How changing grain size affects the land surface temperature pattern in rapidly urbanizing area: a case study of the central urban districts of Hangzhou City, China
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How changing grain size affects the land surface temperature pattern in rapidly urbanizing area : a case study of the central urban districts of Hangzhou City, China. / Yuan, Shaofeng; Xia, Hao; Yang, Lixia.
In: Environmental Science and Pollution Research, Vol. 28, No. 30, 08.2021, p. 40060-40074.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - How changing grain size affects the land surface temperature pattern in rapidly urbanizing area
T2 - a case study of the central urban districts of Hangzhou City, China
AU - Yuan, Shaofeng
AU - Xia, Hao
AU - Yang, Lixia
N1 - Funding Information: This research is supported by the National Natural Science Foundation of China (No. 41871181), the Project of Human Social Science of the Ministry of Education of China (No. 18YJA630136, 19YJA630099), and the Philosophy and Social Sciences Study Foundation of Zhejiang Province (No. 19NDJC015Z). Publisher Copyright: © 2020, Springer-Verlag GmbH Germany, part of Springer Nature.
PY - 2021/8
Y1 - 2021/8
N2 - Urbanization has led to the rapid and large-scale changes in land use and land cover and has affected the spatial distribution of land surface temperature (LST) in urban areas. Studying the LST pattern and their spatial heterogeneity characteristics at different scales can help understand the dynamic mechanism of the thermal landscape and provide insights into urban ecological planning. We utilized transfer matrixes, landscape metrics, and spatial autocorrelation analyses to study the transfer of LST classes, changes in the LST pattern, and changes in LST clusters with varying grain sizes by taking the central urban districts of Hangzhou City in China as a case study. Results indicate that (1) the transfer proportion of the LST classes increased, except for high-temperature class, and each LST class shifted to the adjacent dominant LST class with the increase in grain size. (2) The landscape metrics remarkably changed as the grain size increased, indicating that the LST pattern was scale-dependent. As the grain size increased, the small patches gradually merged into large patches; the fragmentation, complexity, and ductility of the urban thermal landscapes decreased; and the shape of the patches became simple and regular. (3) The LST pattern exhibited a positive spatial autocorrelation. The area of low–low cluster decreased, whereas that of non-significant clusters substantially increased with the grain size. The area of high–high cluster remained steady when the grain size exceeded 90 m. (4) Patch density, mean patch fractal dimension, clumpiness index, and contagion index exhibited predictable responses to changing grain size, whereas Shannon’s diversity and Shannon’s evenness indexes showed erratic responses, indicating that the diversity and evenness of the LST pattern were not scale-dependent. (5) The suitable domain of scale for the analysis of LST pattern was (60, 120), and the optimal grain size was 120 m. The selection of domains of scale and optimal grain size need to be determined according to the changes in thermal landscape patterns at different grain sizes and regional environments.
AB - Urbanization has led to the rapid and large-scale changes in land use and land cover and has affected the spatial distribution of land surface temperature (LST) in urban areas. Studying the LST pattern and their spatial heterogeneity characteristics at different scales can help understand the dynamic mechanism of the thermal landscape and provide insights into urban ecological planning. We utilized transfer matrixes, landscape metrics, and spatial autocorrelation analyses to study the transfer of LST classes, changes in the LST pattern, and changes in LST clusters with varying grain sizes by taking the central urban districts of Hangzhou City in China as a case study. Results indicate that (1) the transfer proportion of the LST classes increased, except for high-temperature class, and each LST class shifted to the adjacent dominant LST class with the increase in grain size. (2) The landscape metrics remarkably changed as the grain size increased, indicating that the LST pattern was scale-dependent. As the grain size increased, the small patches gradually merged into large patches; the fragmentation, complexity, and ductility of the urban thermal landscapes decreased; and the shape of the patches became simple and regular. (3) The LST pattern exhibited a positive spatial autocorrelation. The area of low–low cluster decreased, whereas that of non-significant clusters substantially increased with the grain size. The area of high–high cluster remained steady when the grain size exceeded 90 m. (4) Patch density, mean patch fractal dimension, clumpiness index, and contagion index exhibited predictable responses to changing grain size, whereas Shannon’s diversity and Shannon’s evenness indexes showed erratic responses, indicating that the diversity and evenness of the LST pattern were not scale-dependent. (5) The suitable domain of scale for the analysis of LST pattern was (60, 120), and the optimal grain size was 120 m. The selection of domains of scale and optimal grain size need to be determined according to the changes in thermal landscape patterns at different grain sizes and regional environments.
KW - Central urban district
KW - Grain size
KW - Hangzhou
KW - Land surface temperature
KW - Landscape metric
KW - Scale effect
KW - Thermal landscape pattern
UR - http://www.scopus.com/inward/record.url?scp=85084077082&partnerID=8YFLogxK
U2 - 10.1007/s11356-020-08672-w
DO - 10.1007/s11356-020-08672-w
M3 - Journal article
C2 - 32314291
AN - SCOPUS:85084077082
VL - 28
SP - 40060
EP - 40074
JO - Environmental Science and Pollution Research
JF - Environmental Science and Pollution Research
SN - 0944-1344
IS - 30
ER -
ID: 305118325