Impact of urbanization on gas-phase pollutant concentrations: a regional-scale, model-based analysis of the contributing factors

Huszár, Peter; Karlický, Jan; Bartík, Lukáš; Liaskoni, Marina; Perez, Alvaro Patricio Prieto; Šindelářová, Kateřina

doi:10.5194/acp-22-12647-2022

Cited by 7 publications

(13 citation statements)

References 139 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The study uses the same models, model settings and same input data as Huszar et al (2022). Here we will therefor summarize only the most relevant information about the model setup stressing the eventual differences.…”

Section: Models Usedmentioning

confidence: 99%

“…ii) it was detailed above that urban areas exhibit higher-temperature and moreover it seems that cloudiness is somewhat reduced above cities too (w.r.t rural regions) meaning higher solar incident radiation at the surface (Karlický et al, 2020) -both promoting the vegetation metabolism resulting in higher fluxes of BVOC (Guenther et al, 2006). These two effects (i and ii) counteract but the dominant one is probably the vegetation effect (Li et al, 2019;Huszar et al, 2022), i.e. due to urbanization, BVOC emissions are reduced.…”

Section: Introductionmentioning

confidence: 96%

“…In case of secondary pollutant the situation is more difficult as the total impact of UCMF is a combination of the direct impact on the secondary pollutant and the impact on its precursors; e.g. for ozone the resulting effect is an increase (over the surface or at higher levels) (Janssen et al, 2017;Yim et al, 2019;Li et al, 2019;Kim et al, 2021;Kang et al, 2022;Huszar et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…However, this is modulated also by the modifications of precursor concentrations as a result of the land-surface changes associated with RUT. For example, Huszar et al (2022) modelled decreases of NO 2 and SO 2 concentration due to land-surface change (and hence dry deposition modifications) alone which would imply an amplification of the land-surface induced decrease of nitrates and sulphates. Further, it can be assumed that ammonia (NH 3 ) concentrations are also modified by modified dry-deposition velocities which in turn has impacts on the amount of ammonium salts formed.…”

Section: Introductionmentioning

confidence: 99%

“…These four impacts had been formulated also in our previous paper Huszar et al (2022) where we looked, using regional chemistry-transport models coupled to regional climate models, at their effect on gas-phase chemistry, however most of the other studies mentioned above focused either at the total impact of the urbanization or at some of the individual impacts without a detailed analysis of the separate contribution of each of them. The mentioned Huszar et al (2022) study indeed aimed at the quantification of each individual impact as well as the total impact as one of the first studies of this kind analysing central European domain at moderate horizontal resolution. Here, as a follow-up study, we extend our analysis conducted there to particulate matter and will investigate, how the total PM (as PM2.5, particles of diameter less than 2.5 µm) as well as their primary and secondary components respond to these impacts.…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Impact of urbanization on fine particulate matter concentrations over central Europe

Huszar,

Perez,

Bartík

et al. 2023

Preprint

View full text Add to dashboard Cite

Abstract. The rural-to-urban transformation (RUT) is the process of turning rural or natural land-surface into urban one which brings important modifications in the surface causing well know effects like the urban heat island (UHI), reduced wind-speeds, increased boundary layer heights and so on. Moreover, with concentrated human activities RUT introduces new emission source which greatly perturbs the local and regional air-pollution. Particulate matter (PM) is one of key pollutants responsible for deterioration of urban air-quality and is still a major issue in European cities with frequent exceedances of limit values. Here we introduce a regional chemistry-climate model (regional climate model RegCM coupled offline to chemistry transport model CAMx) study which quantifies how the process of RUT modified the PM concentrations over central Europe including the underlying controlling mechanisms that contribute to the final PM pollution. Apart from the two most studied ones, i) the urban emissions and ii) the urban canopy meteorological forcing (UCMF, i.e. the impact of modified meteorological conditions on air-quality) we analyze also two less studied contributors to the RUT’s impact on air-quality: iii) the impact of modified dry-deposition velocities due to urbanized land-use and iv) the impact of modified biogenic emissions due to urbanization induced vegetation modifications and changes in meteorological conditions which affect these emissions. To calculate the magnitude of each of these RUT contributors, we perform a cascade of simulations were each contributor is added one-by-one to the reference state while focus is given on PM2.5 (particulate matter with diameter less then 2.5 µm). We also look at their primary and secondary components, namely primary elemental carbon (PEC), sulphates (PSO4), nitrates (PNO3), ammonium (PNH4) and secondary organic aerosol (SOA). The validation using surface measurements showed a systematic negative bias for the total PM2.5 which is probably caused by underestimated organic aerosol and partly by the negative bias in sulphates and elemental carbon. For ammonium and nitrate, the underestimation is limited to the warm season while for winter, the model tends to overestimate their concentrations. However, in each case, the annual cycle is reasonably captured. We evaluated the RUT impact on PM2.5 over an ensemble of 19 central European cities and found that the total impact of urbanization is about 2–3 and 1–1.5 µgm−3 in winter and summer, respectively. This is mainly driven by the impact of emissions alone causing a slightly higher impact (1.5–3.5 and 1.2–2 µgm−3 in winter and summer), while the effect of UCMF was a decrease at about 0.2–0.5 µgm−3 (in both seasons) which was mainly controlled by enhanced vertical eddy-diffusion while increases were modelled over rural areas. The transformation of rural land-use into urban one caused an increase of dry-deposition velocities by around 30–50 % which alone resulted in a decrease of PM2.5 by 0.1–0.25 µgm−3 in both seasons. Finally, the impact of biogenic emission modification due to modified land-use and meteorological conditions caused a decrease of summer PM2.5 of about 0.1 µgm−3 while the winter effects were negligible. The total impact of urbanization on aerosol components is modelled to be (values indicate winter and summer averages) 0.4 and 0.3 µgm−3 for PEC, 0.05 and 0.02 µgm−3 for PSO4, 0.1 and 0.08 µgm−3 for PNO3, 0.04 and 0.03 µgm−3 for PNH4 and 0 and 0.05 µgm−3 for SOA. The main contributor of each of these components was the impact of emissions which was usually larger than the total impact due to the fact that UCMF counteracted with a decrease. For each aerosol component the impact of modified DV was a clear decrease of concentration and finally, the modifications of biogenic emissions impacted predominantly SOA causing a summer decrease while a very small secondary effect of secondary inorganic aerosol was modelled too (they increased). In summary, we showed that when analyzing the impact of urbanization on PM pollution, apart from the impact of emissions and the urban canopy meteorological forcing, one has to consider also the effect of modified land-use and its impact on dry-deposition. These were shown to be important in both seasons. For the effect of modified biogenic emissions, our calculations showed that it acts on PM2.5 predominantly trough SOA modifications which turned to be important only during summer.

show abstract

Section: Models Usedmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Impact of urbanization on fine particulate matter concentrations over central Europe

Huszar,

Perez,

Bartík

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

Effects of chemical mechanism and meteorological factors on the concentration of atmospheric pollutants in the megacity Beijing, China

Li,

Wu,

Wang

et al. 2024

Atmospheric Environment

View full text Add to dashboard Cite

The long-term impact of biogenic volatile organic compound emissions on urban ozone patterns over central Europe: contributions from urban and rural vegetation

Liaskoni,

Huszár,

Bartík

et al. 2024

Atmos. Chem. Phys.

View full text Add to dashboard Cite

Abstract. The paper evaluates the long-term (2007–2016) impact of biogenic volatile organic compound (BVOC) emissions on urban ozone patterns over central Europe, specifically focusing on the contribution of urban vegetation using a regional climate model coupled offline to a chemistry transport model. BVOCs are emitted by terrestrial ecosystems, and their impact is considered especially important over NOx-rich environments such as urban areas. The study evaluates the impact of BVOC emissions on ozone (O3), formaldehyde (HCHO), and hydroxyl radical (OH) near-surface concentrations, showing an increase in summer ozone by 6 %–10 % over large areas in central Europe due to their emissions. It also demonstrates a substantial increase in formaldehyde concentrations. Additionally, the impact of BVOC emissions on hydroxyl radical concentrations shows a decrease over most of the modeled region by 20 %–60 %, with some increases over urban areas. Impacts on peroxy radicals (HO2 and higher RO2) are shown too. Importantly, the study explores the partial role of urban vegetation in modulating ozone and evaluates its contribution to the overall ozone formation due to all BVOC emissions. The findings reveal that urban BVOC emissions contribute to around 10 % of the total impact on ozone and formaldehyde concentrations in urban areas, indicating their significant but localized influence. The study also conducts sensitivity analyses to assess the uncertainty arising from the calculation of the urban fraction of BVOC emissions. The results show that the impact of urban BVOC emissions responds to their magnitude nearly linearly, with variations up to 4-fold, emphasizing the importance of accurately quantifying the urban BVOC fluxes. Overall, the study sheds light on the intricate relationship between urban vegetation, BVOC emissions, and their impact on atmospheric chemistry, providing valuable insights into the regional chemistry of BVOC emissions over central Europe and the causes of urban ozone pollution.

show abstract

Impact of urbanization on gas-phase pollutant concentrations: a regional-scale, model-based analysis of the contributing factors

Cited by 7 publications

References 139 publications

Impact of urbanization on fine particulate matter concentrations over central Europe

Impact of urbanization on fine particulate matter concentrations over central Europe

Effects of chemical mechanism and meteorological factors on the concentration of atmospheric pollutants in the megacity Beijing, China

The long-term impact of biogenic volatile organic compound emissions on urban ozone patterns over central Europe: contributions from urban and rural vegetation

Contact Info

Product

Resources

About