Propagation of toxic substances in the urban atmosphere: A complex network perspective

The accidental or malicious release of toxic substances in the urban atmosphere is a major environmental and safety problem, especially in large cities. Computational fluid dynamics codes and simplified modelling tools have been used in the last decades to model pollutant dispersion in urban areas....

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Bibliographic Details
Published in:Atmospheric environment (1994) Vol. 198; pp. 291 - 301
Main Authors: Fellini, Sofia, Salizzoni, Pietro, Soulhac, Lionel, Ridolfi, Luca
Format: Journal Article
Language:English
Published: Elsevier Ltd 01.02.2019
Elsevier
Subjects:
Accidental releases
algorithms
atmospheric chemistry
buildings
canopy
case studies
cities
Complex networks
Environmental Engineering
Environmental Sciences
fluid mechanics
Global Changes
network theory
people
pollutants
Spreading on networks
Street network
topology
toxic substances
toxicity
Urban air pollution
urban areas
Vulnerability
wind
Street network
Urban air pollution
Vulnerability
Accidental releases
Complex networks
Spreading on networks
ISSN:1352-2310, 1873-2844
Online Access:Get full text
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Summary:The accidental or malicious release of toxic substances in the urban atmosphere is a major environmental and safety problem, especially in large cities. Computational fluid dynamics codes and simplified modelling tools have been used in the last decades to model pollutant dispersion in urban areas. These studies have shown that propagation is strongly influenced by the layout of buildings and, therefore, by the street topology of the city. This work presents a novel approach to the study of toxic propagation within the urban canopy based on the theory of complex networks. The urban canopy is modelled as a network, where the streets and the street intersections represent respectively the links and the nodes of the network. The direction and the weights of the links contain the geometrical characteristics of the street canyons and their wind conditions, so that all the key variables involved in pollutant dispersion are represented in a single mathematical structure that is a weighted and directed complex network. Thanks to this mathematical interpretation, propagation is modelled as a spreading process on a network and a depth-first search algorithm is used to rapidly delimit the zone of influence of a source node. This zone is the set of streets that are contaminated from the source. As a case study, the proposed model is applied to the urban tissue of the city of Lyon. The algorithm simulates a toxic release in all the nodes of the network and computes the number of people affected by each propagation process. In this way, the nodes with the most dangerous spreading potential are identified and vulnerability maps of the city are constructed. Moreover, various wind and concentration scenarios are easily implemented. The results highlight how the proposed method is effective in assessing the most vulnerable points in a city with a computational time that is up to three orders of magnitude lower than that of existing models. Moreover, the proposed approach paves the way to future applications of tools and metrics from the complex network theory for a deeper comprehension of the mechanisms that drive pollutant dispersion in urban areas. [Display omitted] •A complex network approach to model dispersion in the urban atmosphere is presented.•Dispersion from a source is modelled as a spreading process on a complex network.•The polluted area and the number of people affected by the release are assessed.•Maps of urban vulnerability to the release of toxic gases are rapidly constructed.•The street topology of the city is a key driver in the dispersion process.
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ISSN:1352-2310
1873-2844
DOI:10.1016/j.atmosenv.2018.10.062