南京夏季城市热岛时空分布特征的观测分析

利用2010年南京夏季城市热岛三维观测试验资料,分析了南京夏季典型天气条件下城市热岛的时空分布特征。结果表明,南京夏季高温晴天日平均热岛强度达1℃以上,夜间热岛强度稳定且强于白天,热岛分布具有方向性特征并与城市土地利用现状对应较好。白天,城市大气混合层的发展速度和高度均大于郊区;夜间,由于城市大气层结的不稳定及下垫面的粗糙特性,致使城市低空始终存在着一个对流混合层,其高度至少有250 m。城市下垫面高热量储存和强湍流输送的共同作用形成边界层内热岛,热岛强度总体上随高度递减,影响高度在白天约900 m、夜间约300 m。     

晋江市海陆风对城市热岛的影响

利用2017年晋江市及其周边共27个自动气象站逐小时气象资料,分析了2017年晋江城市热岛强度的日变化及有无海陆风对城市热岛强度的影响,同时研究了不同季节海陆风风速对城市热岛强度的影响,最后通过典型个例海陆风日验证了晋江城市热岛的日变化特征。结果表明:晋江市全年平均热岛强度的日变化趋势呈“V”字型分布;海风能使城市降温,减弱城市热岛强度,而陆风能使夜间热岛显著增强,故与非海陆风日相比,海陆风日热岛强度的日变化幅度增大;热岛强度与海陆风风速呈负相关,海陆风风速越大对城市热岛有一定的缓解作用。     

基于Landsat TM/ETM＋数据的北京城市热岛季节特征研究

利用1988—2006年20景LandsatTM和ETM＋数据分析了北京市城市热岛的季节变化特征。通过反演地表温度,建立统一的城市和农村区域,计算了城市热岛强度,并采用多项式拟合获取了城市热岛强度的季节变化曲线;同时,分析了热岛强度季节特征与气候因子的关系。另外利用4景2005—2006年不同季节Landsat TM影像,分析了不同季节城市热岛的空间变化特征,并选择穿越北京城区的两条不同方向剖线（SE-NW和SW-NE）,分析了沿剖线方向城市热岛与地表类型的关系。结果显示,北京城市热岛具有明显的季节变化特征,与总云量的季节变化关系显著。最大热岛强度出现在夏季,呈现片状发散和零星热岛并存的空间分布特征。冬季为冷岛特征,其空间分布与夏季热岛一致。春秋两季热岛强度最小,但春季热岛空间差异较大。在相同季节,城市热岛强度和空间尺度在不同剖线方向具有明显的差异,这与不同地类的空间分布有关。     

基于MODIS资料分析近15年广州城市热岛特征及演变规律

利用MODIS地表温度数据,计算城市热岛强度指数,分析近15年广州市城市热岛的时空分布特征及演变规律,并结合气象观测数据、社会统计数据定性分析其主要影响因素。结果表明:广州市城市热岛的空间分布受地形地貌影响明显,负热岛区主要分布于森林密集的北部山区,无热岛区主要分布于中部低山丘陵区域,热岛区主要分布于高度城市化的中南部平原区。关于城市热岛的日变化规律,白天热岛区、负热岛区面积均小于夜间,但白天热岛区强度、负热岛区强度大于夜间。关于城市热岛的季节变化规律,冬季热岛区面积最大,热岛强度最小,夏季热岛区面积最小,热岛强度最大;冬季负热岛区面积最小,负热岛强度最小,夏季负热岛区面积最大,负热岛强度最大。对于城市热岛的年际变化规律,近15年来广州市的热岛区、负热岛区占全市总面积的百分比呈上升趋势,无热岛区所占百分比呈下降趋势,人为热排放在城市中心区域的持续增长,加上区内建筑物密度大、植被覆盖度低,导致了热岛区的增加,而北部山区至中部丘陵山区的植被的持续好转,加上地理特征限制了该区域的城市化发展,导致了负热岛区的增加。      

基于ＬａｎｄｓａｔＴＭ／ＥＴＭ ＋数据的北京城市热岛季节特征研究

利用１９８８—２００６年２０景ＬａｎｄｓａｔＴＭ和ＥＴＭ＋数据分析了北京市城市热岛的季节变化特征。通过反演地表温度,建立统一的城市和农村区域,计算了城市热岛强度,并采用多项式拟合获取了城市热岛强度的季节变化曲线;同时,分析了热岛强度季节特征与气候因子的关系。另外利用４景２００５—２００６年不同季节ＬａｎｄｓａｔＴＭ影像,分析了不同季节城市热岛的空间变化特征,并选择穿越北京城区的两条不同方向剖线（ＳＥ ＮＷ 和ＳＷ ＮＥ）,分析了沿剖线方向城市热岛与地表类型的关系。结果显示,北京城市热岛具有明显的季节变化特征,与总云量的季节变化关系显著。最大热岛强度出现在夏季,呈现片状发散和零星热岛并存的空间分布特征。冬季为冷岛特征,其空间分布与夏季热岛一致。春秋两季热岛强度最小,但春季热岛空间差异较大。在相同季节,城市热岛强度和空间尺度在不同剖线方向具有明显的差异,这与不同地类的空间分布有关。     

基于多源融合资料分析北京一次超强城市热岛三维结构特征

城市热岛效应是人类活动对大气系统影响的最主要体现之一。本文利用(Space and Time Multiscale Analysis System, STMAS)时空多尺度分析系统,融合了地面自动站、雷达、卫星等多源高时空分辨率观测资料,建立了城市热岛三维数据集。并在此基础上统计了2021年北京夏季的城市热岛强度变化特征,选取其中一次超强城市热岛个例(2021年6月11—12日)详细分析了其三维精细化结构特征。结果表明：(1)本个例中,夜间郊区近地面迅速降温,形成逆温层;而城市近地面降温缓慢,使得近地面城郊温差不断增大。(2)本次超强城市热岛三维温度场暖心结构在地面和990 hPa以下低空等压面清晰可见,风场距平呈现气旋性环流特征并在低空从郊区向城区辐合,引起可到达中高空的上升运动,说明城市热岛效应有增强垂直环流的作用。     

大庆市热岛特征及人工增雨需求的可行分析

利用大庆市2个国家站和5个区域气象站的气温、风速、云量资料对大庆市热岛特征进行了分析,结果表明:1991-2012年大庆市热岛强度的年平均值为0.3℃,城市热岛强度较弱,近几年呈显著增强趋势;大庆市热岛效应强度存在冬季强,春秋弱,夏季无热岛效应的特点,热岛效应最强出现在1月份,热岛效应最弱出现在6月份;1-6月热岛强度呈单调下降趋势;7-12月热岛强度呈单调上升趋势;大庆市热岛强度的日变化特征具有夜间强白天弱、快生快消、难以维持24 h的特点;城市热岛效应与云量、风速呈明显的负相关;晴天和较阴天容易出现城市热岛效应,热岛强度晴天强于阴天;城市热岛一般出现在风力1-3级的条件下,当风力3级时,城市热岛消失;在气象条件满足的情况下,充分利用"热岛效应"增加的低云开展人工增雨,可缓解热岛效应给城市带来的不利影响。     

本溪地区温度场结构的客观分析方法研究

用客观分析方法研究本溪地区温度场结构，揭示城市热岛、热岛混合层、城市地面热岛和高空冷岛、城市垂直热岛、城市垂直冷岛存在的事实，为制定本溪地区环境综合整治提供依据。     

本溪地区温度场结构的客观分析方法研究

用客观分析方法研究本溪地区温度场结构 ,揭示城市热岛、热岛混合层、城市地面热岛和高空冷岛、城市垂直热岛、城市垂直冷岛存在的事实 ,为制定本溪地区环境综合整治提供依据。     

天津地区夏季海陆风对城市热岛日变化特征影响的观测分析

应用2008年天津市14个自动气象站逐小时观测资料、北京站探空资料和天津站6h一次的地面常规观测资料,分析了2008年天津地区夏季海陆风对城市热岛日变化特征的影响.结果表明:在大气层结稳定条件下,海陆风日与非海陆风日相比,天津市热岛强度的日变化幅度增大,海风能使城市降温,削弱城市热岛强度,推迟夜间热岛的出现时间,而陆风能使夜间热岛显著增强;天津市热岛强度与海风向内陆传播的距离有密切关系,在海陆风日,当天气尺度地转风与离岸风的方向一致时,海风的传播距离较近,而当天气尺度地转风与向岸风方向一致时,海风的传播距离较远,当海风只能到达津南、东丽或宁河站时,天津市热岛强度增幅最大,随着海风传播距离的增加,热岛强度的总体增幅减小.     

The New Canadian Urban Modelling System: Evaluation for Two Cases from the Joint Urban 2003 Oklahoma City Experiment

A new Canadian numerical urban modelling system has been developed at the Meteorological Service of Canada to represent surface and boundary-layer processes in the urban environment. In this system, urban covers are taken into account by including the Town Energy Balance urban-canopy parameterization scheme in the Global Environmental Multiscale meteorological model. The new modelling system is run at 250-m grid size for two intensive observational periods of the Joint Urban 2003 experiment that was held in Oklahoma City, U.S.A. An extensive evaluation against near-surface and upper-air observations has been performed. The Town Energy Balance scheme correctly simulates the urban micro-climate, more particularly the positive nighttime urban heat island, and also reproduces the “cool” island during the morning but does not succeed in maintaining it during all of the daytime period. The vertical structure of the boundary layer above the city is reasonably well simulated, but the simulation of the nocturnal boundary layer is difficult, due to the complex interaction with the nighttime southerly low-level jet that crosses the domain. Sensitivity tests reveal that the daytime convective boundary layer is mainly driven by dry soil conditions in and around Oklahoma City and that the nighttime low-level jet reinforces the urban heat island in the first 300m through large-scale advection, leading to the development of a less stable layer above the city.     

城市热岛效应对甘肃省温度序列的影响

对甘肃省若干国家基本/基准站、城市站和乡村站1961—2002年共42年季、年平均温度资料等进行了对比分析。结果表明:城市站和国家基本/基准站比乡村站增温趋势显著。近40多年来城市热岛效应对基本/基准站年平均温度的增温贡献率为18.5%,对城市站年平均温度的增温贡献率为37.6%。季节增温率冬季最大,秋季次之,春夏季最小;城市热岛效应对季节增暖的贡献率则为春季最大,夏季次之,秋冬季最小。     

复杂地形条件下城市热岛及局地环流特征的数值模拟

应用基于多层城市冠层方案BEP(Building Environment Parameterization)增加室内空调系统影响的建筑物能量模式BEM(Building Energy Model)方案的WRF模式,模拟研究重庆热岛的特征、成因以及局地环流对热岛形成的影响。文中共有两个算例,一为重庆真实下垫面算例,称之为URBAN算例,二为将城市下垫面替换为耕地下垫面的对比算例,称之为NOURBAN算例。结果表明:1)WRF方案模拟结果与观测2 m气温的对比吻合较好,误差主要出现在正午温度峰值和凌晨温度谷值处,由城市下垫面特性及城市内建筑分布误差引起。2)BEP+BEM方案较好地模拟出了重庆地区的热岛分布的空间和时间特征。重庆市温度的分布受地形和城市下垫面的双重影响,越靠近城区,温度的分布受城市化影响就越大,在海拔低处,温度就越高。3)城区立体三维表面对辐射的陷阱作用导致城市表面总体反射率小,向上短波辐射小于郊区约20 W/m~2。城市表面以感热排放为主,而郊区则表现为潜热的作用占主导。夜间城市地表储热以及空调废热向大气释放,是城市热岛形成的重要原因。4)模拟区域背景风场主要为东南风,局地环流呈现出越靠近山区风速越大、城市区域风速较小的特性,体现了城市密集的建筑群对低层大气流场的空气动力学效应,以及复杂山谷地形的山谷风环流特性。在市区的西侧和东南侧均有高大山脉阻挡,山脉对城市出流的阻碍作用、气流越山与绕流运动对城市热岛的形成有一定影响。     

Numerical simulation of the anthropogenic heat effect on urban boundary layer structure

In this paper, several methods of incorporating anthropogenic heat release into the boundary layer are compared. The best scheme was one that included anthropogenic heat release in both the surface energy balance equation and the thermodynamic equations. In addition, it included diurnal variations and a distribution of heat based on building concentrations. We further investigated the influence of anthropogenic heat release on urban boundary layer structure and the urban heat island, and found that the contribution of anthropogenic heat release to the urban heat island is greatest in the evening and at night, and least at noon. The daily average contribution ratio of anthropogenic heat to urban heat island intensity in the winter is 54.5%, compared with just 43.6% in the summer. Anthropogenic heat strengthens the vertical movement of urban surface air flow, changing the urban heat island circulation. It also makes the urban boundary layer more turbulent and unstable, especially in the morning and evening. The degree of influence of anthropogenic heat release on local boundary layer structure depends on its importance to the surface energy budget.     

Effects of boundary-layer stability on urban heat island-induced circulation

Summary The effects of atmospheric boundary-layer stability on urban heat island-induced circulation are numerically and theoretically investigated using a nonlinear numerical model (ARPS) and a two-layer linear analytical model. Numerical model simulations show that as the boundary layer becomes less stable, a downwind updraft cell induced by the urban heat island strengthens. It is also shown that as the boundary layer becomes less stable, both the height of the maximum updraft velocity and the vertical extent of the downwind updraft cell increase. Hence, in the daytime with a nearly neutral or less stable boundary layer the urban heat island-induced circulation can become strong, even though the urban heat island is weak. It is suggested that these findings can be a mechanism for urban-induced thunderstorms observed in the late afternoon or evening with a nearly neutral or less stable boundary layer. The boundary-layer stability affects the spatial distribution of scalar concentration through its influencing urban heat island-induced circulation. Analytical results from a two-layer model with different boundary-layer stabilities in the lower and upper layers are in general qualitatively consistent with the numerical simulation results, although the low-level maximum vertical velocity does not change monotonically with lower-layer stability.     

The impact of heat waves on surface urban heat island and local economy in Cluj-Napoca city,Romania

The association between heat waves and the urban heat island effect can increase the impact on environment and society inducing biophysical hazards. Heat stress and their associated public health problems are among the most frequent. This paper explores the heat waves impact on surface urban heat island and on the local economy loss during three heat periods in Cluj-Napoca city in the summer of 2015. The heat wave events were identified based on daily maximum temperature, and they were divided into three classes considering the intensity threshold: moderate heat waves (daily maximum temperature exceeding the 90th percentile), severe heat waves (daily maximum temperature over the 95th percentile), and extremely severe heat waves (daily maximum temperature exceeding the 98th percentile). The minimum length of an event was of minimum three consecutive days. The surface urban heat island was detected based on land surface temperature derived from Landsat 8 thermal infrared data, while the economic impact was estimated based on data on work force structure and work productivity in Cluj-Napoca derived from the data released by Eurostat, National Bank of Romania, and National Institute of Statistics. The results indicate that the intensity and spatial extension of surface urban heat island could be governed by the magnitude of the heat wave event, but due to the low number of satellite images available, we should consider this information only as preliminary results. Thermal infrared remote sensing has proven to be a very efficient method to study surface urban heat island, due to the fact that the synoptic conditions associated with heat wave events usually favor cloud free image. The resolution of the OLI_TIRS sensor provided good results for a mid-extension city, but the low revisiting time is still a drawback. The potential economic loss was calculated for the working days during heat waves and the estimated loss reached more than 2.5 mil. EUR for each heat wave day at city scale, cumulating more than 38 mil. EUR for the three cases considered.     

城市热岛效应研究进展

随着城市规模的高速发展和城市人口的急剧膨胀,因城市下垫面结构的急剧变化和城市人为热排放的迅速增加所引起的城市热岛效应已逐渐成为严重影响城市人居环境和居民健康的重要因素。城市热岛效应研究已成为城市气候和区域气候研究中的热点问题。为更好地研究城市热岛效应,及时追踪国内外最新进展,综述了城市热岛的概念和形成机制,重点介绍了地面气象资料观测法、遥感监测法和边界层数值模式模拟法等3种城市热岛效应研究方法,总结了城市热岛效应国内外最新研究进展。最后基于现有城市热岛效应研究不够完善和深入,研究过于简单化和表面化,尺度局限于宏观大尺度以及各种方法自身的局限性等不足,指出在未来的城市热岛效应研究中,应突破现有的大中尺度,注意结合高分辨率卫星遥感影像进行多尺度多平台监测以及综合考虑气溶胶粒子对辐射强迫的影响等。     

Temperature trends through urbanization in Metropolitan Washington,D.C., 1945–1979

Summary Annual and seasonal changes of the urban heat island magnitude in Washington, D.C. and a close-in suburb were analyzed for the period of 1945 through 1979. Monthly and annual mean temperature data, corrected for elevation, from three stations (National Airport, D.C.—downtown, Silver Spring, MD—suburban, and Beltsville, MD—rural) were evaluated by testing the statistical significance of temperature differences between the different data sets.The analysis indicated that the absolute heat island magnitudes have increased at the rate of 0.020 and 0.019 C/yr at Washington National Airport and Silver Spring, respectively during the study period. The differences between these two rates were not statistically significant at the 0.95 confidence level. However, the increase of the heat island magnitude from 1945 to 1979 at the suburban station was 20% greater than that at the downtown station. Those results indicate that as urbanization progresses, the suburban site, Silver Spring, has become incorporated into the Washington, D.C. urban heat island. The data also indicate that the magnitude of the heat island near the city center has continued to increase despite a significant population decrease since 1950.With 5 Figures     

城市效应对福州市气候的影响

计算了福州近４０多年来气温等要素的气候倾向率，揭示了福州气候的变化规律。通过城区和郊区的气候资料对比分析，发现福州城区存在着热岛，雨岛，干岛，浑浊岛等城市气候效应，同时还存在着雾和雷暴负效应的异常现象。最后用气象学原理论讨产生异常现象原因。