共查询到20条相似文献,搜索用时 31 毫秒
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基于陆面模式Noah-MP的不同参数化方案在半干旱区的适用性 总被引:2,自引:2,他引:0
针对陆面模式Noah-MP对兰州大学半干旱气候与环境观测站(SACOL)2009年8月地表热通量模拟值偏差大的问题,通过分析相关物理过程和模拟试验来探究偏差的来源,并确定合适的参数化方案:采用Chen97方案计算感热输送系数可以改善感热通量的模拟;采用Jarvis气孔阻抗方案能增大植被蒸腾,改进模式对潜热通量的模拟效果,同时也使热通量在感热和潜热间的分配比例合理;采用LP92方案可减小土壤蒸发阻抗并有利于土壤蒸发,使得模式对潜热通量的模拟效果变好。不同参数化方案的组合试验表明:同时采用2组或3组新的参数化方案组合可以进一步减小模拟的地表感热和潜热通量的均方根误差,但是土壤湿度和温度的模拟效果并没有同步改善。 相似文献
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Summary We study the response of the land-surface to prescribed atmospheric forcing for 31 May 1978 at Cabauw, Netherlands, using the land-surface scheme from the Coupled Atmospheric boundary layer-Plant-Soil (CAPS) model. Results from model runs show realistic daytime surface fluxes are produced using a canopy conductance formulation derived from Cabauw data (for 1987, a different year), and un-tuned parameterizations of root density (near-uniform with depth) and soil heat flux (reduced thermal conductivity through vegetation). Sensitivity of model-calculated surface heat fluxes to initial values of soil moisture is also examined. Results of this study provide the land-surface base state for a coupled land–atmosphere modeling study. 相似文献
4.
一个陆面过程参数化模式与
MM5的耦合 总被引:10,自引:0,他引:10
在法国陆面过程模式的基础上,为了表示冠层叶片遮挡对水分蒸发阻抗的影响,在植被覆盖部分引入了遮盖因子,然后将这个修正的陆面过程参数化模式耦合到MM5模式中。耦合后的模式模拟出了因为降水造成土壤湿度变化和植被覆盖动态作用对地面通量的影响,而原MM5模式模拟结果则没有反映上述动态变化对地面通量的作用。原MM5模式和耦合模式模拟了1993年8月17日到20日以内蒙古半干旱草原为中心的中尺度区域的气象场,模拟结果和IMGRASS预观测资料进行了对比,对比说明新的陆面过程模式提高了MM5模式对地面通量和边界层各物理量(风、温、湿)的模拟精度。 相似文献
5.
土壤-植被-大气系统水分散失机理的数值模拟 总被引:8,自引:0,他引:8
以Eeardorff(1978)提出的陆面参数化方案和Noilhan等人(1989)土壤水分参数化方案为基础,对陆面物理过程参数化方案进行了改进,在模式中较详细地考虑了植被和地面的各种物理参量如地面和叶面的反射率和发射率,净叶面面积指数,植被的物理阻抗等,并与大气边界层模式耦合。应用该模式模拟了沙漠及绿洲地区不同植被覆盖率情况下的蒸散量、土壤含水量和表面温度的日变化和连续变化特征;对不同植被覆盖率的热量平衡特征进行了比较。结果表明该模式较好地反映了地表蒸散3阶段的变化趋势特征,揭示出下垫面热量平衡分量间的相互转换过程。该模式可以用于中尺度的气象和区域气候模式,模拟和预测不同植被覆盖情况下近地层的热量输送和水分散失情况。 相似文献
6.
J. Sanjay 《Boundary-Layer Meteorology》2008,129(1):159-177
Data collected during the Land Surface Processes Experiment (LASPEX) in a semi-arid region of the state of Gujarat in north-west
India for a clear sky day (16 May 1997) are used to assess the performance of the atmospheric boundary-layer (ABL) and land-
surface parameterizations in the fifth-generation Pennsylvania State University-National Center for Atmospheric Research (PSU-NCAR)
Mesoscale Model (MM5). The ABL turbulence parameterizations examined are the Blackadar scheme coupled to a simple soil slab
model (SSM), and the Troen-Mahrt scheme coupled to SSM or to the more sophisticated Noah land-surface model (NSM). The comparison
of several two-way nested high resolution (9-km) MM5 short term 24-h simulations indicate that, although the model is able
to capture the trend in the observed data, the computed results deviate from observations. The NSM with a modest treatment
of vegetation outperforms the SSM in capturing the observed daily variations in surface heat fluxes and aspects of ABL structure
over the tropical land surface at local scales. Detailed analysis showed that, with the incorporation of observed local vegetation
and soil characteristics, the NSM reproduced a realistic surface energy balance and near-surface temperature. It is further
found that the coupling of the NSM with the Troen-Mahrt ABL scheme leads to excessive ABL mixing and a dry bias in the model
simulations. 相似文献
7.
Mark Reyers Andreas Krüger Christiane Werner Joaquim G. Pinto Stefan Zacharias Michael Kerschgens 《Boundary-Layer Meteorology》2011,139(1):121-141
A mesoscale meteorological model (FOOT3DK) is coupled with a gas exchange model to simulate surface fluxes of CO2 and H2O under field conditions. The gas exchange model consists of a C3 single leaf photosynthesis sub-model and an extended big
leaf (sun/shade) sub-model that divides the canopy into sunlit and shaded fractions. Simulated CO2 fluxes of the stand-alone version of the gas exchange model correspond well to eddy-covariance measurements at a test site
in a rural area in the west of Germany. The coupled FOOT3DK/gas exchange model is validated for the diurnal cycle at singular
grid points, and delivers realistic fluxes with respect to their order of magnitude and to the general daily course. Compared
to the Jarvis-based big leaf scheme, simulations of latent heat fluxes with a photosynthesis-based scheme for stomatal conductance
are more realistic. As expected, flux averages are strongly influenced by the underlying land cover. While the simulated net
ecosystem exchange is highly correlated with leaf area index, this correlation is much weaker for the latent heat flux. Photosynthetic
CO2 uptake is associated with transpirational water loss via the stomata, and the resulting opposing surface fluxes of CO2 and H2O are reproduced with the model approach. Over vegetated surfaces it is shown that the coupling of a photosynthesis-based
gas exchange model with the land-surface scheme of a mesoscale model results in more realistic simulated latent heat fluxes. 相似文献
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9.
Yaping Shao Shaofeng Liu Jan H. Schween Susanne Crewell 《Boundary-Layer Meteorology》2013,148(2):333-356
A model is developed for the large-eddy simulation (LES) of heterogeneous atmosphere and land-surface processes. This couples a LES model with a land-surface scheme. New developments are made to the land-surface scheme to ensure the adequate representation of atmosphere–land-surface transfers on the large-eddy scale. These include, (1) a multi-layer canopy scheme; (2) a method for flux estimates consistent with the large-eddy subgrid closure; and (3) an appropriate soil-layer configuration. The model is then applied to a heterogeneous region with 60-m horizontal resolution and the results are compared with ground-based and airborne measurements. The simulated sensible and latent heat fluxes are found to agree well with the eddy-correlation measurements. Good agreement is also found in the modelled and observed net radiation, ground heat flux, soil temperature and moisture. Based on the model results, we study the patterns of the sensible and latent heat fluxes, how such patterns come into existence, and how large eddies propagate and destroy land-surface signals in the atmosphere. Near the surface, the flux and land-use patterns are found to be closely correlated. In the lower boundary layer, small eddies bearing land-surface signals organize and develop into larger eddies, which carry the signals to considerably higher levels. As a result, the instantaneous flux patterns appear to be unrelated to the land-use patterns, but on average, the correlation between them is significant and persistent up to about 650 m. For a given land-surface type, the scatter of the fluxes amounts to several hundred W $\text{ m }^{-2}$ , due to (1) large-eddy randomness; (2) rapid large-eddy and surface feedback; and (3) local advection related to surface heterogeneity. 相似文献
10.
The land surface processes of the Noah-MP and Noah models are evaluated over four typical landscapes in the Haihe River Basin(HRB) using in-situ observations. The simulated soil temperature and moisture in the two land surface models(LSMs) is consistent with the observation, especially in the rainy season. The models reproduce the mean values and seasonality of the energy fluxes of the croplands, despite the obvious underestimated total evaporation. Noah shows the lower deep soil temperature. The net radiation is well simulated for the diurnal time scale. The daytime latent heat fluxes are always underestimated, while the sensible heat fluxes are overestimated to some degree. Compared with Noah, Noah-MP has improved daily average soil heat flux with diurnal variations. Generally, Noah-MP performs fairly well for different landscapes of the HRB. The simulated cold bias in soil temperature is possibly linked with the parameterized partition of the energy into surface fluxes. Thus, further improvement of these LSMs remains a major challenge. 相似文献
11.
Changhai Liu Jimy Dudhia Mitchell W. Moncrieff 《Meteorology and Atmospheric Physics》2010,107(1-2):9-15
This paper presents a case study of the impact of land surface treatment on warm season precipitation simulations at convection-permitting grid resolution. Two surface schemes are tested: Dudhia’s five-layer soil model (FLSM) and the Noah land-surface model (NLSM). The experimentation case involves a 1-week episode of active summertime convection over the central United States. The overall precipitation features, such as the diurnal regeneration of zonally propagating rainfall episodes and the spatial distribution of accumulative rainfall, are adequately replicated by the two parameterizations. In comparison, NLSM produces roughly 12% more and broader rainfall than FLSM. This differential rainfall amount is consistent with the differential surface moisture fluxes between the two schemes, whereas the precipitation feedback plays a negligible role. It is also found that FLSM generates comparatively stronger sensible heat transports from the land surface and thus a warmer temperature near the surface. 相似文献
12.
Sensitivity study and validation of a land surface parameterization using the HAPEX-MOBILHY data set 总被引:6,自引:0,他引:6
A simple parameterization of land surface processes, amenable to the structure of a two-layer soil model, including a representation of the vegetation, has been designed for use in meteorological models. Prior to implementation in a mesoscale model, it is necessary to check the components and to verify the good working order of the parameterization as a whole. The aims of this paper then are: (i) evaluation and a sensitivity study of the various components of the model, specifying the needed accuracy for the parameters; (ii) micrometeorological validation of the model against the HAPEX-MOBILHY data set.First, we present the basic scheme. The focus is on the parameterization of surface resistance, and especially on its relationship with soil moisture.A sensitivity study is then performed through a set of one-dimensional simulations which allow a full interaction between the ground and the atmosphere. Above bare ground, it is shown that both soil texture and initial moisture greatly influence the outcome of the simulation. Latent heat flux ranges from that associated with potential evaporation through a switch-like behavior to that of dry soil. Next, the effects of transpiring vegetation canopies on the physical processes involved and the surface energy balance are examined. The sensitivity of the latent heat flux to changes in the soil and canopy parameters is emphazised; the major influence of the initial mean soil moisture and of the vegetation cover is pointed out. Finally, the evolution of the boundary layer in response to various surface conditions is studied.A validation of the land surface scheme is conducted through daily cycles during cloudless days. Simulated turbulent fluxes are successfully compared to micrometeorological measurements over a maize field at different growth stages. Over a pine forest, the correct simulation of the turbulent fluxes is obtained with an adequate parameterization of the surface resistance accounting for the atmospheric moisture deficit. 相似文献
13.
Analysis of the variability of canopy resistance over a desert steppe site in Inner Mongolia,China 总被引:1,自引:0,他引:1
ABSTRACT Canopy resistance substantially affects the partitioning of available energy over vegetated surfaces. This study analyzed the variability of canopy resistance and associated driving environmental factors over a desert steppe site in Inner Mongolia, China, through the use of eddy-flux and meteorological data collected from 2008 to 2010. Distinct seasonal and interannual variabilities in canopy resistance were identified within those three years, and these variabilities were controlled primarily by precipitation. Strong interannual variability was found in vapor pressure deficit (VPD), similar to that of air temperature. Based on the principal component regression method, the analysis of the relative contribution of five major environmental factors [soil-water content (SWC), leaf-area index (LAI), photosynthetically active radiation (Kp), VPD, and air temperature] to canopy resistance showed that the canopy-resistance variation was most responsive to SWC (with 〉 35% contribution), followed by LAI, especially for water-stressed soil conditions (〉 20% influence), and VPD (consistently with an influence of approximately 20%). Canopy-resistance variations did not respond to Kp due to the small interannual variability in Kp during the three years. These analyses were used to develop a new exponential function of water stress for the widely used Jarvis scheme, which substantially improved the calculation of canopy resistance and latent heat fluxes, especially for moist and wet soils, and effectively reduced the high bias in evaporation estimated by the original Jarvis scheme. This study highlighted the important control of canopy resistance on plant evaporation and growth for the investigated desert steppe site with a relatively low LA1. 相似文献
14.
J A Marengo J R Miller G L Russell C E Rosenzweig F Abramopoulos 《Climate Dynamics》1994,10(6-7):349-361
This study examines the impact of a new land-surface parameterization and a river routing scheme on the hydrology of the Amazon basin, as depicted by the NASA/Goddard Institute of Space Studies (GISS) global climate model (GCM). The more physically realistic land surface scheme introduces a vegetation canopy resistance and a six-layer soil system. The new routing scheme allows runoff to travel from a river's headwater to its mouth according to topography and other channel characteristics and improves the timing of the peak flow. River runoff is examined near the mouth of the Amazon and for all of its sub-basins. With the new land-surface parameterization, river run-off increases significantly and is consistent with that observed in most basins and at the mouth. The representation of the river hydrology in small basins is not as satisfactory as in larger basins. One positive impact of the new land-surface parameterization is that it produces more realistic evaporation over the Amazon basin, which was too high in the previous version of the GCM. The realistic depiction of evaporation also affects the thermal regime in the lower atmosphere in the Amazon. In fact, the lower evaporation in some portions of the basin reduces the cloudiness, increases the solar radiation reaching the ground, increases the net radiation at the surface, and warms the surface as compared to observations. Further GCM improvement is needed to obtain a better representation of rainfall processes. 相似文献
15.
The Met Office Hadley Centre Unified Model (HadAM3) with the tiled version of the Met Office Surface Exchange Scheme (MOSES2) land surface scheme is used to assess the impact of a comprehensive imposed vegetation annual cycle on global climate and hydrology. Two 25-year numerical experiments are completed: the first with structural vegetation characteristics (Leaf Area Index, LAI, canopy height, canopy water capacity, canopy heat capacity, albedo) held at annual mean values, the second with realistic seasonally varying vegetation characteristics. It is found that the seasonalities of latent heat flux and surface temperature are widely affected. The difference in latent heat flux between experiments is proportional to the difference in LAI. Summer growing season surface temperatures are between 1 and 4 K lower in the phenology experiment over a majority of grid points with a significant vegetation annual cycle. During winter, midlatitude surface temperatures are also cooler due to brighter surface albedo over low LAI surfaces whereas during the dry season in the tropics, characterized by dormant vegetation, surface temperatures are slightly warmer due to reduced transpiration. Precipitation is not as systematically affected as surface temperature by a vegetation annual cycle, but enhanced growing season precipitation rates are seen in regions where the latent heat flux (evaporation) difference is large. Differences between experiments in evapotranspiration, soil moisture storage, the timing of soil thaw, and canopy interception generate regional perturbations to surface and sub-surface runoff annual cycles in the model. 相似文献
16.
William P. Kustas Martha C. Anderson John M. Norman Fuqin Li 《Boundary-Layer Meteorology》2007,122(1):167-187
In many land-surface models using bulk transfer (one-source) approaches, the application of radiometric surface temperature
observations in energy flux computations has given mixed results. This is due in part to the non-unique relationship between
the so-called aerodynamic temperature, which relates to the efficiency of heat exchange between the land surface and overlying
atmosphere, and a surface temperature measurement from a thermal-infrared radiometer, which largely corresponds to a weighted
soil and canopy temperature as a function of radiometer viewing angle. A number of studies over the past several years using
multi-source canopy models and/or experimental data have developed simplified methods to accommodate radiometric–aerodynamic
temperature differences in one-source approaches. A recent investigation related the variability in the radiometric–aerodynamic
relation to solar radiation using experimental data from a variety of landscapes, while another used a multi-source canopy
model combined with measurements over a wide range in vegetation density to derive a relationship based on leaf area index.
In this study, simulations by a detailed multi-source soil–plant–environment model, Cupid, which considers both radiative
and turbulent exchanges across the soil–canopy–air interface, are used to explore the radiometric–aerodynamic temperature
relations for a semi-arid shrubland ecosystem under a range of leaf area/canopy cover, soil moisture and meteorological conditions.
The simulated radiometric-aerodynamic temperatures indicate that, while solar radiation and leaf area both strongly affect
the magnitude of this temperature difference, the relationships are non-unique, having significant variability depending on
local conditions. These simulations also show that soil–canopy temperature differences are highly correlated with variations
in the radiometric–aerodynamic temperature differences, with the slope being primarily a function of leaf area. This result
suggests that two-source schemes with reliable estimates of component soil and canopy temperatures and associated resistances
may be better able to accommodate variability in the radiometric–aerodynamic relation for a wider range in vegetated canopy
cover conditions than is possible with one-source schemes. However, comparisons of sensible heat flux estimates with Cupid
using a simplified two-source model and a one-source model accommodating variability in the radiometric-aerodynamic relation
based on vegetation density gave similar scatter. On the other hand, with experimental data from the shrubland site, the two-source
model generally outperformed the one-source scheme. Clearly, vegetation density/leaf area has a major effect on the radiometric–aerodynamic
temperature relation and must be considered in either one-source or two-source formulations. Hence these adjusted one-source
models require similar inputs as in two-source approaches, but provide as output only bulk heat fluxes; this is not as useful
for monitoring vegetation conditions. 相似文献
17.
基于2001年和2010年中分辨率成像光谱仪MODIS(MODerate-resolution Imaging Spectroradiometer)土地覆盖数据,利用公共陆面模式(Community Land Model, CLM)模拟真实的土地利用/覆盖变化(Land Use/Cover Change, LUCC)对地表能量平衡和水分循环过程的影响。研究表明:1)在2001~2010年,中国LUCC最明显的区域位于干旱半干旱区过渡带、半干旱半湿润区过渡带和南方地区;中国区域荒漠减少0.92%,草地减少0.01%,农田增加0.77%,森林增加2.86%,植被覆盖度整体增加。2)在2001年和2010年两种土地利用/覆盖背景下,LUCC使大部分地区感热通量增加,植被蒸腾、蒸发潜热通量增加,土壤表面蒸发潜热通量减小。3)LUCC使大部分地区地表径流减小;中国西北东部、华北和东北地区土壤湿度减小,其他地区土壤湿度增加,仅干旱半干旱过渡带上的土壤湿度发生了显著变化。4)当典型过渡带区域由荒漠变为草地后,感热通量增加1.11 W m?2,潜热通量增加0.14 W m?2;冠层蒸腾和蒸发分别增加0.039 mm d?1、0.009 mm d?1。土壤湿度平均减小0.01 m3 m?3,且随深度增加变干更明显,这是由于根系吸收了较多深层土壤水分,以满足植被显著增加的蒸腾而产生的结果。当草地变为灌木时,其能量通量和水分循环的变化与上述结果类似。 相似文献
18.
Syed Zahid Husain Stéphane Bélair Jocelyn Mailhot Sylvie Leroyer 《Boundary-Layer Meteorology》2013,147(3):525-551
A new approach to improve the representation of surface processes in the Global Environmental Multiscale (GEM) atmospheric model associated with the exchanges between the urban canopy and the atmosphere is presented. Effects of the urban canopy on the evolution of surface-layer wind, temperature, moisture, and turbulence are directly parametrized in order to allow realistic interactions between the canopy elements (i.e., roofs, roads, and walls) and the atmosphere at GEM’s multiple vertical levels that are positioned inside the canopy. Surface energy budgets as implemented in the Town Energy Balance (TEB) scheme have been used to determine temperatures of the urban canopy elements for the proposed multilayer scheme. Performance of the multilayer scheme is compared against standard implementations of the TEB scheme for one nighttime intensive observation period of the Joint Urban 2003 experiment held in Oklahoma City, USA. Although the new approach is found to have a negligible impact on urban surface-layer wind profiles, it improves the prediction of near-neutral nocturnal profiles of potential temperature close to the surface. The urban heat island effect is simulated with a better accuracy by the multilayer approach. The horizontal temperature gradient across the central business district of the city along the direction of flow is also reasonably well captured by the proposed scheme. 相似文献
19.
A regional climate model simulation over West Africa: parameterization tests and analysis of land-surface fields 总被引:2,自引:2,他引:0
The West African Monsoon has been simulated with the regional climate model PROMES, coupled to the land-surface model ORCHIDEE
and nested in ECMWF analysis, within AMMA-EU project. Three different runs are presented to address the influence of changes
in two parameterizations (moist convection and radiation) on the simulated West African Monsoon. Another aim of the study
is to get an insight into the relationship of simulated precipitation and 2-m temperature with land-surface fluxes. To this
effect, data from the AMMA land-surface model intercomparison project (ALMIP) have been used. In ALMIP, offline simulations
have been made using the same land-surface model than in the coupled simulation presented here, which makes ALMIP data particularly
relevant for the present study, as it enables us to analyse the simulated soil and land-surface fields. The simulation of
the monsoon depends clearly on the two analysed parameterizations. The inclusion of shallow convection parametrization affects
the intensity of the simulated monsoon precipitation and modifies some dynamical aspects of the monsoon. The use of a fractional
cloud-cover parameterization and a more complex radiation scheme is important for better reproducing the amplitude of the
latitudinal displacement of the precipitation band. This is associated to an improved simulation of the surface temperature
field and the easterly jets. However, the parameterization changes do not affect the timing of the main rainy and break periods
of the monsoon. A better representation of downward solar radiation is associated with a smaller bias in the surface heat
fluxes. The comparison with ALMIP land-surface and soil fields shows that precipitation and temperature biases in the regional
climate model simulation are associated to certain biases in land-surface fluxes. The biases in soil moisture seem to be driven
by atmospheric biases as they are strongly affected by the parameterization changes in atmospheric processes. 相似文献
20.
D.L. Verseghy 《大气与海洋》2013,51(3):435-456
Abstract The performance of two Canadian land surface schemes of widely differing complexity is compared and contrasted in a pair of year‐long simulations using the GCM developed at Atmospheric Environment Service, Canada. The old land surface model incorporates the force‐restore method for soil temperatures and the bucket approximation for soil moisture; the new model, CLASS (Canadian Land Surface Scheme) features three soil layers, an explicitly modelled snow layer, a thermally separate vegetation canopy, and physically‐based calculations of heat and moisture transfers between all of the land surface components and the atmosphere. It was reported in previous papers that compared with observations, the old scheme tends to generate a climate which is characterized by anomalously high precipitation rates and cold temperatures over land. In this paper, by reference to field measurements and to the energy fluxes and temperatures generated by the two models at local scales, the hypotheses earlier postulated as to the underlying reasons for this are validated. The main factor contributing to the climate anomalies observed with the old scheme is found to be its generation of excessive evaporation rates; this is caused by the fact that the evaporation rate is never directly energy‐limited, the fact that the scaling of the evaporation rale with decreasing soil moisture content underestimates the effect of vegetation stomatal resistance, and the fact that the evaporation rate over bare soil depends not on the surface soil moisture, but on the moisture content of whole modelled soil column. The cold surface temperatures are additionally attributed to systematic errors incurred by the forward‐stepping temperature scheme, and to the fact that soils subjected to subzero temperature forcing in the winter are modelling as freezing completely. Finally, the inability of the old scheme to simulate partially frozen soils means that it proves unable to handle either shallow frost penetration at temperature latitudes, or the development of an active layer in permafrost. 相似文献