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1.
Christophe Etienne Stéphane Goyette Charles-Antoine Kuszli 《Theoretical and Applied Climatology》2013,113(3-4):529-547
This study reports on the ability of the Canadian Regional Climate Model to simulate the surface wind gusts of 24 severe mid-latitude storms in Switzerland during the period 1990–2010. A multiple self-nesting approach is used, reaching a final 2-km grid which is centred over Switzerland, a country characterised by complex topography. A physically-based wind gust parameterization scheme is applied to simulate local surface gusts. Model performance is evaluated by comparing simulated wind speeds to time series at weather stations. While a number of simulated variables are reproduced in a realistic manner, the surface wind gusts show differences when compared to observed values. Results indicate that the performance of this parameterization scheme not only depends on the accuracy of the simulated planetary boundary layer, the vertical temperature, wind speed and atmospheric humidity profiles, but also on the accuracy of the reproduction of the surface fields such as temperature and moisture. 相似文献
2.
利用区域环境集成系统模式(RIEMS2.0)在60 km和30 km两种分辨率下进行中国区域的长期模拟试验(1991~2000年),开展不同分辨率下中国气温平均气候态和年际变率的模拟能力分析研究。结果表明:(1)RIEMS2.0能较好模拟出多数分区多年平均气温的空间分布,与观测空间分布较接近。随着水平分辨率的提高,模式模拟的气温空间分布模拟更精细,使得平均气温的模拟冷偏差减小,模拟结果更趋于实测。对年均温和冬季气温来说,中国及多数分区模拟与观测的偏差减少,且通过显著性检验(P0.01);对夏季气温来说,中国及多数分区的偏差增加,气温的模拟能力没有明显提高。(2)对年际变率来说,随着水平分辨率的提高,大部分区域模拟能力有一定程度的提高。特别是年均温和冬季气温的年际变率,多数地区模拟改进效果较好;而夏季气温年际变率的模拟在中国大部分地区没有明显改善。 相似文献
3.
Charles L. Curry Bárbara Tencer Kirien Whan Andrew J. Weaver Michel Giguère Edward Wiebe 《大气与海洋》2016,54(4):385-402
We evaluate the capacity of a regional climate model to simulate the statistics of extreme events, and also examine the effect of differing horizontal resolution, at the scale of individual hydrological basins in the topographically complex province of British Columbia, Canada. Two climate simulations of western Canada (WCan) were conducted with the Canadian Regional Climate Model (version 4) at 15 (CRCM15) and 45?km (CRCM45) horizontal resolution driven at the lateral boundaries by global reanalysis over the period 1973–1995. The simulations were evaluated with ANUSPLIN, a daily observational gridded surface temperature and precipitation product and with meteorological data recorded at 28 stations within the upper Peace, Nechako, and upper Columbia River basins. In this work, we focus largely on a comparison of the skill of each model configuration in simulating the 90th percentile of daily precipitation (PR90). The companion paper describes the results for a wider range of temperature and precipitation extremes over the entire WCan domain.Over all three watersheds, both simulations exhibit cold biases compared with observations, with the bias exacerbated at higher resolution. Although both simulations generally display wet biases in median precipitation, CRCM15 features a reduced bias in PR90 in all three basins in summer and throughout the year in the upper Columbia River basin. However, the higher resolution model is inferior to CRCM45 with respect to rarer heavy precipitation events and also displays high spatial variability and lower spatial correlations with ANUSPLIN compared with the coarser resolution model. A reduction in the range of PR90 biases over the upper Columbia basin is noted when the 15?km results are averaged to the 45?km grid. This improvement is partly attributable to the averaging of errors between different elevation data used in the gridded observations and CRCM, but the sensitivity of CRCM15 to resolved topography is also clear from spatial maps of seasonal extremes. At the station scale, modest but systematic reductions in the bias of PR90 relative to ANUSPLIN are again found when the CRCM15 results are averaged to the 45?km grid. Furthermore, the annual cycle of inter-station spatial variance in the upper Columbia River basin is well reproduced by CRCM15 but not by ANUSPLIN or CRCM45. The former result highlights the beneficial effect of spatial averaging of small-scale climate variability, whereas the latter is evidently a demonstration of the added value at high resolution vis-à-vis the improved simulation of precipitation at the resolution limit of the model. 相似文献
4.
WRF模式分辨率对新疆异常降雨天气要素模拟的影响 总被引:7,自引:2,他引:5
利用新一代中尺度气候数值模式WRF对中国西北干旱典型地区——新疆2000年10月的异常降雨事件进行模拟,主要研究了不同水平分辨率、垂直分辨率以及不同积云参数化过程对气温、降雨和土壤温度模拟的影响。结果表明:不同分辨率的模拟基本上均模拟出了地面气温的分布特征,且随着水平分辨率的提高,模式模拟能力显著提高,对地面气温值、分布范围的模拟渐趋合理,同时模式对于地形引起的温度分布变化的模拟更加趋近实际。水平分辨率、垂直分辨率的提高同样改善了模式对降水的模拟能力,分辨率的提高不仅改进了模式对降雨分布区模拟的精度,也增强了对于地形引起的降雨变异的模拟能力。在土壤温度模拟上,不同分辨率的试验均能模拟出土壤温度的分布特征,较高水平分辨率有利于描述土壤温度分布细节,但更容易出现“数值点风暴”现象。 相似文献
5.
MRI模式对华南春雨气候态及年际变率的模拟:不同模式分辨率的比较 总被引:2,自引:1,他引:1
本文利用日本气象研究所(MRI)参加第五次国际耦合模式比较计划(CMIP5)的大气环流模式在高、中、低三种分辨率下的AMIP试验结果,评估了其对华南春雨气候态和年际变率的模拟能力,比较了不同分辨率的模拟结果。结果表明,三种不同水平分辨率(120 km、60 km和20 km)的模式均能再现北半球春季位于中国东南部的降水中心。相较于120 km模式,20 km模式能够更为合理地模拟出华南春雨位于南岭—武夷山脉的降水中心。水汽收支分析表明,60 km、20 km模式高估了水汽辐合,使得华南春雨的降水强度被高估。在年际变率方面,在三种分辨率下,模式均能较好地再现观测中El Ni?o衰减年春季的西北太平洋反气旋以及华南春雨降水正异常。较之120 km模式,60 km、20 km模式模拟的降水正异常的空间分布和强度更接近观测,原因是后者模拟的El Ni?o衰减年春季华南地区的水平水汽平流异常更接近观测。本研究表明,发展高分辨率气候模式是提高华南春雨的气候态和年际变率模拟水平的有效途径之一。 相似文献
6.
The fifth-generation Pennsylvania State University/NCAR Mesoscale Model Version 3 (MM5V3) was used to simulate extreme heavy rainfall events over the Yangtze River Basin in June 1999. The effects of model's horizontal and vertical resolution on the extreme climate events were investigated in detail. In principle, the model was able to characterize the spatial distribution of monthly heavy precipitation. The results indicated that the increase in horizontal resolution could reduce the bias of the modeled heavy rain and reasonably simulate the change of daily precipitation during the study period. A finer vertical resolution led to obviously improve rainfall simulations with smaller biases, and hence, better resolve heavy rainfall events. The increase in both horizontal and vertical resolution could produce better predictions of heavy rainfall events. Not only the rainfall simulation altered in the cases of different horizontal and vertical grid spacing, but also other meteorological fields demonstrated diverse variations in terms of resolution change in the model. An evident improvement in the simulated sea level pressure resulted from the increase of horizontal resolution, but the simulation was insensitive to vertical grid spacing. The increase in vertical resolution could enhance the simulation of surface temperature as well as atmospheric circulation at low levels, while the simulation of circulation at middle and upper levels were found to be much less dependent on changing resolution. In addition, cumulus parameterization schemes showed high sensitivity to horizontal resolution. Different convective schemes exhibited large discrepancies in rainfall simulations with regards to changing resolution. The percentage of convective precipitation in the Grell scheme increased with increasing horizontal resolution. In contrast, the Kain-Fritsch scheme caused a reduced ratio of convective precipitation to total rainfall accumulations corresponding to increasing horizontal resolution. 相似文献
7.
The scaled-decomposed atmospheric water budget over North America is investigated through the analysis of 25 years of simulation
by the Canadian Regional Climate Model (CRCM) driven by the NCEP–NCAR reanalyses for the period 1975–1999. The time average
and time variability of the atmospheric water budget for the winter and summer seasons are decomposed into their large-scale
and small-scale components to identify the added value of the regional model. For the winter season, the intra-seasonal transient-eddy
variance is the main temporal variability. The large- and small-scale terms are of the same order of magnitude, and are large
over both coasts and weak over the continent. For the summer season, the time–mean atmospheric water budget is rather different
to that of winter, with maximum values over the south-eastern part of the continent. The summer intra-seasonal variance is
about twice stronger than in winter and also dominates the variability, but the inter-monthly variance is non-negligible and
can be in part associated to North American Monsoon System. Over the continent, the intra-seasonal climatological variance
is dominated by the variability of the small scales. The small scales, that is those scales that are only resolved in the
regional model but not in the reanalyses, contribute to the added value in a regional climate simulation. In the winter season,
the added value of the CRCM is large and dominated by oceanic forcing, while in summer, it is dominant (larger than the large
scales) and controlled mainly by convective processes. 相似文献
8.
利用WRF模式,研究了模式水平和垂直网格分辨率对台风“天鸽”(2017)模拟的影响。结果表明:水平分辨率的改变会对台风路径造成一定的影响,这种影响与改变水平分辨率以后所引起的台风强度和结构的变化有关。使用更高的水平分辨率时模拟的台风强度往往更强。此外,改变垂直分辨率对台风的路径模拟也有一定的影响。采用双曲正切的垂直分层方法,提高垂直层数,模式大气的垂直分辨率都有增加,但是在低层和高层垂直分辨率的增加更大。低层和高层垂直分辨率增加,模拟的台风强度增强。模式的水平分辨率和垂直分辨率之间匹配才能比较好地模拟台风,双向嵌套模式在提高嵌套层数的同时也要增加模式的垂直分辨率。台风强度和结构变化密切相关,台风强度增强的重要原因是台风云墙随着分辨率的增加更加陡峭,垂直风速随着水平分辨率的提高逐渐增强。 相似文献
9.
分辨率对区域气候极端事件模拟的影响 总被引:13,自引:2,他引:13
利用NCAR MM5V3对1999年6月长江流域的极端异常降水事件进行了模拟,主要研究不同水平和垂直分辨率对极端区域气候事件模拟的影响。数值模拟试验表明:模式能够模拟出极端强降水的主要分布特征;水平分辨率的提高降低了模式模拟的强降水偏差,对逐日降水变化的模拟更加合理,而垂直分辨率的提高基本上也都减小了模拟的强降水过程的偏差,改善对强降水的模拟能力;模式水平、垂直分辨率的提高在一定程度上增强了对强降水过程的模拟能力。水平分辨率的提高能够改善模式对海平面气压的模拟,而垂直分辨率的提高可以改善模式模拟的地面气温和低层环流。分辨率对中层大气环流的影响不是很敏感。不同积云对流参数化方案模拟的对流降水比率随水平分辨率的变化是不同的,Grell方案对流降水比例随分辨率的提高而增加,而Kain-Fritsch方案的结果相反。 相似文献
10.
Rene Laprise Daniel Caya Michel Giguere Guy Bergeron Hélène Côté Jean‐Pierre Blanchet 《大气与海洋》2013,51(2):119-167
Abstract A þrst climate simulation performed with the novel Canadian Regional Climate Model (CRCM) is presented. The CRCM is based on fully elastic non‐hydrostatic þeld equations, which are solved with an efþcient semi‐implicit semi‐Lagrangian (SISL) marching algorithm, and on the parametrization package of subgrid‐scale physical effects of the second‐generation Canadian Global Climate Model (GCMII). Two 5‐year integrations of the CRCM nested with GCMII simulated data as lateral boundary conditions are made for conditions corresponding to current and doubled CO2 scenarios. For these simulations the CRCM used a grid size of 45 km on a polar‐stereographic projection, 20 scaled‐height levels and a time step of 15 min; the nesting GCMII has a spectral truncation of T32, 10 hybrid‐pressure levels and a time step of 20 min. These simulations serve to document: (1) the suitability of the SISL numerical scheme for regional climate modelling, (2) the use of GCMII physics at much higher resolution than in the nesting model, (3) the ability of the CRCM to add realistic regional‐scale climate information to global model simulations, and (4) the climate of the CRCM compared to that of GCMII under two greenhouse gases (GHG) scenarios. 相似文献
11.
Simulations of the Indian summer monsoon using a nested regional climate model: domain size experiments 总被引:2,自引:0,他引:2
Seasonal simulations of the Indian summer monsoon using a 50-km regional climate model (RCM) are described. Results from three versions of the RCM distinguished by different domain sizes are compared against those of the driving global general circulation model (AGCM). Precipitation over land is 20% larger in the RCMs due to stronger vertical motions arising from finer horizontal resolution. The resulting increase in condensational heating helps to intensify the monsoon trough relative to the AGCM. The RCM precipitation distributions show a strong orographically forced mesoscale component (similar in each version). This component is not present in the AGCM. The RCMs produce two qualitatively realistic intraseasonal oscillations (ISOs) associated respectively with monsoon depressions which propagate northwestward from the Bay of Bengal and repeated northward migrations of the regional tropical convergence zone. The RCM simulations are relatively insensitive to domain size in several respects: (1) the mean bias relative to the AGCM is similar for all three domains; (2) the variability simulated by the RCM is strongly correlated with that of the driving AGCM on both daily and seasonal time scales, even for the largest domain; (3) the mesoscale features and ISOs are not damped by the relative proximity of the lateral boundaries in the version with the smallest domain. Results (1) and (2) contrast strongly with a previous study for Europe carried out with the same model, probably due to inherent differences between mid-latitude and tropical dynamics. 相似文献
12.
Ramón de Elía Daniel Caya Hélène Côté Anne Frigon Sébastien Biner Michel Giguère Dominique Paquin Richard Harvey David Plummer 《Climate Dynamics》2008,30(2-3):113-132
This work is a first step in the analysis of uncertainty sources in the RCM-simulated climate over North America. Three main
sets of sensitivity studies were carried out: the first estimates the magnitude of internal variability, which is needed to
evaluate the significance of changes in the simulated climate induced by any model modification. The second is devoted to
the role of CRCM configuration as a source of uncertainty, in particular the sensitivity to nesting technique, domain size,
and driving reanalysis. The third study aims to assess the relative importance of the previously estimated sensitivities by
performing two additional sensitivity experiments: one, in which the reanalysis driving data is replaced by data generated
by the second generation Coupled Global Climate Model (CGCM2), and another, in which a different CRCM version is used. Results
show that the internal variability, triggered by differences in initial conditions, is much smaller than the sensitivity to
any other source. Results also show that levels of uncertainty originating from liberty of choices in the definition of configuration
parameters are comparable among themselves and are smaller than those due to the choice of CGCM or CRCM version used. These
results suggest that uncertainty originated by the CRCM configuration latitude (freedom of choice among domain sizes, nesting
techniques and reanalysis dataset), although important, does not seem to be a major obstacle to climate downscaling. Finally,
with the aim of evaluating the combined effect of the different uncertainties, the ensemble spread is estimated for a subset
of the analysed simulations. Results show that downscaled surface temperature is in general more uncertain in the northern
regions, while precipitation is more uncertain in the central and eastern US. 相似文献
13.
Abstract The Canadian Regional Climate Model (CRCM) has been nested within the Canadian Centre for Climate Modelling and Analysis ‘ second generation General Circulation Model (GCM), for a single month simulation over the Mackenzie River Basin and environs. The purpose of the study is to assess the ability of the higher resolution CRCM to downscale the hydrological cycle of the nesting GCM. A second 1‐month experiment, in which the CRCM was nested within analyzed fields of a global data assimilation system, was also performed to examine the sensitivity of the basin moisture budget to atmospheric lateral boundary forcing. We have found that the CRCM can produce realistic lee cyclogenesis, preferentially in the Liard sub‐basin, along with associated circulation and precipitation patterns, as well as an improved rainshadow in the lee of the Rocky Mountains compared to the GCM. While these features do quantitatively affect the monthly average climate statistics, the basin scale moisture budgets of the models were remarkably similar, though some of this agreement is due to compensating errors in the GCM. Both models produced excessive precipitation compared to a recent climatology for the region, the cause of which is traced to lateral boundary forcing. A second experiment, identical to the first except that the CRCM was forced with analyzed fields at the lateral boundaries, produced a qualitatively different basin moisture budget, including a much more realistic precipitation field. Errors in the moisture budget of the first experiment appear to be associated with the poor representation of the Aleutian Low in the GCM, and do not appear to be strongly connected to (local) surface processes within the models. This suggests that an effective strategy for modelling the hydrological cycle of the Mackenzie Basin on the fast climate timescale ‐ a major requirement of the Mackenzie GEWEX Study ‐ will involve nesting the CRCM within analyzed (or re‐analyzed) atmospheric fields. 相似文献
14.
Charles L. Curry Bárbara Tencer Kirien Whan Andrew J. Weaver Michel Giguère Edward Wiebe 《大气与海洋》2016,54(4):364-384
We evaluate the capacity of a regional climate model to represent observed extreme temperature and precipitation events and also examine the impact of increased resolution, in an effort to identify added value in this respect. Two climate simulations of western Canada (WCan) were conducted with the Canadian Regional Climate Model (version 4) at 15 (CRCM15) and 45?km (CRCM45) horizontal resolution driven at the lateral boundaries by data from the European Centre for Medium-range Weather Forecasts (ECMWF) 40-year Reanalysis (ERA-40) for the period 1973–1995. The simulations were evaluated using the spline-interpolated dataset ANUSPLIN, a daily observational gridded surface temperature and precipitation product with a nominal resolution of approximately 10?km. We examine a range of climate extremes, comprising the 10th and 90th percentiles of daily maximum (TX) and minimum (TN) temperatures, the 90th percentile of daily precipitation (PR90), and the 27 core Climate Daily Extremes (CLIMDEX) indices.Both simulations exhibit cold biases compared with observations over WCan, with the bias exacerbated at higher resolution, suggesting little added value for temperature overall. There are instances, however, of regional improvement in the spatial pattern of temperature extremes at the higher resolution of CRCM15 (e.g., the CLIMDEX index for the annual number of days when TX?>?25°C). The high-resolution simulations also reveal similarly localized features in precipitation (e.g., rain shadows) that are not resolved at the 45?km resolution. With regard to precipitation extremes, although both simulations generally display wet biases, CRCM15 features a reduced bias in PR90 in all seasons except winter. This improvement occurs despite the fact that spatial and interannual variability of PR90 in CRCM15 is significantly overestimated relative to both CRCM45 and ANUSPLIN. We posit that these characteristics are the result of demonstrable differences between corresponding topographical datasets used in the gridded observations and CRCM, the resulting errors propagated to physical variables tied to elevation and the beneficial effect of subsequent spatial averaging. Because topographical input is often discordant between simulations and gridded observations, it is argued that a limited form of spatial averaging may contribute added value beyond that which has already been noted in previous studies with respect to small-scale climate variability. 相似文献
15.
Kevin HAMILTON 《大气科学进展》2006,23(6):842-856
An informal review is presented of recent developments in numerical simulation of the global atmospheric circulation with very fine numerical resolution models. The focus is on results obtained recently with versions of the GFDL SKYHI model and the Atmospheric Model for the Earth Simulator (AFES) global atmospheric models. These models have been run with effective horizontal grid resolution of 10–40 km and fine vertical resolution. The results presented demonstrate the utility of such models for the study of a diverse range of phenomena. Specifically the models are shown to simulate the development of tropical cyclones with peak winds and minimum central pressures comparable to those of the most intense hurricanes actually observed. More fundamentally, the spectrum of energy content in the mesoscale in the flow can be reproduced by these models down to near the smallest explicitly-resolved horizontal scales. In the middle atmosphere it is shown that increasing horizontal resolution can lead to significantly improved overall simulation of the global-scale circulation. The application of the models to two specific problems requiring very fine resolution global will be discussed. The spatial and temporal variability of the vertical eddy flux of zonal momentum associated with gravity waves near the tropopause is evaluated in the very fine resolution AFES model. This is a subject of great importance for understanding and modelling the flow in the middle atmosphere. Then the simulation of the small scale variations of the semidiurnal surface pressure oscillation is analyzed, and the signature of significant topographic modulation of the semidiurnal atmospheric tide is identified. 相似文献
16.
In this study, we investigate the response of a Regional Climate Model (RCM) to errors in the atmospheric data used as lateral
boundary conditions (LBCs) using a perfect-model framework nick-named the “Big-Brother Experiment” (BBE). The BBE has been
designed to evaluate the errors due to the nesting process excluding other model errors. First, a high-resolution (45 km)
RCM simulation is made over a large domain. This simulation, called the Perfect Big Brother (PBB), is driven by the National
Centres for Environmental Prediction (NCEP) reanalyses; it serves as reference virtual-reality climate to which other RCM
runs will be compared. Next, errors of adjustable magnitude are introduced by performing RCM simulations with increasingly
larger domains at lower horizontal resolution (90 km mesh). Such simulations with errors typical of today’s Coupled General
Circulation Models (CGCM) are called the Imperfect Big-Brother (IBB) simulations. After removing small scales in order to
achieve low-resolution typical of today’s CGCMs, they are used as LBCs for driving smaller domain high-resolution RCM runs;
these small-domain high-resolution simulations are called Little-Brother (LB) simulations. The difference between the climate
statistics of the IBB and those of PBB simulations mimic errors of the driving model. The comparison of climate statistics
of the LB to those of the PBB provides an estimate of the errors resulting solely from nesting with imperfect LBCs. The simulations
are performed over the East Coast of North America using the Canadian RCM, for five consecutive February months (from 1990
to 1994). It is found that the errors contained in the large scales of the IBB driving data are transmitted to and reproduced
with little changes by the LB. In general, the LB restores a great part of the IBB small-scale errors, even if they do not
take part in the nesting process. The small scales are seen to improve slightly in regions with important orographic forcing
due to the finer resolution of the RCM. However, when the large scales of the driving model have errors, the small scales
developed by the LB have errors as well, suggesting that the large scales precondition the small scales. In order to obtain
correct small scales, it is necessary to provide the accurate large-scale circulation at the lateral boundary of the RCM. 相似文献
17.
Evaluation of regional climate model simulations versus gridded observed and regional reanalysis products using a combined weighting scheme 总被引:1,自引:0,他引:1
This study presents a combined weighting scheme which contains five attributes that reflect accuracy of climate data, i.e. short-term (daily), mid-term (annual), and long-term (decadal) timescales, as well as spatial pattern, and extreme values, as simulated from Regional Climate Models (RCMs) with respect to observed and regional reanalysis products. Southern areas of Quebec and Ontario provinces in Canada are used for the study area. Three series of simulation from two different versions of the Canadian RCM (CRCM4.1.1, and CRCM4.2.3) are employed over 23?years from 1979 to 2001, driven by both NCEP and ERA40 global reanalysis products. One series of regional reanalysis dataset (i.e. NARR) over North America is also used as reference for comparison and validation purpose, as well as gridded historical observed daily data of precipitation and temperatures, both series have been beforehand interpolated on the CRCM 45-km grid resolution. Monthly weighting factors are calculated and then combined into four seasons to reflect seasonal variability of climate data accuracy. In addition, this study generates weight averaged references (WARs) with different weighting factors and ensemble size as new reference climate data set. The simulation results indicate that the NARR is in general superior to the CRCM simulated precipitation values, but the CRCM4.1.1 provides the highest weighting factors during the winter season. For minimum and maximum temperature, both the CRCM4.1.1 and the NARR products provide the highest weighting factors, respectively. The NARR provides more accurate short- and mid-term climate data, but the two versions of the CRCM provide more precise long-term data, spatial pattern and extreme events. Or study confirms also that the global reanalysis data (i.e. NCEP vs. ERA40) used as boundary conditions in the CRCM runs has non-negligible effects on the accuracy of CRCM simulated precipitation and temperature values. In addition, this study demonstrates that the proposed weighting factors reflect well all five attributes and the performances of weighted averaged references are better than that of the best single model. This study also found that the improvement of WARs’ performance is due to the reliability (accuracy) of RCMs rather than the ensemble size. 相似文献
18.
Summary The effects of varying horizontal and vertical grid resolution on the numerical simulation of upper-tropospheric frontal structures are examined using a, two-dimensional, dry, hydrostatic sigma-coordinate primitive equation model. These effects are illustrated with the results of 72 h model integrations in which frontogenesis is forced solely by confluence. Four different horizontal grid spacings, ranging from 100 km to 12.5 km, and four different vertical, grid resolutions, varying from 10 to 70 layers (90 mb to 13 mb), are considered.The intensity and integrity of the frontogenesis as a function of grid resolution are diagnosed in terms of time histories and spatial distributions of frontal parameters, such as the speed of the along-front jet, maxima of absolute vorticity and potential temperature gradient, and ageostrophic motions. The time histories show that, provided the vertical resolution is sufficient, increasing horizontal resolution leads to better-defined frontal structure due to the decrease in cross-frontal scale. They also indicate that for a given horizontal resolution there exists an optimal vertical resolution beyond which frontal parameters change only slightly. This optimal vertical resolution increases with increasing horizontal resolution, and apparently is related to the horizontal resolution through the slope of the frontal zone.The time histories for simulations combining low vertical resolution with high horizontal resolution exhibit substantial high-frequency variability. Cross sections show that this temporal variability appears to be manifested spatially in the form of gravity waves characterized by wavelengths on the order of 200 km and periods of 12 h, over the range of horizontal and vertical resolution that is considered. Although the source mechanism for these waves cannot be established definitively, it likely involves a grid-induced ageostrophic component of the along-front wind which disrupts thermal wind balance. This results thus demonstrates the potential risk of flawed frontal simulations, when incompatible combinations of horizontal and vertical resolution are used.With 7 Figures 相似文献
19.
Effects of Mesoscale Surface Thermal Heterogeneity on Low-Level Horizontal Wind Speeds 总被引:2,自引:2,他引:0
Using large-eddy simulation, we investigate characteristics of horizontal wind speed at 100 m above the ground, with surface
heat-flux variations that are sinusoidal with amplitudes of 0, 50, and 200 W m−2 and wavelengths of 16, 32, and 128 km, and no background flow. When the amplitude is 200 W m−2, wind speeds induced by the surface-flux variations on scales of 16 and/or 32 km have multiple temporal oscillations from
0600 to 1800 local standard time. The positive peaks first appear before noon. In contrast, for wind speeds induced by the
128-km surface heterogeneity, a single oscillation occurs in the late afternoon, which is much larger than those generated
by the 16- and 32-km surface heterogeneity. In addition, at the oscillation onset the kurtosis of the velocity increment over
a distance of 1 km significantly increases, which implies intermittency in the generation of 1-km scale eddies. The spatially
intermittent energy cascade generated by surface heterogeneity scaled down to 1-km eddies is analogous to the well-known intermittent
energy cascade in the inertial subrange. The kurtosis of the 1-km eddies is much larger with the 128-km surface heterogeneity
than with the 16- and 32-km heterogeneities. Thus we conclude that localized rapid changes of low-level horizontal wind speed
may be caused by significant local surface heterogeneity on scales between a few tens and a few hundreds of kilometres. 相似文献
20.
Variability of Sub-Canopy Flow,Temperature, and Horizontal Advection in Moderately Complex Terrain 总被引:1,自引:1,他引:0
We examine the space–time structure of the wind and temperature fields, as well as that of the resulting spatial temperature
gradients and horizontal advection of sensible heat, in the sub-canopy of a forest with a dense overstorey in moderately complex
terrain. Data were collected from a sensor network consisting of ten stations and subject to orthogonal decomposition using
the multiresolution basis set and stochastic analyses including two-point correlations, dimensional structure functions, and
various other bulk measures for space and time variability. Despite some similarities, fundamental differences were found
in the space–time structure of the motions dominating the variability of the sub-canopy wind and temperature fields. The dominating
motions occupy similar spatial, but different temporal, scales. A conceptual space–time diagram was constructed based on the
stochastic analysis that includes the important end members of the spatial and temporal scales of the observed motions of
both variables. Short-lived and small-scale motions govern the variability of the wind, while the diurnal temperature oscillation
driven by the surface radiative transfer is the main determinant of the variability in the temperature signal, which occupies
much larger time scales. This scale mismatch renders Taylor’s hypothesis for sub-canopy flow invalid and aggravates the computation
of meaningful estimates of horizontal advective fluxes without dense spatial information. It may further explain the ambiguous
and inconclusive results reported in numerous energy and mass balance and advection studies evaluating the hypothesis that
accounting for budget components other than the change in storage term and the vertical turbulent flux improves the budget
closure when turbulent diffusion is suppressed in plant canopies. Estimates of spatial temperature gradients and advective
fluxes were sensitive to the network geometry and the spatial interpolation method. The assumption of linear spatial temperature
gradients was not supported by the results, and leads to increased spatial and temporal variability of inferred spatial gradients
and advection estimates. A method is proposed to estimate the appropriate minimum network size of wind and temperature sensors
suitable for an evaluation of energy and mass balances by reducing spatial and temporal variability of the spatially sampled
signals, which was estimated to be on the order of 200 m at the study site. 相似文献