Life on land, MODEL, SHALLOW LAKE, Geophysics, CONVECTION, 13. Climate action, Space and Planetary Science, Environmental science, Physical geography
Abstract

Qinghai Lake is the largest lake in China. However, its influence on the local climate remains poorly understood. By using an atmosphere-lake coupled model, we investigated the impact of the lake on the local climate. After the adjustment of four key parameters, the model reasonably reproduced the lake-air interaction. Superimposed by the orographic effects on lake-land breeze circulation, the presence of the lake enhanced precipitation over the southern part of the lake and its adjacent land, while slightly reduced precipitation along the northern shore of the lake. The lake effect on local precipitation revealed a distinct seasonal and diurnal variability, reducing precipitation in May (-6.6%) and June (-4.5%) and increasing it from July (5.7%) to November (125.6%). During the open water season, the lake's daytime cooling effect weakened and the nighttime warming effect strengthened, affecting spatial distribution and intensity of lake-induced precipitation. In early summer, precipitation slightly decreased over the north part of the lake due to the lake's daytime cooling. In turn, lake-induced nighttime warming increased precipitation over the southern section of the lake and its adjacent land. With the start of the autumn cooling in September, heat and moisture fluxes from the lake resulted in precipitation increase in both daytime and nighttime over the entire lake. In October, the background atmospheric circulation coupled with the strong lake effects lead to a small amount but high proportion of lake-induced precipitation spreading evenly over the lake.

Published
2020
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5. Evaluation of snowmelt simulation in the Weather Research and Forecasting model

Author

Lijuan Wen and Jiming Jin

Subjects
Rapid update cycle, Atmospheric Science, Ecology, Meteorology, Paleontology, Soil Science, Forestry, Vegetation, Aquatic Science, Oceanography, Snow, Water resources, Geophysics, Space and Planetary Science, Geochemistry and Petrology, SNOTEL, Climatology, Weather Research and Forecasting Model, Snowmelt, Earth and Planetary Sciences (miscellaneous), Precipitation, Earth-Surface Processes, Water Science and Technology
Abstract

[1] The objective of this study is to better understand and improve snowmelt simulations in the advanced Weather Research and Forecasting (WRF) model by coupling it with the Community Land Model (CLM) Version 3.5. Both WRF and CLM are developed by the National Center for Atmospheric Research. The automated Snow Telemetry (SNOTEL) station data over the Columbia River Basin in the northwestern United States are used to evaluate snowmelt simulations generated with the coupled WRF-CLM model. These SNOTEL data include snow water equivalent (SWE), precipitation, and temperature. The simulations cover the period of March through June 2002 and focus mostly on the snowmelt season. Initial results show that when compared to observations, WRF-CLM significantly improves the simulations of SWE, which is underestimated when the release version of WRF is coupled with the Noah and Rapid Update Cycle (RUC) land surface schemes, in which snow physics is oversimplified. Further analysis shows that more realistic snow surface energy allocation in CLM is an important process that results in improved snowmelt simulations when compared to that in Noah and RUC. Additional simulations with WRF-CLM at different horizontal spatial resolutions indicate that accurate description of topography is also vital to SWE simulations. WRF-CLM at 10 km resolution produces the most realistic SWE simulations when compared to those produced with coarser spatial resolutions in which SWE is remarkably underestimated. The coupled WRF-CLM provides an important tool for research and forecasts in weather, climate, and water resources at regional scales.

Published
2012
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6. Modeling seasonal snowpack evolution in the complex terrain and forested Colorado Headwaters region: A model intercomparison study

Author

Roy Rasmussen, Lijuan Wen, Mukul Tewari, Jiming Jin, Michael Barlage, Gonzalo Miguez-Macho, C. S. Lin, Guo Yue Niu, Fei Chen, Dennis P. Lettenmaier, Ben Livneh, and Zong-Liang Yang

Subjects
Atmospheric Science, Meteorology, Terrain, Snowpack, Snow, Atmospheric sciences, Radiative flux, Geophysics, Space and Planetary Science, SNOTEL, Snowmelt, Earth and Planetary Sciences (miscellaneous), Environmental science, Climate model, Meltwater
Abstract

Correctly modeling snow is critical for climate models and for hydrologic applications. Snowpack simulated by six land surface models (LSM: Noah, Variable Infiltration Capacity, snow-atmosphere-soil transfer, Land Ecosystem-Atmosphere Feedback, Noah with Multiparameterization, and Community Land Model) were evaluated against 1 year snow water equivalent (SWE) data at 112 Snow Telemetry (SNOTEL) sites in the Colorado River Headwaters region and 4 year flux tower data at two AmeriFlux sites. All models captured the main characteristics of the seasonal SWE evolution fairly well at 112 SNOTEL sites. No single model performed the best to capture the combined features of the peak SWE, the timing of peak SWE, and the length of snow season. Evaluating only simulated SWE is deceiving and does not reveal critical deficiencies in models, because the models could produce similar SWE for starkly different reasons. Sensitivity experiments revealed that the models responded differently to variations of forest coverage. The treatment of snow albedo and its cascading effects on surface energy deficit, surface temperature, stability correction, and turbulent fluxes was a major intermodel discrepancy. Six LSMs substantially overestimated (underestimated) radiative flux (heat flux), a crucial deficiency in representing winter land-atmosphere feedback in coupled weather and climate models. Results showed significant intermodel differences in snowmelt efficiency and sublimation efficiency, and models with high rate of snow accumulation and melt were able to reproduce the observed seasonal evolution of SWE. This study highlights that the parameterization of cascading effects of snow albedo and below-canopy turbulence and radiation transfer is critical not only for SWE simulation but also for correctly capturing the winter land-atmosphere interactions.

Published
2014
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7. Numerical simulations of the atmospheric and land conditions over the Jinta oasis in northwestern China with satellite-derived land surface parameters

Author

Siqiong Luo, Yan Bao, Yuanpu Liu, Yanhong Gao, Xianhong Meng, Tangtang Zhang, Jiixin Guo, Shihua Lu, and Lijuan Wen

Subjects
Atmospheric Science, Ecology, Land use, Meteorology, Paleontology, Soil Science, Forestry, Vegetation, Land cover, Aquatic Science, Oceanography, Energy budget, Atmosphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, MM5, Satellite, Moderate-resolution imaging spectroradiometer, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Mesoscale meteorological modeling is an important tool to help understand the energy budget of the oasis, while some of its initial field data are rough limited to describe the atmosphere and land conditions over a small oasis. Local factors including land surface parameters and their interaction with the atmosphere play a dominant role in the local circulation. Therefore, in this study, land surface parameters such as land-use types, vegetation cover fraction, and surface layer soil moisture are derived by satellite remote sensing data from EOS Moderate Resolution Imaging Spectroradiometer (EOS/MODIS), and soil moisture at 10 cm and 200 cm depth are obtained by combining surface layer soil moisture with experiential statistics. Then the parameters are used to specify the respective options in the MM5 model. Comparison with the observations shows that the modeling including satellite values leads to improved meteorological simulations in the Jinta oasis, both for the oasis effect and the local wind circulation, especially for description of the inhomogeneous characteristics over the oasis. Replacing values in the initial field with data obtained from remote sensing removes the number of unknowns in the model and increases the accuracy of the energy budget. This work is a very valuable addition to current numerical research on local circumfluence over the oasis areas.

Published
2009
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