More than surface temperature: mitigating thermal exposure in hyper-local land system

V. Kelly Turner; Morgan L. Rogers; Yujia Zhang; Ariane Middel; Florian A. Schneider; Jonathan P. Ocón; Megs Seeley; John Dialesandro

doi:10.1080/1747423X.2021.2015003

Journal of Land Use Science (Jan 2022)

More than surface temperature: mitigating thermal exposure in hyper-local land system

V. Kelly Turner,
Morgan L. Rogers,
Yujia Zhang,
Ariane Middel,
Florian A. Schneider,
Jonathan P. Ocón,
Megs Seeley,
John Dialesandro

Affiliations

V. Kelly Turner: Department of Urban Planning, Luskin School of Public Affairs, USA
Morgan L. Rogers: Department of Urban Planning, Luskin School of Public Affairs, USA
Yujia Zhang: School of Geographical Sciences and Urban Planning, College of Liberal Arts and Sciences, Phoenix, Arizona, USA
Ariane Middel: School of Arts, Media and Engineering, Herberger Institute for Design and the Arts, USA
Florian A. Schneider: School of Arts, Media and Engineering, Herberger Institute for Design and the Arts, USA
Jonathan P. Ocón: Geography Department, College of Arts and Sciences, University of California, Los Angeles, USA
Megs Seeley: School of Geographical Sciences and Urban Planning, College of Liberal Arts and Sciences, Phoenix, Arizona, USA
John Dialesandro: Department of Urban Planning, Luskin School of Public Affairs, USA

DOI: https://doi.org/10.1080/1747423X.2021.2015003
Journal volume & issue: Vol. 17, no. 1
pp. 79 – 99

Abstract

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ABSTRACTRegional land surface temperature (LST) maps derived from remote sensing data are most available to cities to assess and respond to heat. Yet, LST only captures one dimension of urban climate. This study investigates the extent to which remote sensing derived estimates of LST are a proxy for multiple climate variables at hyper-local scales (<10s of meters). We compare remotely sensed estimates of LST (RS-LST) to field and simulated LST, MRT, and air temperature (AT), in a neighborhood in Tucson, Arizona, USA. We find that LST, MRT, and ST follow different diurnal trends masked by RS-LST. We also find that three-dimensional urban design is a better predictor of MRT than two-dimensional land cover and albedo – a known determinant of RS-LST. Shade is a better predictor of both simulated LST and MRT than RS-LST. We conclude that RS-LST is not adequate for guiding heat mitigation at hyper-local scales in cities.

Published in Journal of Land Use Science

ISSN: 1747-423X (Print); 1747-4248 (Online)
Publisher: Taylor & Francis Group
Country of publisher: United Kingdom
LCC subjects: Social Sciences: Industries. Land use. Labor: Land use
Website: https://www.tandfonline.com/journals/tlus20

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