The influence of seasonal land-use-land-cover transformation on thermal characteristics within the city of Pietermaritzburg

IF 0.3 Q4 REMOTE SENSING South African Journal of Geomatics Pub Date : 2020-09-14 DOI:10.4314/sajg.v9i2.23
J. Odindi
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引用次数: 1

Abstract

Urbanisation has been identified as a major threat to the environment as it increases demand for urban spaces and transforms natural landscapes to impervious surfaces, leading to the Urban Heat Island (UHI) phenomenon. Natural landscapes such as vegetation and water bodies act as thermal sinks that absorb heat while impervious surfaces such as buildings and concrete pavements act as thermal sources that retain and emit heat. The thermal emission results in several negative effects such as temperature inversion, compromised human health, pollution, species loss, high energy consumption and climate change at a local, regional and global scales. Whereas studies on UHI are abound, there is paucity in literature on the influence of seasonal urban Land Use Land Cover (LULC) transformation on urban thermal characteristics. Specifically, the proportional seasonal variability and contribution of individual LULCs to urban heat is often poorly understood. Using the freely available Landsat 8 optical and thermal bands, this study examined the seasonal characteristics of the UHI phenomenon in relation to LULCs in the Pietermaritzburg city, South Africa. Results in this study revealed that UHIs exist in both winter and summer, but with more intensity in summer. The study also established that LULCs varied with seasons. Bare surfaces and dense vegetation had the most thermal influence during winter while dense vegetation and low density buildings had the most thermal influence during summer. These findings provide a better understanding of thermal distribution based on LULC seasonality changes, valuable for sustainable urban planning and climate change mitigation.
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彼得马里茨堡城市土地利用-土地覆盖季节变化对热特征的影响
城市化已被确定为对环境的主要威胁,因为它增加了对城市空间的需求,并将自然景观转变为不透水的表面,导致了城市热岛现象。植被和水体等自然景观充当吸热的散热器,而建筑物和混凝土路面等不透水表面充当保温和散热的热源。热排放在地方、区域和全球范围内造成了一些负面影响,如温度倒置、人类健康受损、污染、物种损失、高能源消耗和气候变化。尽管对UHI的研究很多,但关于季节性城市土地利用-土地覆盖(LULC)变化对城市热特性的影响的文献却很少。具体而言,人们往往对各个LULC对城市热量的比例季节变化和贡献知之甚少。本研究使用免费提供的Landsat 8光学和热波段,研究了南非彼得马里茨堡市UHI现象与LULC的季节特征。这项研究的结果表明,UHIs在冬季和夏季都存在,但在夏季强度更大。该研究还证实,LULC随季节而变化。裸露的地表和茂密的植被在冬季受热影响最大,而茂密的植被和低密度的建筑物在夏季受热影响最大。这些发现提供了对基于LULC季节性变化的热分布的更好理解,对可持续城市规划和减缓气候变化有价值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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