利用地球观测资料研究德里城市能量通量的长期时空变化

Q2 Social Sciences

The International Archives of the Photogrammetry Remote Sensing and Spatial Information Sciences Pub Date : 2023-09-05 DOI:10.5194/isprs-archives-xlviii-m-3-2023-49-2023

M. Bondada, K. Gupta, A. Danodia, M. Bhatt, N. R. Patel

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引用次数: 0

摘要

摘要德里的快速城市化和人口增长导致土地和土地覆盖发生了重大变化，导致排放量增加，城市能源平衡发生了变化。为了了解这些长期趋势并确定影响因素，使用陆地卫星系列数据和ECMWF ERA-5再分析的气象数据进行了一项研究。该研究侧重于估算城市能量通量，包括净辐射、感热通量、潜热通量和地热通量，并将人为热量视为残差。研究结果显示，人为热通量大幅增加，从1990年的172 W/m2上升到2022年的281 W/m2。还观察到季节变化，最高的能量通量值出现在夏季，其次是季风后和冬季。净辐射范围为650至700 W/m2，显热通量范围为250至300 W/m2，潜热通量范围为250-300 W/m2，地热通量范围为30-120 W/m2。城市地区表现出较高的能源通量，强调了有效规划干预措施对减少这些地区排放的重要性。该研究强调了基于地球观测的方法在估计和平衡城市能源通量方面的潜力，同时强调在制定减少城市地区排放的战略时，需要考虑土地利用模式的季节和空间变化。

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LONG TERM SPATIO-TEMPORAL VARIATIONS OF URBAN ENERGY FLUXES USING EARTH OBSERVATION DATA FOR DELHI

Abstract. The rapid urbanization and population growth in Delhi have led to significant changes in the land and land cover, resulting in increased emissions and alterations in the urban energy balance. To understand these long-term trends and identify contributions factors, a study was conducted using Landsat series data and meteorological data from the ECMWF ERA-5 reanalysis. The study focused on estimating urban energy fluxes, including Net Radiation, Sensible heat flux, Latent heat flux and Ground heat flux with anthropogenic heat considered as the residual. The findings reveal a substantial increase in the anthropogenic heat flux, rising from 172 W/m2 in 1990 to 281 W/m2 in 2022. Seasonal variations were also observed, with the highest energy flux values occurring during the summer season, followed by post monsoon and winter season. Net radiation ranged from 650 to 700 W/m2, sensible heat flux ranged between 250–300 W/m2, latent heat flux ranged between 250–300 W/m2 and ground heat flux ranged 30–120 W/m2. Urban areas exhibited higher energy fluxes, emphasizing the importance of effective planning interventions to mitigate emissions in such areas. The study highlights the potential of Earth observation based approaches in estimating and balancing urban energy fluxes, while also emphasising the need to consider seasonal and spatial variations in the land use pattern when formulating strategies to mitigate emissions in the urban areas.

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来源期刊

The International Archives of the Photogrammetry Remote Sensing and Spatial Information Sciences Social Sciences-Geography, Planning and Development

CiteScore

1.70

自引率

0.00%

发文量

949

审稿时长

16 weeks