Zhengzhou Living City Lab
Impact the city’s future sustainable development
Projects
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Health perception and commuting choice
A survey experiment measuring behavioral trade-offs between physical activity benefits and pollution exposure risks
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Air quality in different transport modes in Zhengzhou
Reporting the levels of multiple traffic-related pollutants: PM, SO2, CO, NO2 in different transport microenvironments in downtown Zhengzhou.
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Green travel and clean air in Zhengzhou
MIT Sustainable Urbanization Practicum
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Publications
Our publications related to these projects
Health Perception and Commuting Choice
A survey experiment measuring behavioral trade-offs between physical activity benefits and pollution exposure risks
Research Questions
Whether people choose to switch commuting modes to protect themselves under air pollution scenario?
Whether people are rational in making trade-offs between the health benefit and cost?
What are the determinants of the choices?
(a) Job locations of survey participants; (b) 2019 daily average PM2.5 pollution (micrograms/m3) in Zhengzhou
(a) Commuting modes composition; (b) Home-job walking distance
Survey designs
The survey was conducted in July, 2019. Our major target group is non-vehicle commuters whose job location is around Zhengzhou CBD area, with a total 2285 valid participants.
Questionnaires are designed and collected through Qualtrics. Survey takes 15-20 minutes, including an opening video introducing the iPad interface of electronic questionnaire, informed consent, four rounds of commuting choices questions, two information intervention, and some socio-demographics habits and preferences characterization questions. All respondents are asked to make four rounds of commuting choices. Each round of choices is bundled with three questions: their primary mode of commuting, whether they are willing to switch to active commuting (i.e., biking or walking) given a reasonable amount of subsidy, and what is the minimum amount of subsidy they are willing to accept for the switch.
Survey structure and group decompositions
Results
Descriptive analysis of commuting choice for Treatment Group 1 under different pollution scenarios
1. Air pollution and commuting choice
After we present with people their personal pollution exposure information, we see a large reduction in respondents choosing public transit and a large increase in motor vehicle (i.e., car/ taxi). Assuming information is the only thing updated their believes, the result indicates a knowledge gap between people’s perceived pollution exposure and the reality, specifically, people seem to underestimate the exposure in public transit.
Active commuting reduction after informed pollution exposure by counterfactual biking time.
2. Health trade-offs in active commuting
Though biking within 30 minutes has exercise benefit outweighs pollution cost, people who live close to the job location also intentionally switch from active commuting to other transportation modes to hedge against their subjective perception of exposure risk.
3. Implications for active commuting policies
People with counterfactual biking time 28-60 minutes value the health cost of pollution exposure the most. The differences for extensive and intensive margin can be partially explained by the selection bias, since people who adopts active commuting for biking time longer than 30 minutes usually have greater preferences for physical activities or having limited alternative transportation choice.
(a) Changes in willingness to go active given subsidy; (b) Changes in minimum acceptable subsidy
Conclusion
People have the intention of switching commuting modes as a channel of air pollution adaptation.
People seem to overreact to air pollution.
Both financial subsidy and green nudge policies to encourage active commuting are likely to be in vein under air pollution.
Team
Yichun Fan
MIT Sustainable Urbanization Lab
Juan Palacios
MIT Sustainable Urbanization Lab
Siqi Zheng
MIT Sustainable Urbanization Lab
Air Quality in different transport modes in Zhengzhou
Reporting the levels of multiple traffic related pollutants: PM, SO2, CO, NO2 in different transport microenvironments in downtown Zhengzhou.
Research Design
Route selection (see image on the left)
Time of Day:
Rush hours: 7am-9am, 5pm-7pm, all days of week.
From Sunday July 5th to July 26th:
Results overview
NO2 , CO and SO2 are primary pollutants and are highest in the bus and taxi, reflecting the closest proximity to the exhaust of other vehicles. PM and O3 are secondary pollutants.
The highest correlations between pollutants on different transport modes were found between PM2.5 and PM10. The bus and bike PM were more highly correlated than that of taxi and bus, or taxi and bike.
O3 and NO2 were inversely correlated, especially for bike drivers.
SO2 on taxi is strongly inversely correlated with CO measured on bikes, while it is weakly correlated with the CO measured in the bus. The bike and bus CO are weakly inversely related.
The most direct comparisons between travel mode were made by taking the average of individual (pairwise) run ratios between modes, because this limited the effect of temporal variations in meteorology
When comparing the average of ratios from the pairwise analysis to the ratio of the overall mode averages, we found that the rank ordering obtained is the same.
In general the pairwise analysis provided greater contrasts, with an extreme increase in the bus/bike NO2 ratio, the SO2 ratios of all three: taxi/bike, bus/bike and taxi/bus
Pros and Cons:
Pros:
We measured a range of pollutants.
We attempted to do a pair-wise analysis.
Cons:
Our study was only conducted in one season: summer, and therefore the results cannot be generalized to other seasons.
We used low-cost sensors, and there could be issues with calibration
Future steps:
Calibrate Purple Air data + integrate subway analysis
Team
Priyanka deSouza
Department of Urban Studies and Planning, MIT
Ruining Lu
Fairsense (Beijing) Environment Technology Co., Ltd
Pat Kinney
Boston University School of Public Health
Siqi Zheng
MIT Sustainable Urbanization Lab & MIT Center for Real Estate
Green Travel and Clean Air in Zhengzhou
MIT Sustainable Urbanization Practicum
Air pollution and traffic congestion have become major threats to the quality of life in many cities in the developing world. In recent years, Chinese central and city governments have been taking actions on various green transportation initiatives. Public and private companies as well as academia are also engaged in this endeavor. All are involved in devising technologies, economic and policy frameworks to support inclusive, and innovative and sustainable transportation projects. However, often the interests, goals, and timeframes of these stakeholders are not aligned.
In the practicum of “Sustainable Urbanization Pilot 2020: Green Travel and Clean Air in Zhengzhou” , the MIT Sustainable Urbanization Laboratory (MIT-SUL) partnered with governmental agencies and companies in Zhengzhou (Henan Province, China) to conduct a semester-long course that combined fieldwork, active participation of multiple stakeholders, and research. This Policy Guideline presents the results of this practicum. By bridging the gap between the academic and the professional worlds, we offer a combination of academic research grounded on real-world issues, with the common goal of achieving sustainable urbanization.
The combination of a critical issue in urban environments (air quality), with a government committed to find solutions towards green transportation, and companies innovating at the global scale, brings an exciting challenge to MIT students: how to advance knowledge and, at the same time, turn gathered and synthesized data into guidelines and recommendations that can be used to guide public and private processes dealing with green transportation and sustainable urban development goals in Zhengzhou.
This report provides a practical and evidence-based strategy for Zhengzhou’s sustainable urbanization in three key areas: Autonomous Buses (AV Bus), Sensing, and Transit-Oriented Development (TOD), with the objective of informing their policy designs of green transportation development in the next decade. Underlying the three sections, there is a long term integral vision of how technology and behavioral science could be integrated into urban transportation planning. The report has an ambitious goal to make real-world differences in improving the environmental quality and overall well-being of Zhengzhou.
We are grateful to the support of Zhengzhou Zhengdong New District Administrative Committee, Zhengzhou Yutong Bus Co., Ltd., Yasin Holdings, Operations Office of Zhengzhou Bus Communication Corporation (ZZB), the Public-Private Partnership Research Center (in School of Naval Architecture, Civil and Ocean Engineering) at Shanghai Jiao Tong University (SJTU), and the Department of Urban Studies and Planning (MIT) in our research and teaching. We also thank Wei Ningdi (Zhengdong New District Administrative Committee); Ren Yongli (Yutong), Xu Ti (Yutong), Gu Chaoran (Yutong); Zhang Yongliang (Yasin), Zhang Chuanye (Yasin), Wang Chen (Yasin); Dai Lei (SJTU), Huang Yujie (SJTU), Qi Changlu (SJTU), Guo Yuanyuan (ZZB), Niu Dongxiao (Tsinghua and MIT), and Zhai Guochen (MIT), for their helpful comments and suggestions.
Publications
Fan, Y., Palacios, J., Arcaya, M., Luo, R., & Zheng, S. (2021). Health perception and commuting choice: a survey experiment measuring behavioral trade-offs between physical activity benefits and pollution exposure risks. Environmental Research Letters.
DeSouza, P., Lu, R., Kinney, P., & Zheng, S. (2021). Exposures to multiple air pollutants while commuting: Evidence from Zhengzhou, China. Atmospheric Environment, 247, 118168.
Wang, B., & Zheng, S. (2020). Air pollution lowers travel demand in a consumer city. Transportation Research Part D: Transport and Environment, 89, 102616.