陆面模式CLM4.5对青藏高原高寒草甸地表能量交换模拟性能的评估

利用中国科学院那曲高寒气候环境观测研究站2013年9月1日至2014年8月31日一个完整年的观测资料,对陆面过程模式CLM4.5在青藏高原(下称高原)高寒草甸下垫面地表能量交换的模拟性能进行了评估。模拟结果表明,CLM4.5能够较好的模拟高原春季、夏季和秋季非冻结期地面长波、反射辐射和地表净辐射、感热和潜热通量以及地表土壤热通量等的季节变化和日循环特征。但对冬季冻结期地表温度的模拟偏低,导致模拟与观测的感热反相,对地面反射辐射模拟偏大。截断冬季降水的敏感性试验进一步指出,模式冬季反射辐射偏大主要是由于积雪引起的地表反照率偏高造成,进而造成地表温度以及感热通量的模拟偏低。因此,高原积雪参数化方案以及与积雪相关的反照率参数化方案还需进一步改进和完善。     

基于自动站资料的WRF-EnSRF陆面同化系统的效果检验及应用

基于集合平方根滤波方法(En SRF)同化方法和NOAH陆面模式的WRF-En SRF陆面同化系统,同化了江苏省70个自动站资料进行试验,研究加入不同的同化资料(地表温度、10 cm土壤温度、20 cm土壤温度)及初始扰动强度的大小对陆面数据同化系统性能的影响,以及对不同区域(降水大值区和降水小值区)的分析场进行效果对比,并且检验了同化系统在一次典型的梅雨锋暴雨的同化效果,证明了这个系统的有效性和可行性。对于资料选取试验,比较全场平均的同化时刻分析场模拟观测相对真实观测的均方根误差可以得到:同化地表温度资料并且初始扰动强度1 K的时候同化效果最理想。对于选定的降水大值区和降水小值区来讲,降水大值区的土壤温度和土壤湿度分析场更加接近于真实场。运用于一次梅雨锋暴雨的同化实验,对于最后一个同化时次的分析场作为背景场做集合预报,最终证明预报结果是有效的。土壤温度、土壤湿度、地表温度和近地面风场的预报结果都较用NCEP再分析资料直接做预报作为控制试验的结果有不同程度的改进。这说明该系统应用于实际同化中的性能较为良好,可以应用于实际土壤湿度与温度的预报。     

CoLM模式地表温度变分同化研究

本文采用变分方法对通用陆面模式 (CoLM) 中的地表温度进行同化.同化伴随约束条件采用CoLM模式中的地表及植被能量平衡方程,调节因子采用裸土及植被蒸发比.采用美国通量网 (AmeriFlux) 中的Bonville站数据对同化方法进行了单点验证,验证结果表明同化后地表温度以及蒸散结果更加接近于实测值.选取中国华北地区对同化方法进行区域验证,结果显示每天仅采用白天一次观测值对地表温度进行同化的方法是有效的.通过对同化前后地表温度误差直方图比较可以发现,在有MODIS观测值的区域,同化后白天地表温度误差大大降低,同时,同化后地表蒸散空间分布图也发生了变化.单点验证以及区域验证结果都表明了变分同化方法是可靠的.变分同化方法可以改进陆面模式模拟结果,对于地表过程研究中的植被生态、水文等研究具有重要意义,同时,陆面模式可以与数值预报模式进行耦合,改进数值预报结果.     

区域气候模式RegCM2对标量粗糙敏感性试验

在地气通量的计算中,一般没有考虑温度、水汽、动量的相应粗糙度之间的不同。本文将标量粗糙度Z0T和Z0q引入区域气候模式RegCM2的陆面过程BATS中,用1991年6月与7月的观测资料作了三组敏感性试验,并同实况进行了比较。结果表明：在区域气候模式RegCM2中引入标量粗糙度后,提高了地气间感热通量与潜热通量的计算精度,改善了地表温度和地表比湿的模拟,进而改变了降水的模拟,表明区域气候模式对标量粗糙是敏感的,并且在晴天状况下更为敏感。     

不同陆面过程模式对半干旱区通榆站模拟性能的检验与对比

随着全球气候变化和伴随而来的日益严重的干旱化问题,干旱/半干旱地区的陆气相互作用引起了越来越多的重视。利用国际协同强化观测期(CEOP)观测资料对3个不同的陆面过程模式BATS、LSM和CoLM在半干旱区通榆站进行了模拟检验与对比,考察了不同陆面过程模式对半干旱地区的模拟性能。结果表明,3个模式都可以较好地模拟出半干旱地区地气间的能量通量的季节和日变化,但模拟性能存在较大差异。对于地表温度和出射长波辐射的模拟,BATS表现最优;而对于感热和潜热通量的模拟,CoLM和LSM要好于BATS,其中CoLM的表现最好。各模式的模拟性能随着季节不同存在着很大的差异,夏季的模拟要好于冬季,3个模式都不能很好地模拟冬季该地区的潜热通量,说明对半干旱地区冬季地表过程的刻画还有待进一步提高。     

青藏高原单点地气交换过程的模拟试验

利用GAME-Tibet 1998 IOPs的外场观测资料,采用单点陆面过程气柱模式CLSM对青藏高原的昌都(Amdo)站和改则(Gaize)站的地气交换过程进行了模拟试验,模拟结果与观测分析的对比表明：模式对两个站陆面特征的变化和陆气之间的交换给出了比较合理的模拟结果,模拟结果与观测结果较一致。这在一定程度上表明,CLSM模式具有描述夏季高原地区两种不同下垫面陆面状况基本过程的能力。     

同化极轨卫星陆地产品对改善陆面模式模拟能力研究进展

利用同化极轨卫星陆地产品改善陆面模式的模拟能力,是目前提升干旱监测水平研究的一个热点,也是一个难点问题。通过介绍现阶段几种典型陆面模式和同化方法,回顾了地表类型、地表反照率、植被覆盖度、地表温度、土壤湿度和降水量等主要极轨卫星陆地产品发展现状,并指出同化极轨卫星陆地产品对陆面模式模拟能力的改善作用主要受陆面模式、同化方法和卫星产品质量三方面限制。而基于较新的地表类型、(准)实时植被覆盖度和地表反照率产品及高质量的土壤湿度、地表温度和降水数据,通过优化同化方法和系统地发展陆面模式,有望进一步改善同化效果。     

辽宁省地气温差变化特征及其原因分析

利用1965—2014年辽宁省54个气象站月平均气温和地表温度观测资料、2003年45个气象站气温与地表温度的人工和自动定时观测资料,分析辽宁省气温、地表温度及地气温差的变化特征,并分析了地气温差变化的主要原因。结果表明:1965—2003年辽宁省气温和地表温度相关性较好,均呈显著升高的趋势,地气温差的变化较小;2004年开始气温较前10 a(1994—2003年)差异较小,而地表温度持续升高,地气温差加大,此现象在辽宁省东北部地区冬季最显著。2004年辽宁省气象站全面由人工观测改为自动站观测,积雪天气时人工气象站观测的地面温度为雪面温度,自动气象站观测的地面温度为雪下温度,不同观测方式引起的地面温度差异是导致近10 a(2004—2014年)地表温度持续升高的最主要原因。因此,辽宁省积雪期最长的东北部地区是地气温差加大最显著的区域。可见,观测方式的改变是导致2004—2014年辽宁地区地表温度持续升高和地气温差加大的主要原因。     

城市陆面模式设计及检验

针对城市冠层模式(Urban Canopy Model,UCM)的各种局限性,本文首次提出整体城市陆面模式(Bulk Urbanized Land Surface Model,BULSM)的概念,即在现有先进的陆面模式的基础上直接构建城市陆面模式。本文在通用陆面模式(Common Land Model,CoLM)基础上构建整体城市陆面模式,根据城市的特点对CoLM进行了发展和重新参数化。模式采用高分辨率地表分类数据;改进了模式的地表能量平衡方程与水分平衡方程;对反照率、城市地表粗糙度、城市大气廓线、城市人为热、不透水面水分蒸发及积水深度等进行了重新参数化。模式保留了CoLM在自然下垫面的全部特性,加强了CoLM在城市或人为下垫面的模拟和预报能力。区域验证以及与CoLM对比结果表明整体城市陆面模式模拟结果能够显示出北京城区各参数的空间精细化分布情况,能够反映出地表分类对模拟结果的影响。单站点验证以及与CoLM和高分辨率城市陆面同化系统(u-HRLDAS)对比结果表明整体城市陆面模式地表温度模拟结果与CoLM相比有很大提高;和u-HRLDAS相比大部分站点地表温度模拟结果也有一定的改进。     

改进的CLDAS降水驱动对中国区域积雪模拟的影响评估

积雪因为其特定的属性在气候变化和水文循环中扮演着重要角色,在大气和陆面之间起到了调节能量和水交换的显著作用,而陆面驱动数据的质量直接决定着模式对积雪的模拟效果。本文采用CLDAS(CMA Land Data Assimilation System)和改进后的降水驱动(CLDAS-Prcp)分别驱动Noah3.6陆面模式对积雪变量进行模拟,并对中国主要的积雪区东北区域、新疆区域、青藏高原区域的积雪覆盖率、雪深、雪水当量的模拟效果进行了评估。结果表明,CLDAS-Prcp改善了原有驱动在冬季由于低估降水所造成的模拟积雪量偏少的情况;东北区域模拟结果与观测的时间变率最为一致,积雪覆盖率、雪深、雪水当量的相关系数分别为0.42,0.78,0.93;而雪水当量的改进效果最明显,均方根误差和偏差分别减小了54.8%和83.1%,相关系数提高了0.47;同时,CLDAS-Prcp不仅能反映积雪变量的年际变率,而且能够较准确地反映出强度较大的突发降雪事件。     

陆面水文过程研究进展

本文回顾了近年来中国科学院大气物理研究所在陆面水文过程的观测、模式发展以及陆气相互作用研究等方面所取得的重要研究成果。首先概述了近年来在中国区域所开展的陆气相互作用野外观测试验,通过资料分析揭示了国际上现有陆面模式对干旱／半干旱地区陆气相互作用模拟的偏差,指出典型干旱／半干旱区陆面过程参数修正的必要性;随后重点描述了陆面过程模式中积雪覆盖度和冻土参数化方案的发展,中国区域土壤湿度的时空分布特征及其对区域气候的影响,以及中国区域大尺度水文模式的研制和应用等;最后给出了陆面水文过程研究的趋势和发展方向的展望。     

陆面模式CLSM的设计及性能检验Ⅰ.模式设计

在现有陆面模式的基础上,详细考虑了地气系统中的积雪、土壤水热传输、植被及湍流边界层中的各种物理过程,发展了一个既能反映积雪变化、干旱/半干旱区地气交换过程,同时又能描述不同陆面状况物理过程的陆面模式(Comprehensive Land Surface Model,简称CLSM),改善了陆面模式对全球范围内不同下垫面条件下的陆面过程及地-气交换过程的模拟能力.     

Improved Land Use and Leaf Area Index Enhances WRF-3DVAR Satellite Radiance Assimilation: A Case Study Focusing on Rainfall Simulation in the Shule River Basin during July 2013

The application of satellite radiance assimilation can improve the simulation of precipitation by numerical weather prediction models. However, substantial quantities of satellite data, especially those derived from low-level(surface-sensitive)channels, are rejected for use because of the difficulty in realistically modeling land surface emissivity and energy budgets.Here, we used an improved land use and leaf area index(LAI) dataset in the WRF-3 DVAR assimilation system to explore the benefit of using improved quality of land surface information to improve rainfall simulation for the Shule River Basin in the northeastern Tibetan Plateau as a case study. The results for July 2013 show that, for low-level channels(e.g., channel 3),the underestimation of brightness temperature in the original simulation was largely removed by more realistic land surface information. In addition, more satellite data could be utilized in the assimilation because the realistic land use and LAI data allowed more satellite radiance data to pass the deviation test and get used by the assimilation, which resulted in improved initial driving fields and better simulation in terms of temperature, relative humidity, vertical convection, and cumulative precipitation.     

An Updated Coupled Model for Land-Atmosphere Interaction. Part I： Simulations of Physical Processes

A new two-way land-atmosphere interaction model （R42_AVIM） is fulfilled by coupling the spectral atmospheric model （SAMIL_R42L9） developed at the State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics, Institute of Atmospheric Physics, Chinese Academy of Sciences （LASG/IAP/CAS） with the land surface model, Atmosphere-Vegetation-Interaction-Model （AVIM）. In this coupled model, physical and biological components of AVIM are both included. Climate base state and land surface physical fluxes simulated by R42_AVIM are analyzed and compared with the results of R42_SSIB [which is coupled by SAMIL_R42L9 and Simplified Simple Biosphere （SSIB） models]. The results show the performance of the new model is closer to the observations. It can basically guarantee that the land surface energy budget is balanced, and can simulate June-July-August （JJA） and December-January- February （DJF） land surface air temperature, sensible heat flux, latent heat flux, precipitation, sea level pressure and other variables reasonably well. Compared with R42_SSIB, there are obvious improvements in the JJA simulations of surface air temperature and surface fluxes. Thus, this land-atmosphere coupled model will offer a good experiment platform for land-atmosphere interaction research.     

环太湖地区土地利用变化的局地气候效应

利用WRF模式和1985年、2005年环太湖区域的土地利用资料,模拟了环太湖区域土地利用变化的局地气候效应,并从陆面过程的角度进行了分析。模拟结果显示：城市扩张区域净短波辐射通量增多,地面温度升高,感热通量增大,潜热通量减小。近地面水平风场在城市化地区风速减小,在城市化带方向上形成狭长的动能衰减区域。湖陆风和城市热岛环流增强,城市化地区向上垂直速度增大,积云性降水增多。老城区和郊区下沉运动增强,对流受到抑制,积云性降水减少。层云降水的改变,集中在层云降水的大值区,且多呈带状分布。总降水在城市化区域增强,在老城区和郊区减少,积云性降水占总降水的比值增大。在土地利用没有变化的区域,降水的改变与地表能量通量的改变在空间分布上大致吻合。     

An Updated Coupled Model for Land-Atmosphere Interaction. Part Ⅰ: Simulations of Physical Processes

A new two-way land-atmosphere interaction model (R42_AVIM) is fulfilled by coupling the spectral at- mospheric model (SAMIL_R42L9) developed at the State Key Laboratory of Numerical Modeling for Atmo- spheric Sciences and Geophysical Fluid Dynamics, Institute of Atmospheric Physics, Chinese Academy of Sci- ences (LASG/IAP/CAS) with the land surface model, Atmosphere-Vegetation-Interaction-Model (AVIM). In this coupled model, physical and biological components of AVIM are both included. Climate base state and land surface physical fluxes simulated by R42_AVIM are analyzed and compared with the results of R42_SSIB [which is coupled by SAMIL_R42L9 and Simplified Simple Biosphere (SSIB) models]. The results show the performance of the new model is closer to the observations. It can basically guarantee that the land surface energy budget is balanced, and can simulate June-July-August (JJA) and December-January- February (DJF) land surface air temperature, sensible heat flux, latent heat flux, precipitation, sea level pressure and other variables reasonably well. Compared with R42_SSIB, there are obvious improvements in the JJA simulations of surface air temperature and surface fluxes. Thus, this land-atmosphere coupled model will offer a good experiment platform for land-atmosphere interaction research.     

Improved Assimilation of Fengyun-3 Satellite-Based Snow Cover Fraction in Northeastern China

Assimilation of snow cover is an important method to improve the accuracy of snow simulation. However, the effects of snow assimilation are poor because satellite observed snow cover data contain erroneous information, such as cloud contamination. In this paper, an improved approach is proposed to reduce the effects of observational errors during assimilation of snow cover fraction acquired by the Fengyun-3(FY-3) satellite in northeastern China. A snow depth constraint was imposed on quality control of a snow depth product from a microwave radiation imager. The assimilation experiments were carried out before and after quality control(denoted as SCFDA and SCFDA_WSD, respectively). The snow cover fraction results were evaluated against the Moderate Resolution Imaging Spectroradiometer(MODIS) snow cover products. When assimilating the snow cover fraction with the snow depth constraint(i.e., SCFDA_WSD), substantially larger improvement was obtained than that without such a constraint/quality control(SCFDA), and the deviation and root mean square error of the snow cover fraction were significantly reduced.The assimilation performance was also evaluated against in-situ snow depth observations. The SCFDA_WSD also showed greater improvements during the snow accumulation and snowmelt periods than the SCFDA. The SCFDA_WSD improvements in woodland and shrubland were the most obvious. At different altitudes, the effects of the SCFDA_WSD were basically equivalent, and the deeper the snow depth was, the better the effect. In addition, the SCFDA_WSD method was found in close agreement with the observations during a sudden snowfall event.     

卫星资料循环同化应用对区域数值预报效果影响分析

为提高卫星资料在同化系统中的利用率及验证卫星微波资料对区域数值预报效果的影响,本文以2008年8月1-31日为研究时段,利用WRF模式及其WRF-3DVAR同化模块,设计并构建了卫星微波资料的快速循环同化方案,分析循环同化方案对数值预报的改进效果.结果表明,相比于单时次同化,循环同化方案使各预报要素的相关系数在一定程度上得到改善,均方差也呈现减小的趋势.此外,对研究时段内暴雨和台风个例的具体分析显示,循环同化方案能够有效改善降水和台风路径的预报.     

The coupling of the Common Land Model (CLM0) to a regional climate model (RegCM)

Summary We replace the existing land surface parameterization scheme, the Biosphere-Atmosphere Transfer Scheme (BATS), in a regional climate model (RegCM) with the newly developed Common Land Model (CLM0). The main improvements of CLM0 include a detailed 10-layer soil model, the distinction between soil ice and water phases, a linked photosynthesis-stomatal conductance model, a multilayer snow model, and an improved runoff parameterization. We compare the performance of CLM0 and BATS as coupled to the RegCM in a one year simulation over East Asia. We find that the RegCM/CLM0 improves the winter cold bias present in the RegCM/BATS simulation. With respect to the surface energy balance, lower CLM0 albedos allow the absorption of more solar radiation at the surface. CLM0 tends to simulate higher sensible heat and lower latent heat fluxes than its BATS counterpart. The surface water balance also changes considerably between the two land surface schemes. Compared to BATS, CLM0 precipitation is reduced overall and surface runoff is increased, thereby allowing less water to enter the soil column. Evapotranspiration is lower in CLM0 due to lower ground evaporation, which leads to a wetter surface soil in CLM0 in spite of less precipitation input. However, transpiration is greater in CLM0 than BATS, which has an overall effect of less surface storage during the summertime. Comparison with station observations indicates that CLM0 tends to improve the simulation of root zone soil water content compared to BATS. Another pronounced difference between the two schemes is that CLM0 produces lower snow amounts than BATS because of different snow models and warmer CLM0 temperatures. In this case, BATS snow cover amounts are more in line with observations. Overall, except for the snow amounts, CLM0 appears to improve the RegCM simulation of the surface energy and water budgets compared to BATS.