Toward Cleaner Transport Alternatives: Reduction in Exposure to Air Pollutants in a Mass Public Transport

Ricardo Morales Betancourt; Boris Galvis; Daniela Mendez-Molano; Juan Manuel Rincón-Riveros; Yadert Contreras; Thalia Alejandra Montejo; Diego Roberto Rojas-Neisa; Oscar Casas

doi:10.1021/acs.est.1c07004

Toward Cleaner Transport Alternatives: Reduction in Exposure to Air Pollutants in a Mass Public Transport

Environ Sci Technol. 2022 Jun 7;56(11):7096-7106. doi: 10.1021/acs.est.1c07004. Epub 2022 Mar 25.

Authors

Ricardo Morales Betancourt¹, Boris Galvis², Daniela Mendez-Molano^{1

3}, Juan Manuel Rincón-Riveros¹, Yadert Contreras¹, Thalia Alejandra Montejo¹, Diego Roberto Rojas-Neisa¹, Oscar Casas⁴

Affiliations

¹ Department of Civil and Environmental Engineering, Universidad de Los Andes, Cra. 1E No. 19A - 40, Bogotá, Colombia 111711.
² Chemical Engineering Program, Universidad de la Salle Cra. 2 No. 10-70, Bogotá, Colombia 111711.
³ Universidad Manuela Beltrán, Bogotá, Colombia 110231.
⁴ Center of Innovation and Technology ICP, Ecopetrol, Piedecuesta, Colombia 110231.

PMID: 35333524
DOI: 10.1021/acs.est.1c07004

Abstract

Commuters are often exposed to higher concentrations of air pollutants due to its proximity to mobile sources. Despite recent trends in urban transport toward zero- and low-tailpipe emission alternatives, the assessments of the impact of these transformations on commuter exposure are limited by the low frequency of such studies. In this work, we use a unique data set of personal exposure concentration measurements collected over the span of 5 years to analyze changes due to the introduction of a new fleet for Bogotá's Bus Rapid Transit System. In that system, over a thousand Euro-II and -III diesel-powered buses were replaced with Euro-VI compressed natural gas and filter-equipped Euro-V diesel buses. We measured personal exposure concentrations of equivalent black carbon (eBC), fine particulate (PM_2.5), and ultra fine particles (UFP) during and after the retirement of old buses and the introduction of new ones. Observations collected prior to the fleet renewal were used as baseline and later compared to data collected over two follow-up campaigns in 2019 and 2020. Significant reductions in the concentration of PM_2.5 and eBC were observed during the 2019 campaign, with a 48% decrease for mean in-bus eBC (89.9 to 46.4 μg m^-3) and PM_2.5 (180.7 to 95.4 μg m^-3) concentrations. Further reductions were observed during the 2020 follow-up, when the fleet renovation was completed, with mean in-bus eBC decreasing to 17.7 μg m^-3 and PM_2.5 to 42.3 μg m^-3. These observations imply nearly a 5-fold reduction in eBC exposure and a 4-fold decrease in PM_2.5. There was a much smaller reduction of in-bus UFP concentration between 2019 and 2020, indicating a persistent presence of high particle number concentrations in the near-road environment despite the fleet renovation process. In-bus UFP concentrations ranged between 65 000 and 104 500 cm^-3 during the follow-up campaigns. The results in this work illustrate the immediate benefits of reducing personal exposure through the adoption of vehicles with more stringent emission standards.

Keywords: PM2.5 exposure; UFP; air pollution reduction; black carbon; commuter exposure; traffic-related air pollutants; ultrafine particles.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Air Pollutants* / analysis
Air Pollution* / analysis
Environmental Monitoring / methods
Particulate Matter / analysis
Soot
Vehicle Emissions / analysis

Substances

Air Pollutants
Particulate Matter
Soot
Vehicle Emissions