共查询到15条相似文献,搜索用时 125 毫秒
1.
边界层参数化方案及海气耦合对WRF模拟东亚夏季风的影响 总被引:2,自引:0,他引:2
区域气候模式的边界层参数化方案很大程度上影响着陆地-海洋-大气间水汽、动量及热量的交换,该方案的不确定性会给模式结果带来明显误差.本文基于WRF区域气候模式中四种常用的边界层参数化方案(YSU,ACM2,BouLac和MYJ)分别对东亚夏季风进行模拟研究,分析了不同的边界层方案对东亚夏季风环流及降水模拟的影响.结果表明,局地湍流动能方案BouLac和MYJ对东亚夏季风的模拟结果相对于非局地闭合方案YSU和ACM2更接近于观测,前者能更好的模拟出中国东部中低空西南风气流和西太平洋副热带高压.对于东亚夏季风降水,无论是空间分布还是季节内演变,BouLac和MYJ方案都要明显优于YSU和ACM2.此外,通过对比YSU和BouLac两种方案的模拟结果,发现边界层方案对东亚夏季风的模拟在海洋区域的影响更为显著.造成不同方案模拟差异的主要原因是非局地方案YSU和ACM2的边界层垂直混合偏强,使得海表向上输送的潜热通量明显偏强,对流更活跃,导致降水偏多以及相应季风环流的异常偏差.进一步研究指出缺少海气反馈过程使得WRF模式由边界层方案引起的模拟误差在海洋区域更为突出,引入海气耦合可以减小海表热通量误差并明显改善东亚夏季风的模拟结果. 相似文献
2.
本文利用高分辨率中尺度WRF模式,通过改变边界层参数化方案进行多组试验,评估该模式对美国北部森林地区边界层结构的模拟能力,同时比较了五种不同边界层参数化方案模拟得出的边界层热力和动力结构.结果表明:除个别方案外,配合不同边界层方案的WRF模式都能成功模拟出白天对流边界层强湍流混合特征和夜间稳定边界层内强逆温、逆湿和低空急流等热力和动力结构.非局地YSU、ACM2方案在白天表现出强的湍流混合和卷夹,相比于局地MYJ、UW方案,模拟的对流边界层温度更高、湿度更低、混合层高度更高、感热通量更大,更接近实际观测,这表明在不稳定层结下考虑非局地大涡输送更为合理,但局地方案在风速和风向的预报上存在一定优势.TEMF方案得到的白天局地湍流混合强度为所有方案中最弱,混合层难以发展,无法体现对流边界层内气象要素垂直分布均匀的特点.对于夜间稳定边界层的模拟,不同参数化方案之间的差异较小,但是YSU方案在一定程度上高估了机械湍流,导致局地湍流混合偏强,从而影响了其对稳定边界层的模拟能力. 相似文献
3.
研究新一代中尺度气象模式WRF中两种大气边界层方案(MYJ,YSU)对沈阳冬季大气边界层结构模拟的影响,重点分析温度层结、低层风场、边界层高度等对污染物扩散有重要影响的气象要素.和观测数据的比对表明WRF基本能够模拟出温度风速的日变化特征,但模拟风速偏大.YSU方案由于模拟的边界层顶卷挟和边界层内混合作用较强,夜间接地逆温强度低于MYJ方案,逆温维持时间比MYJ方案短4小时,同时模拟边界层高度也高于MYJ方案,有利于污染物垂直扩散.边界层高度的3种计算方法中,湍流动能方法计算的边界层高度最高,Richardson数方法次之,位温方法得到的高度最低.Richardson数方法对临界值的选取较敏感. 相似文献
4.
本文基于WRF-ARW(V4.0)中尺度数值模式,选用耦合同一近地层参数化方案(Eta)的五种边界层参数化方案(MYJ、MYNN2、MYNN3、BouLac、UW),对2020年5月1—2日海南岛一次典型山地环流个例进行模拟,对比分析了这五种方案所模拟的山地环流结构和湍流特征的差异,旨在为模式应用于山地环流研究和模式改进提供一定的科学依据.研究结果表明,这五种湍流动能边界层参数化方案均能模拟出山谷风特征,对环流结构和湍流特征的影响表现为谷风时段大于山风时段.对于山地环流水平结构的模拟,因平原风推进距离的不同,五种方案模拟的近地面风速差异可达4 m·s-1以上,其中MYJ方案模拟的谷风最强盛,而MYNN3方案最弱,山区多为静风或小风.对于山地环流垂直结构的模拟,MYNN2、UW方案模拟的谷风环流较强,表现为谷风厚度较厚,推进距离较远,同时由于模拟的谷风环流可越过山顶,从而模拟的高海拔地区上升区的覆盖范围和强度均较大;MYJ、BouLac方案模拟的谷风环流均未能越过山顶,且其中BouLac方案的平原风环流未能与上坡风环流耦合;而MYNN3方案模拟的环流结构最不明显.湍... 相似文献
5.
本文利用中尺度数值模式WRF,分别采用YSU和MYJ两种边界层参数化方案对2010年超强台风Megi的移动路径进行了模拟,研究了热带气旋(TC)路径模拟对边界层方案的敏感性,并从模拟TC尺度差异所造成的影响角度揭示了模式边界层方案影响TC路径的机理.结果表明:由于两种方案对边界层垂直混合作用过程的描述不同,两个试验模拟的低层水汽垂直输送存在差异.相对于能很好模拟出Megi路径的MYJ方案,YSU方案模拟的TC外围螺旋雨带更活跃,造成TC尺度增大,引起TC中心北侧外围气压梯度和径向风速增加,使得由副高向TC中心输送更多的质量,造成副高异常减弱,从而导致由副高主导的引导气流发生改变,最终使得采用YSU方案模拟的Megi路径出现提前转向. 相似文献
6.
Impacts of boundary layer parameterization schemes and air-sea coupling on WRF simulation of the East Asian summer monsoon 总被引:2,自引:0,他引:2
The planetary boundary layer(PBL)scheme in the regional climate model(RCM)has a significant impact on the interactions and exchanges of moisture,momentum,and energy between land,ocean,and atmosphere;however,its uncertainty will cause large systematic biases of RCM.Based on the four different PBL schemes(YSU,ACM2,Boulac,and MYJ)in Weather Research and Forecasting(WRF)model,the impacts of these schemes on the simulation of circulation and precipitation during the East Asian summer monsoon(EASM)are investigated.The simulated results of the two local turbulent kinetic energy(TKE)schemes,Boulac and MYJ,are more consistent with the observations than those in the two nonlocal closure schemes,YSU and ACM2.The former simulate more reasonable low-level southwesterly flow over East China and west pacific subtropical high(WPSH)than the latter.As to the modeling of summer monsoon precipitation,both the spatial distributions and temporal evolutions from Boulac and MYJ are also better than those in YSU and ACM2 schemes.In addition,through the comparison between YSU and Boulac experiments,the differences from the results of EASM simulation are more obvious over the oceanic area.In the experiments with the nonlocal schemes YSU and ACM2,the boundary layer mixing processes are much stronger,which lead to produce more sea surface latent heat flux and enhanced convection,and finally induce the overestimated precipitation and corresponding deviation of monsoon circulation.With the further study,it is found that the absence of air-sea interaction in WRF may amplify the biases caused by PBL scheme over the ocean.Consequently,there is a reduced latent heat flux over the sea surface and even more reasonable EASM simulation,if an ocean model coupled into WRF. 相似文献
7.
为了修正中尺度气象模式WRF(Weather Research and Forecasting model)对低层风速模拟的系统性误差,有学者在新版本WRF模式的YSU(Yonsei University)边界层参数化方案中加入了两个地形订正方法:Jiménez方法和UW(University of Washington method)方法.本文利用这两个地形订正方法,选取了两个时间段,对北京地区的地面气象要素以及气象要素垂直廓线进行了个例模拟研究,模拟结果和观测数据的比对表明在北京地区:是否采用地形订正,对地面温度的模拟几乎没有影响;采用地形订正后,模式对地面风速的模拟有明显的改进,两种方法对风速模拟的差别主要体现在山/丘陵地区;Jiménez方法在山/丘陵地区的模拟风速明显偏大,而采用UW方法进行订正后,模拟的风速减小,更接近观测值;两种方法在山谷地区对风速均有一定的过度订正.通过分析气象要素的垂直廓线发现,不同地形订正方法主要影响的是2000m以下的低层风速.总体而言,UW地形订正方法在北京地区更为适用,采用UW方法后,模拟得到的地面气象要素的各项统计参数基本达到了统计基准值. 相似文献
8.
北冰洋及其邻近海域极昼期间大气边界层结构特征试验研究 总被引:17,自引:1,他引:16
1年7-月中国"雪龙"号破冰船首航北极科学考察期间,利用TMT(系留式气象塔)大气边界层探测系统,对北冰洋及其邻近海域不同下垫面进行较长时间的连续多次观测. 观测到的大气边界层廓线,其中包括比湿廓线的多层、逆湿结构(逆湿强度最强为0.7g/(10m·kg));风向、风速廓线的切变结构(风向切变为1.1°/m,风速切变为0.11(m·s-1)/m. 特别是持续数日、厚达几百米、其平均逆温强度有时高达1.4℃/10m的逆温结构,这种北冰洋海域特有的大气边界层结构,与地球气候系统中其他圈层的大气边界层结构有明显差别. 据此,提出了对该海域大气-海冰-海洋间动量、感热和潜热等湍流通量垂直交换以及热量平衡等有重要影响的大气逆温的屏障过程. 这为研究北极地区对全球气候影响、模拟北极地区现代气候和未来气候等提供一条新的思路. 此外,文中还给出该海域不同下垫面稳定大气边界层的高度. 相似文献
9.
利用三维非静力中尺度模式ARPS,对白洋淀地区水陆非均匀下垫面上大气边界层结构及其变动进行了模拟研究.结果表明,晴天弱背景下,白洋淀地区陆地大气比湿高于水域的情况发生在白天大部分时间内,是普遍存在的一种现象,该现象首先出现在近地层,然后不断向高空延伸,与水陆两种不同的下垫面特征密切相关.由于水陆下垫面的差异,导致水域感热和潜热通量全天较小,变化平稳,而陆地日间感热和潜热通量较大,且潜热高于感热.水陆两地近地层湍流运动状态存在较大差异,湍流输送在水陆比湿空间变动过程中起决定性作用.形成的局地环流同样影响着水陆比湿的空间变动,主要表现在环流上下支对近地层湍流发展以及水汽的垂直输送的影响.陆地上空水汽主要来源于土壤植被的蒸发蒸腾,而来自水域的仅占很少一部分. 相似文献
10.
通过建立一个包含比较详细的地面和水体内物理过程的非静力近似中小尺度数值模式,模拟陆地水体对周围空气比湿影响的空间分布,模拟结果与实际情况比较接近。计算结果表明:水体在冬季和夏季都增加周围空气的比湿;增加的幅度是晴天大于阴天、夜间大于白天、冬季大于夏季;仅在夏季晴天正午时,由于水体强烈降温,近水面大气层结很稳定,水体附近空气比湿略有降低。空气比湿的改变主要发生在气流刚过水面的2—3km范围内;在岸上水体影响接近指数律减小,水体对空气比湿影响消失的距离为:在上风岸不到4km,下风岸可超过20km;水体影响空气比湿的高度为200—400m。 相似文献
11.
This paper investigates the sensitivity of the numerical simulations of a near equatorial Typhoon Vamei (2001) to various
planetary boundary layer (PBL) parameterization schemes in the Pennsylvania State University (PSU)/National Centre for Atmospheric
Research (NCAR) non-hydrostatic mesoscale model (MM5). The numerical simulations are conducted on two domains at 45 and 15 km
grids nested in a one-way fashion. Four different PBL parameterization schemes including the Blackadar (BLK) scheme, the Burk–Thompson
(BURKT) scheme, the NCEP Eta model scheme and the NCEP medium range forecast (MRF) model scheme are investigated. Results
indicate that the intensity and propagation track of the simulated near equatorial typhoon system is not very sensitive to
the different PBL treatments. The simulated minimum central pressures and the maximum surface wind speeds differ by only 5–6 hPa
and 6–8 ms−1, respectively. Larger variations between the simulations occur during the weakening phase of the typhoon system. While all
schemes simulated the typhoon with reasonable accuracy, the ETA scheme produces the strongest storm intensity with the largest
heat exchanges over the marine environment and the highest warm moisture air content in the PBL around the core of the storm. 相似文献
12.
Sensitivity of Mesoscale Model Forecast During a Satellite Launch to Different Cumulus Parameterization Schemes in MM5 总被引:1,自引:0,他引:1
The identification of the model discrepancy and skill is crucial when a forecast is issued. The characterization of the model
errors for different cumulus parameterization schemes (CPSs) provides more confidence on the model outputs and qualifies which
CPSs are to be used for better forecasts. Cases of good/bad skill scores can be isolated and clustered into weather systems
to identify the atmospheric structures that cause difficulties to the forecasts. The objective of this work is to study the
sensitivity of weather forecast, produced using the PSU-NCAR Mesoscale Model version 5 (MM5) during the launch of an Indian
satellite on 5th May, 2005, to the way in which convective processes are parameterized in the model. The real-time MM5 simulations
were made for providing the weather conditions near the launch station Sriharikota (SHAR). A total of 10 simulations (each
of 48 h) for the period 25th April to 04th May, 2005 over the Indian region and surrounding oceans were made using different
CPSs. The 24 h and 48 h model predicted wind, temperature and moisture fields for different CPSs, namely the Kuo, Grell, Kain-Fritsch
and Betts-Miller, are statistically evaluated by calculating parameters such as mean bias, root-mean-squares error (RMSE),
and correlation coefficients by comparison with radiosonde observation. The performance of the different CPSs, in simulating
the area of rainfall is evaluated by calculating bias scores (BSs) and equitable threat scores (ETSs). In order to compute
BSs and ETSs the model predicted rainfall is compared with Tropical Rainfall Measuring Mission (TRMM) observed rainfall. It
was observed that model simulated wind and temperature fields by all the CPSs are in reasonable agreement with that of radiosonde
observation. The RMSE of wind speed, temperature and relative humidity do not show significant differences among the four
CPSs. Temperature and relative humidity were overestimated by all the CPSs, while wind speed is underestimated, except in
the upper levels. The model predicted moisture fields by all CPSs show substantial disagreement when compared with observation.
Grell scheme outperforms the other CPSs in simulating wind speed, temperature and relative humidity, particularly in the upper
levels, which implies that representing entrainment/detrainment in the cloud column may not necessarily be a beneficial assumption
in tropical atmospheres. It is observed that MM5 overestimates the area of light precipitation, while the area of heavy precipitation
is underestimated. The least predictive skill shown by Kuo for light and moderate precipitation asserts that this scheme is
more suitable for larger grid scale (>30 km). In the predictive skill for the area of light precipitation the Betts-Miller
scheme has a clear edge over the other CPSs. The evaluation of the MM5 model for different CPSs conducted during this study
is only for a particular synoptic situation. More detailed studies however, are required to assess the forecast skill of the
CPSs for different synoptic situations. 相似文献
13.
Numerical simulation of the influence of aerosol radiation effect on urban boundary layer 总被引:2,自引:0,他引:2
With the intensification of pollution and urbanization, the aerosol radiation effect continues to play an important role in the urban boundary layer. In this paper, a winter pollution process in Beijing has been taken as an example, and a new aerosol vertical profile in the radiative parameterization scheme within the Weather Forecast Research and Forecasting (WRF) model has been updated to study the effect of aerosols on radiation and the boundary layer. Furthermore, the interactions among aerosols, urbanization, and planetary boundary layer (PBL) meteorology were discussed through a series of numerical experiments. The results show the following: (1) The optimization improves the performance of the model in simulating the distribution features of air temperature, humidity, and wind in Beijing. (2) The aerosols reduce the surface temperature by reducing solar radiation and increasing the temperature in the upper layer by absorbing or backscattering solar radiation. The changes in the PBL temperature lead to more stable atmospheric stratification, reducing the energy transfer from the surface and the height of the boundary layer. (3) With the increase in the aerosol optical depth, the atmospheric stratification most likely becomes stable over rural areas, most likely becomes stable over suburb areas, and has great difficultly becoming stable over urban areas. Aerosol radiative forcing, underlying urban surfaces, and the interaction between them are the main factors that affect the changes in the meteorological elements in the PBL. 相似文献
14.
Jiang YuJun Liu HuiZhi Zhang BoYin Zhu FengRong Liang Bin Sang JianGuo 《中国科学D辑(英文版)》2008,51(1):103-113
Flow structure and wind pressure distribution caused by obtuse obstacles are usually the focuses in Computational Wind Engineer researches (CWE). By solving the non-hydrostatical dynamic equations, PUMA model (Peking University Model of Atmospheric Environment) was developed and applied to simulating the flow structure and wind pressure distribution around a tower-shaped building. Evaluation about the wind environment and wind loads around the building was obtained through the analysis of the numerical simulation results and wind tunnel data. Comparisons between the simulation and wind tunnel study indicate that numerical simulation results agree well in the flow field and wind pressure distribution around the tower-shaped building. On the other hand, the horizontal grid interval of 2 m and the vertical grid of 3 m were still too crude to simulate the flow structure and wind pressure distribution on the building surface more exactly in detail; and the absence of suitable pressure perturbation parameterization scheme between the solid and the adjacent space also limits the accuracy of the numerical simulation. The numerical simulation model can be used to evaluate the wind environment and wind load around high buildings. 相似文献
15.
Numerical Simulation of Andhra Severe Cyclone (2003): Model Sensitivity to the Boundary Layer and Convection Parameterization 总被引:1,自引:0,他引:1
C. V. Srinivas R. Venkatesan D. V. Bhaskar Rao D. Hari Prasad 《Pure and Applied Geophysics》2007,164(8-9):1465-1487
The Andhra severe cyclonic storm (2003) is simulated to study its evolution, structure, intensity and movement using the Penn
State/NCAR non-hydrostatic mesoscale atmospheric model MM5. The model is used with three interactive nested domains at 81,
27 and 9 km resolutions covering the Bay of Bengal and adjoining Indian Peninsula. The performance of the Planetary Boundary
Layer (PBL) and convective parameterization on the simulated features of the cyclone is studied by conducting sensitivity
experiments. Results indicate that while the boundary layer processes play a significant role in determining both the intensity
and movement, the convective processes especially control the movement of the model storm. The Mellor-Yamada scheme is found
to yield the most intensive cyclone. While the combination of Mellor-Yamada (MY) PBL and Kain-Fritsch 2 (KF2) convection schemes
gives the most intensive storm, the MRF PBL with KF2 convection scheme produces the best simulation in terms of intensity
and track. Results of the simulation with the combination of MRF scheme for PBL and KF2 for convection show the evolution
and major features of a mature tropical storm. The model has very nearly simulated the intensity of the storm though slightly
overpredicted. Simulated core vertical temperature structure, winds at different heights, vertical winds in and around the
core, vorticity and divergence fields at the lower and upper levels—all support the characteristics of a mature storm. The
model storm has moved towards the west of the observed track during the development phase although the location of the storm
in the initial and final phases agreed with the observations. The simulated rainfall distribution associated with the storm
agreed reasonably with observations. 相似文献