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Acadlore takes over the publication of IJTDI from 2025 Vol. 9, No. 4. The preceding volumes were published under a CC BY 4.0 license by the previous owner, and displayed here as agreed between Acadlore and the previous owner. ✯ : This issue/volume is not published by Acadlore.

Open Access
Research article

Empirical Modelling of A Near-Traffic Emission Hotspot – Analysis of Immission Reduction Potentials

Tim Steinhaus,
Moritz Hartwig,
Christian Beidl
Institute for Internal Combustion Engines and Powertrain Systems, Technical University of Darmstadt, Germany
International Journal of Transport Development and Integration
|
Volume 5, Issue 4, 2021
|
Pages 353-366
Received: N/A,
Revised: N/A,
Accepted: N/A,
Available online: N/A
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Abstract:

Two of the greatest challenges for future individual mobility are urban air quality and climate protection. Although a steady reduction of pollutant emissions from motor vehicles has been achieved in the past, local pollution levels within cities still reach levels that are considered hazardous to health. Although the significant contribution of road traffic to total pollution is known, especially at traffic hotspots, modelling the exact interactions remains a challenge. In this paper, a novel approach for the determination of the emission–immission interaction on the basis of a neural network model for the NO2 immission at a near-traffic hotspot scenario is presented. In addition to a detailed description of the modelling procedure, significance analysis of the influencing variables and the interactions considered, it is also described how the specific emissions for the entire vehicle fleet are implemented in accordance with different emission standards under real driving conditions. On the basis of the model presented, achievable immission levels for currently available and future technology are investigated within scenario analysis. results show that concentrations of less than half of today’s yearly average limit values are technically feasible in hotspot situations.

Keywords: Air pollution, Emission-immission-interaction, Recurrent neural networks, $\mathrm{NO}_2$, NOx
References
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World Health Organization. Health Risks of Air Pollution in Europe – HRAPIE project. Recommendations for Concentration–Response Functions for Cost–Benefit Analysis of Particulate Matter, Ozone and Nitrogen Dioxide. WHO Regional Office for Europe, Kopenhagen, 2013.
2.
Ritz, B., B. Hoffmann und A. Peters. The effects of fine dust, ozone, and nitrogen dioxide on health. Deutsches Arzteblatt International, 116(51–52), 881–886, 2019. [Crossref]
3.
Héroux, M.-E., et al. Quantifying the health impacts of ambient air pollutants: recommendations of a WHO/Europe project. International Journal of Public Health, 60(5), 619–627, 2015. [Crossref]
4.
Brunekreef, B. Health effects of air pollution observed in cohort studies in Europe. Journal of Exposure Science & Environmental Epidemiology, 17(Suppl 2), S61–5, 2007. [Crossref]
5.
Cyrys, J., et al. Variation of NO2 and NOx concentrations between and within 36 European study areas: results from the ESCAPE study. Atmospheric Environment, 62, 374–390, 2012. [Crossref]
6.
Nagl, C., W. Spangl und I. Buxbaum. Sampling Points for Air Quality. Policy Department for Economic, Scientific and Quality of Life Policies, Luxembourg, 2019.
7.
European Environment Agency. Air Quality in Europe. 2019 Report. Luxembourg: Publications Office of the European Union, 2019. EEA report. No 10/2019. ISBN 9789294800886.
8.
World Health Organization. WHO Air Quality Guidelines for Particulate Matter, Ozone, Nitrogen Dioxide and Sulfur Dioxide. Global update 2005. Summary of Risk Assessment. World Health Organization, Genf, 2005.
9.
Raaschou-Nielsen, O., et al. Traffic air pollution and mortality from cardiovascular disease and all causes: a Danish cohort study. Environmental Health, 11, 60, 2012. [Crossref]
10.
Nagl, C., et al. Air Quality and Urban Traffic in the EU: Best Practises and Possible Solutions. Policy Department for Citizens’ Rights and Constitutional Affairs, Brussels, 2018.
11.
Verwaltungsgericht Wiesbaden. Vergleichsvereinbarung im Verwaltungsstreitverfahren Verkehrsclub Deutschland e.V. und Deutsche Umwelthilfe e.V. ./. Land Hessen, 12 December 2018 [Press release]. Available at: https://www.duh.de/fileadmin/user_upload/download/Projektinformation/Verkehr/Luftreinhaltung/Vergleich_VCDDUH_LdHessen_LRP_Darmstadt.pdf (accessed 5 May 2021).
12.
Hessisches Landesamt für Naturschutz, Umwelt und Geologie. Luftmessstelle Darmstadt [online]. Available at: https:// www.hlnug.de / messwerte/ datenportal/messstelle/ 2/ 1/ 0104/ (accessed 6 May 2021).
13.
Bundesnetzagentur. SMARD - Strommarktdaten [online]. Marktdaten, 2021. Available at: https:// www.smard.de / home/ downloadcenter/ download- marktdaten (accessed 6 May 2021).
14.
Matzer, C., Weller K., Dippold M., Lipp S., Röck M., Rexeis M. und S. Hausberger. Update of Emission Factors for HBEFA Version 4.1. Final report. I-05/19/CM EM-I-16/26/679, 9. Sep. 2019.
15.
Keller, M., et al. HBEFA Version 3.3. Hintergrundbericht. INFRAS, Bern, 2017.
16.
Chen, J., et al. A comparison of linear regression, regularization, and machine learning algorithms to develop Europe-wide spatial models of fine particles and nitrogen dioxide. Environment International, 130, 104934, 2019. [Crossref]
17.
Kohoutek, S. Quantifizierung der Wirkungen des Straßenverkehrs auf Partikel-und Stickoxid-Immissionen. Dissertation, Technische Universität Darmstadt, Darmstadt, 2011.
18.
Hrust, L., et al. Neural network forecasting of air pollutants hourly concentrations using optimised temporal averages of meteorological variables and pollutant concentrations. Atmospheric Environment, 43(35), 5588–5596, 2009. [Crossref]
19.
Baumbach, G. Luftreinhaltung. Entstehung, Ausbreitung und Wirkung von Luftverunreinigungen-Meßtechnik, Emissionsminderung und Vorschriften. Dritte Auflage. Springer: Berlin, Heidelberg, 1994. ISBN 3540568239.
20.
Neunhauserer, L., et al. Stand der Modellierungstechnik zur Prognose der NO2-Konzentrationen in Luftreinhalteplänen nach der 39. BImSchV. Bundesumweltamt, Dessau-Roslau, 2011.
Cite this:
APA Style
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BibTex Style
MLA Style
Chicago Style
GB-T-7714-2015
Steinhaus, T., Hartwig, M., & Beidl, C. (2021). Empirical Modelling of A Near-Traffic Emission Hotspot – Analysis of Immission Reduction Potentials. Int. J. Transp. Dev. Integr., 5(4), 353-366. https://doi.org/10.2495/TDI-V5-N4-353-366
T. Steinhaus, M. Hartwig, and C. Beidl, "Empirical Modelling of A Near-Traffic Emission Hotspot – Analysis of Immission Reduction Potentials," Int. J. Transp. Dev. Integr., vol. 5, no. 4, pp. 353-366, 2021. https://doi.org/10.2495/TDI-V5-N4-353-366
@research-article{Steinhaus2021EmpiricalMO,
title={Empirical Modelling of A Near-Traffic Emission Hotspot – Analysis of Immission Reduction Potentials},
author={Tim Steinhaus and Moritz Hartwig and Christian Beidl},
journal={International Journal of Transport Development and Integration},
year={2021},
page={353-366},
doi={https://doi.org/10.2495/TDI-V5-N4-353-366}
}
Tim Steinhaus, et al. "Empirical Modelling of A Near-Traffic Emission Hotspot – Analysis of Immission Reduction Potentials." International Journal of Transport Development and Integration, v 5, pp 353-366. doi: https://doi.org/10.2495/TDI-V5-N4-353-366
Tim Steinhaus, Moritz Hartwig and Christian Beidl. "Empirical Modelling of A Near-Traffic Emission Hotspot – Analysis of Immission Reduction Potentials." International Journal of Transport Development and Integration, 5, (2021): 353-366. doi: https://doi.org/10.2495/TDI-V5-N4-353-366
STEINHAUS T, HARTWIG M, BEIDL C. Empirical Modelling of A Near-Traffic Emission Hotspot – Analysis of Immission Reduction Potentials[J]. International Journal of Transport Development and Integration, 2021, 5(4): 353-366. https://doi.org/10.2495/TDI-V5-N4-353-366