Street-level heat and air pollution exposure informed by mobile sensing

Irfan Batur; Samuel Markolf; Mikhail V. Chester; Ariane Middel; David Hondula; Jennifer Vanos

doi:10.1016/j.trd.2022.103535

Street-level heat and air pollution exposure informed by mobile sensing

Irfan Batur, Samuel Markolf, Mikhail V. Chester, Ariane Middel, David Hondula, Jennifer Vanos

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Heat and air pollution persist as major public health hazards in urban environments. Yet there are gaps in the quality of information about the hazards as conditions tend to be informed by limited stationary sensors providing information at large geographic scales. Here we present the results of a study that took place in Phoenix, Arizona, to assess the efficacy of low-cost mobile sensors on public transportation vehicles to monitor fine-scale on-road heat and PM₁₀ concentrations. The goal of the study is to uncover the spatial and temporal variations of excessive heat and air pollution experienced by transit commuters, bicyclists, and pedestrians. The results show that the sensors on the buses complement the readings from stationary sensors and low-cost mobile sensors are effective for gaining fine-grained heat and air quality readings at different locations, thereby creating new insights into pockets of heat and air pollution that should be targeted for intervention.

Original language	English (US)
Article number	103535
Journal	Transportation Research Part D: Transport and Environment
Volume	113
DOIs	https://doi.org/10.1016/j.trd.2022.103535
State	Published - Dec 2022

Keywords

Active transportation
Air pollution
Emerging technologies
Equity
Extreme heat

ASJC Scopus subject areas

Civil and Structural Engineering
Transportation
General Environmental Science

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10.1016/j.trd.2022.103535

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title = "Street-level heat and air pollution exposure informed by mobile sensing",

abstract = "Heat and air pollution persist as major public health hazards in urban environments. Yet there are gaps in the quality of information about the hazards as conditions tend to be informed by limited stationary sensors providing information at large geographic scales. Here we present the results of a study that took place in Phoenix, Arizona, to assess the efficacy of low-cost mobile sensors on public transportation vehicles to monitor fine-scale on-road heat and PM10 concentrations. The goal of the study is to uncover the spatial and temporal variations of excessive heat and air pollution experienced by transit commuters, bicyclists, and pedestrians. The results show that the sensors on the buses complement the readings from stationary sensors and low-cost mobile sensors are effective for gaining fine-grained heat and air quality readings at different locations, thereby creating new insights into pockets of heat and air pollution that should be targeted for intervention.",

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author = "Irfan Batur and Samuel Markolf and Chester, {Mikhail V.} and Ariane Middel and David Hondula and Jennifer Vanos",

note = "Funding Information: This research was sponsored by the Zimin Institute for Smart and Sustainable Cities at Arizona State University. The authors are thankful to Miguel A. Garcia from the City of Phoenix for assisting with vehicle setup and Rui Li from Arizona State University for helping with the data acquisition of land-form characteristics as well as Joshua Uebelherr, Ronald Pope, and Ben Davis from the Maricopa County Air Quality Department and Megan Gaitan and Quincy Stewart from the CAP LTER at Arizona State University for assisting with data collection/acquisition at air monitoring and weather stations. Publisher Copyright: {\textcopyright} 2022 Elsevier Ltd",

year = "2022",

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doi = "10.1016/j.trd.2022.103535",

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AU - Batur, Irfan

AU - Markolf, Samuel

AU - Chester, Mikhail V.

AU - Middel, Ariane

AU - Hondula, David

AU - Vanos, Jennifer

N1 - Funding Information: This research was sponsored by the Zimin Institute for Smart and Sustainable Cities at Arizona State University. The authors are thankful to Miguel A. Garcia from the City of Phoenix for assisting with vehicle setup and Rui Li from Arizona State University for helping with the data acquisition of land-form characteristics as well as Joshua Uebelherr, Ronald Pope, and Ben Davis from the Maricopa County Air Quality Department and Megan Gaitan and Quincy Stewart from the CAP LTER at Arizona State University for assisting with data collection/acquisition at air monitoring and weather stations. Publisher Copyright: © 2022 Elsevier Ltd

PY - 2022/12

Y1 - 2022/12

N2 - Heat and air pollution persist as major public health hazards in urban environments. Yet there are gaps in the quality of information about the hazards as conditions tend to be informed by limited stationary sensors providing information at large geographic scales. Here we present the results of a study that took place in Phoenix, Arizona, to assess the efficacy of low-cost mobile sensors on public transportation vehicles to monitor fine-scale on-road heat and PM10 concentrations. The goal of the study is to uncover the spatial and temporal variations of excessive heat and air pollution experienced by transit commuters, bicyclists, and pedestrians. The results show that the sensors on the buses complement the readings from stationary sensors and low-cost mobile sensors are effective for gaining fine-grained heat and air quality readings at different locations, thereby creating new insights into pockets of heat and air pollution that should be targeted for intervention.

AB - Heat and air pollution persist as major public health hazards in urban environments. Yet there are gaps in the quality of information about the hazards as conditions tend to be informed by limited stationary sensors providing information at large geographic scales. Here we present the results of a study that took place in Phoenix, Arizona, to assess the efficacy of low-cost mobile sensors on public transportation vehicles to monitor fine-scale on-road heat and PM10 concentrations. The goal of the study is to uncover the spatial and temporal variations of excessive heat and air pollution experienced by transit commuters, bicyclists, and pedestrians. The results show that the sensors on the buses complement the readings from stationary sensors and low-cost mobile sensors are effective for gaining fine-grained heat and air quality readings at different locations, thereby creating new insights into pockets of heat and air pollution that should be targeted for intervention.

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KW - Air pollution

KW - Emerging technologies

KW - Equity

KW - Extreme heat

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Street-level heat and air pollution exposure informed by mobile sensing

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Keywords

ASJC Scopus subject areas

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