Passive scalar transport in a cross-ventilating flow with upstream source: wind and water tunnel measurements
Passive scalar transport in a cross-ventilating flow with upstream source: wind and water tunnel measurements
In urban environments, pollutant ingress from outdoor sources poses a significant challenge to indoor air quality. Cross-ventilation, while essential for passive cooling and natural airflow, can also facilitate the entry of outdoor contaminants into indoor spaces. To investigate the dynamics of outdoor-to-indoor pollutant transport, the present study employs an idealized configuration, namely, a hollow cube representing a scaled-down model building with window openings in the upstream and downstream faces, subjected to an upstream passive scalar source within an atmospheric boundary layer. The experiments are conducted in two distinct facilities: a water tunnel using Rhodamine dye as the scalar, and a wind tunnel using propane gas, all performed at a specified flow Reynolds number of Re=URefH/v ≈ 50,000 for a fixed boundary layer-to-cube height ratio of about 3; here, is the streamwise velocity at cube’s height (H) measured without the cube. The scalar, released from a ground-level upstream source, is predominantly transported by a streamwise advective flux, while relatively weaker wall-normal advective and turbulent fluxes contribute to vertical dispersion and local mixing. A fraction of the oncoming scalar enters the cube intermittently, through the upstream window. Inside, a central jet-like flow carries the scalar parcels primarily by streamwise advective flux, while also interacting with the upper and lower recirculation regions, enabling scalar exchange across these zones through wall-normal advective and turbulent fluxes. While the time-averaged concentration field inside the cube is nearly uniform, suggesting effective mixing, instantaneous concentration traces exhibit strong intermittency, with sporadic peak events, highlighting the risk of transient peak exposures. The indoor concentration exponentially decays over time once the source is turned off, with a slower decay in the upper recirculation region, implying relatively prolonged exposure near the ceiling region. Both experimental setups produce closely matching values and consistent trends in the spatio-temporal dynamics of scalar concentration, and also highlight their complementary nature, with each offering distinct advantages. The present findings will deepen our understanding of pollutant ingress and mixing in buildings in cross-ventilated flows and also offer valuable insights to future modeling of pollutant exposure in urban indoor spaces.
Biswas, Subhajit
66f05b88-e89e-45e0-a29e-f5fb7839527f
Hayden, Paul
b5662acc-6375-4f86-afee-04c779155d5f
Carpentieri, Matteo
07cb3abe-34e2-422d-8728-23734c3ec17e
Vanderwel, Christina
fbc030f0-1822-4c3f-8e90-87f3cd8372bb
14 November 2025
Biswas, Subhajit
66f05b88-e89e-45e0-a29e-f5fb7839527f
Hayden, Paul
b5662acc-6375-4f86-afee-04c779155d5f
Carpentieri, Matteo
07cb3abe-34e2-422d-8728-23734c3ec17e
Vanderwel, Christina
fbc030f0-1822-4c3f-8e90-87f3cd8372bb
Biswas, Subhajit, Hayden, Paul, Carpentieri, Matteo and Vanderwel, Christina
(2025)
Passive scalar transport in a cross-ventilating flow with upstream source: wind and water tunnel measurements.
Experiments in Fluids, 66 (12), [220].
(doi:10.1007/s00348-025-04118-6).
Abstract
In urban environments, pollutant ingress from outdoor sources poses a significant challenge to indoor air quality. Cross-ventilation, while essential for passive cooling and natural airflow, can also facilitate the entry of outdoor contaminants into indoor spaces. To investigate the dynamics of outdoor-to-indoor pollutant transport, the present study employs an idealized configuration, namely, a hollow cube representing a scaled-down model building with window openings in the upstream and downstream faces, subjected to an upstream passive scalar source within an atmospheric boundary layer. The experiments are conducted in two distinct facilities: a water tunnel using Rhodamine dye as the scalar, and a wind tunnel using propane gas, all performed at a specified flow Reynolds number of Re=URefH/v ≈ 50,000 for a fixed boundary layer-to-cube height ratio of about 3; here, is the streamwise velocity at cube’s height (H) measured without the cube. The scalar, released from a ground-level upstream source, is predominantly transported by a streamwise advective flux, while relatively weaker wall-normal advective and turbulent fluxes contribute to vertical dispersion and local mixing. A fraction of the oncoming scalar enters the cube intermittently, through the upstream window. Inside, a central jet-like flow carries the scalar parcels primarily by streamwise advective flux, while also interacting with the upper and lower recirculation regions, enabling scalar exchange across these zones through wall-normal advective and turbulent fluxes. While the time-averaged concentration field inside the cube is nearly uniform, suggesting effective mixing, instantaneous concentration traces exhibit strong intermittency, with sporadic peak events, highlighting the risk of transient peak exposures. The indoor concentration exponentially decays over time once the source is turned off, with a slower decay in the upper recirculation region, implying relatively prolonged exposure near the ceiling region. Both experimental setups produce closely matching values and consistent trends in the spatio-temporal dynamics of scalar concentration, and also highlight their complementary nature, with each offering distinct advantages. The present findings will deepen our understanding of pollutant ingress and mixing in buildings in cross-ventilated flows and also offer valuable insights to future modeling of pollutant exposure in urban indoor spaces.
Text
Biswas_Vanderwel_EXIF2025
- Accepted Manuscript
Text
s00348-025-04118-6
- Version of Record
More information
Accepted/In Press date: 27 October 2025
e-pub ahead of print date: 14 November 2025
Published date: 14 November 2025
Identifiers
Local EPrints ID: 507083
URI: http://eprints.soton.ac.uk/id/eprint/507083
ISSN: 0723-4864
PURE UUID: f294908c-b398-4ff7-9474-c546d2a32747
Catalogue record
Date deposited: 26 Nov 2025 17:47
Last modified: 29 Nov 2025 03:04
Export record
Altmetrics
Contributors
Author:
Subhajit Biswas
Author:
Paul Hayden
Author:
Matteo Carpentieri
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics