Numerical simulation of the effect of solar chimneys on NOx-O3 photochemical reaction and ventilation in urban street canyon

Hanbin Xiong; Tianhao Shi; Yongjia  Wu; Ruiyue Xia; Xitong  Yuan; Renaud Richter; Wei li; Yueping Fang; Nan Zhou; Wenyu Li; Chong Peng; Tingzhen Ming

doi:10.1016/j.uclim.2025.102491

Numerical simulation of the effect of solar chimneys on NOx-O3 photochemical reaction and ventilation in urban street canyon

Hanbin Xiong
, Tianhao Shi
, Yongjia Wu
, Ruiyue Xia
, Xitong Yuan
, Renaud Richter
, Wei li
, Yueping Fang
, Nan Zhou
, Wenyu Li
, Chong Peng
, Tingzhen Ming

CEES School of The Environment

Wuhan University of Technology
Tour-Solaire.Fr, 8 Impasse des Papillons
University of Edinburgh
Lawrence Berkeley National Laboratory
Nanjing University of Science and Technology
Huazhong University of Science and Technology

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

3 Citations (Scopus)

Abstract

The complex interaction between pollutants and insufficient ventilation in urban street canyon presents significant challenges to the creation of a healthy urban environment. This study proposed the innovative application of solar chimneys (SCs) to improve airflow structure and air quality in the confined space considering NOx-O3 photochemical reaction mechanism. The influences of ambient wind, solar radiation at three local solar times (LSTs), and the SCs on NOx diffusion and ventilation performance in street canyon were revealed by developing a mathematical model. The results demonstrated that the uneven temperature distribution induced by solar radiation at the LSTs significantly influences both the NOx-O3 photochemical reaction and the airflow structure within the street canyon. The deleterious effects of thermal buoyancy on the
airflow structure were mitigated by the integration of the SCs. The reaction shifted toward the conversion of NO2 to NO as the temperature decreased. The integration of SCs resulted in a maximum temperature reduction of 6.01 K in the pedestrian respiratory zone and demonstrated maximum removal efficiencies of 66.12 % for NO and 70.65 % for NO2. The NOx levels on the leeward side initially increased and then decreased as the ambient wind strengthened, whereas
the NOx levels on the windward side consistently decreased. This research verifies the feasibility of utilizing the SCs to enhance the street canyon environments and offers a viable strategy for promoting healthy and sustainable urban.

Original language	English
Article number	102491
Number of pages	22
Journal	Urban Climate
Volume	61
Issue number	1
Early online date	6 Jun 2025
DOIs	https://doi.org/10.1016/j.uclim.2025.102491
Publication status	E-pub ahead of print - 6 Jun 2025

Bibliographical note

Publisher Copyright:
© 2024

Funding

This research was supported by the National Natural Science Foundation of China (Grant No. 52278123), the National Key R&D Program (Grant No. 2019YFE0197500), the European Commission H2020 Marie Curie Research and Innovation Staff Exchange (RISE) award (Grant No. 871998).

Funders	Funder number
European Commission
National Natural Science Foundation of China	52278123
National Key Research and Development Program of China	2019YFE0197500

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 11 Sustainable Cities and Communities
SDG 13 Climate Action

Keywords

Solar chimneys Street
canyon ventilation
NOx-O3 photoreaction
Numerical simulation
Pollutant diffusion

ASJC Scopus subject areas

Environmental Science(all)

Themes

Sustainability and Clean Growth

Access to Document

10.1016/j.uclim.2025.102491

Cite this

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title = "Numerical simulation of the effect of solar chimneys on NOx-O3 photochemical reaction and ventilation in urban street canyon",

abstract = "The complex interaction between pollutants and insufficient ventilation in urban street canyon presents significant challenges to the creation of a healthy urban environment. This study proposed the innovative application of solar chimneys (SCs) to improve airflow structure and air quality in the confined space considering NOx-O3 photochemical reaction mechanism. The influences of ambient wind, solar radiation at three local solar times (LSTs), and the SCs on NOx diffusion and ventilation performance in street canyon were revealed by developing a mathematical model. The results demonstrated that the uneven temperature distribution induced by solar radiation at the LSTs significantly influences both the NOx-O3 photochemical reaction and the airflow structure within the street canyon. The deleterious effects of thermal buoyancy on the airflow structure were mitigated by the integration of the SCs. The reaction shifted toward the conversion of NO2 to NO as the temperature decreased. The integration of SCs resulted in a maximum temperature reduction of 6.01 K in the pedestrian respiratory zone and demonstrated maximum removal efficiencies of 66.12 \% for NO and 70.65 \% for NO2. The NOx levels on the leeward side initially increased and then decreased as the ambient wind strengthened, whereas the NOx levels on the windward side consistently decreased. This research verifies the feasibility of utilizing the SCs to enhance the street canyon environments and offers a viable strategy for promoting healthy and sustainable urban.",

keywords = "Solar chimneys Street, canyon ventilation, NOx-O3 photoreaction, Numerical simulation, Pollutant diffusion",

author = "Hanbin Xiong and Tianhao Shi and Yongjia Wu and Ruiyue Xia and Xitong Yuan and Renaud Richter and Wei li and Yueping Fang and Nan Zhou and Wenyu Li and Chong Peng and Tingzhen Ming",

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doi = "10.1016/j.uclim.2025.102491",

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AU - Xiong, Hanbin

AU - Shi, Tianhao

AU - Wu, Yongjia

AU - Xia, Ruiyue

AU - Yuan, Xitong

AU - Richter, Renaud

AU - li, Wei

AU - Fang, Yueping

AU - Zhou, Nan

AU - Li, Wenyu

AU - Peng, Chong

AU - Ming, Tingzhen

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N2 - The complex interaction between pollutants and insufficient ventilation in urban street canyon presents significant challenges to the creation of a healthy urban environment. This study proposed the innovative application of solar chimneys (SCs) to improve airflow structure and air quality in the confined space considering NOx-O3 photochemical reaction mechanism. The influences of ambient wind, solar radiation at three local solar times (LSTs), and the SCs on NOx diffusion and ventilation performance in street canyon were revealed by developing a mathematical model. The results demonstrated that the uneven temperature distribution induced by solar radiation at the LSTs significantly influences both the NOx-O3 photochemical reaction and the airflow structure within the street canyon. The deleterious effects of thermal buoyancy on the airflow structure were mitigated by the integration of the SCs. The reaction shifted toward the conversion of NO2 to NO as the temperature decreased. The integration of SCs resulted in a maximum temperature reduction of 6.01 K in the pedestrian respiratory zone and demonstrated maximum removal efficiencies of 66.12 % for NO and 70.65 % for NO2. The NOx levels on the leeward side initially increased and then decreased as the ambient wind strengthened, whereas the NOx levels on the windward side consistently decreased. This research verifies the feasibility of utilizing the SCs to enhance the street canyon environments and offers a viable strategy for promoting healthy and sustainable urban.

AB - The complex interaction between pollutants and insufficient ventilation in urban street canyon presents significant challenges to the creation of a healthy urban environment. This study proposed the innovative application of solar chimneys (SCs) to improve airflow structure and air quality in the confined space considering NOx-O3 photochemical reaction mechanism. The influences of ambient wind, solar radiation at three local solar times (LSTs), and the SCs on NOx diffusion and ventilation performance in street canyon were revealed by developing a mathematical model. The results demonstrated that the uneven temperature distribution induced by solar radiation at the LSTs significantly influences both the NOx-O3 photochemical reaction and the airflow structure within the street canyon. The deleterious effects of thermal buoyancy on the airflow structure were mitigated by the integration of the SCs. The reaction shifted toward the conversion of NO2 to NO as the temperature decreased. The integration of SCs resulted in a maximum temperature reduction of 6.01 K in the pedestrian respiratory zone and demonstrated maximum removal efficiencies of 66.12 % for NO and 70.65 % for NO2. The NOx levels on the leeward side initially increased and then decreased as the ambient wind strengthened, whereas the NOx levels on the windward side consistently decreased. This research verifies the feasibility of utilizing the SCs to enhance the street canyon environments and offers a viable strategy for promoting healthy and sustainable urban.

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KW - canyon ventilation

KW - NOx-O3 photoreaction

KW - Numerical simulation

KW - Pollutant diffusion

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Numerical simulation of the effect of solar chimneys on NOx-O3 photochemical reaction and ventilation in urban street canyon

Abstract

Bibliographical note

Funding

UN SDGs

Keywords

ASJC Scopus subject areas

Themes

Access to Document

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