新泽西州当前和未来气候下的城市热岛特征

Cynthia Rosenzweig , William D. Solecki , Lily Parshall , Mark Chopping , Gregory Pope , Richard Goldberg
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引用次数: 158

摘要

由二氧化碳和其他温室气体排放增加引起的气候变化是一种长期的气候灾害,有可能改变大都市地区城市热岛的强度、时间格局和空间范围。特殊的气象条件——包括高温、低云量和低平均风速——往往会加剧热岛效应。对纽瓦克和卡姆登附近现有存档气候数据的分析表明,在过去的半个世纪里,城市与郊区/农村的温度差异。从陆地卫星热图像获得的每个站点的地表温度也被分析为热岛的空间格局。然后,在包括不同温室气体排放轨迹的一系列气候变化情景下,研究热岛效应与预估温度、风速和云量变化之间的潜在相互作用。这些情景包括《大城市东海岸气候变率和变化区域评估》中使用的情景和政府间气候变化专门委员会(IPCC)《排放情景特别报告》(SRES)中的A2和B2情景。纽瓦克和卡姆登的卫星地表温度和气象站气温记录都检测到了热岛效应。纽瓦克地区城市和非城市最低气温的平均差异为3.0°C,卡姆登为1.5°C。根据当前趋势的外推和选定的全球气候模式(GCMs)预估,案例研究地区的温度在本世纪将继续变暖,就像过去半个世纪一样。对全球气候情景的初步分析表明,在未来几十年,风速可能会下降,云量可能会增加。这些总体上较小的相互抵消的趋势表明,在气候变化下,城市与非城市之间的温差可能保持不变。全年总体变暖可能会延长城市-郊区热综合体的空间和时间维度。由于热浪频率和持续时间的增加与热岛效应的相互作用,与热有关的发病率和死亡率可能会增加。卡姆登和纽瓦克可能会遭受更高的温度,经历类似大流感的条件和极端温度的地区将会扩大。因此,在气候变暖的情况下,城市热岛相关的潜在危害可能会增加。
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Characterizing the urban heat island in current and future climates in New Jersey

Climate change caused by increased anthropogenic emissions of carbon dioxide (CO2) and other greenhouse gases is a long-term climate hazard with the potential to alter the intensity, temporal pattern, and spatial extent of the urban heat island (UHI) in metropolitan regions. Particular meteorological conditions—including high temperature, low cloud cover, and low average wind speed—tend to intensify the heat island effect. Analyses of existing archived climate data for the vicinities of Newark and Camden, New Jersey indicate urban to suburban/rural temperature differences over the previous half-century. Surface temperatures derived from a Landsat thermal image for each site were also analyzed for spatial patterns of heat islands. Potential interactions between the UHI effect and projected changes in temperature, wind speed, and cloud cover are then examined under a range of climate change scenarios, encompassing different greenhouse gas emissions trajectories. The scenarios include those utilized in the Metropolitan East Coast Regional Assessment of Climate Variability and Change and the A2 and B2 scenarios of the Intergovernmental Panel on Climate Change (IPCC) Special Report on Emissions Scenarios (SRES).

The UHI effect was detected in Newark and Camden in both satellite surface-temperature and meteorological station air-temperature records. The average difference in urban–nonurban minimum temperatures was 3.0 °C for the Newark area and 1.5 °C for Camden. Extrapolation of current trends and the selected global climate models (GCMs) project that temperatures in the case study areas will continue to warm in the current century, as they have over the past half-century. An initial analysis of global climate scenarios shows that wind speed may decline, and that cloud cover may increase in the coming decades. These generally small countervailing tendencies suggest that urban–nonurban temperature differences may be maintained under climate change.

Overall warmer conditions throughout the year may extend the spatial and temporal dimensions of the urban-suburban heat complex. The incidence of heat-related morbidity and mortality are likely to increase with interactions between the increased frequency and duration of heat waves and the UHI effect. Camden and Newark will likely be subjected to higher temperatures, and areas experiencing UHI-like conditions and temperature extremes will expand. Thus, urban heat island-related hazard potential is likely to increase in a warmer climate.

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