Urban ozone air quality impact of emissions from vehicles using reformulated gasolines and M85

Urban ozone air quality impact of emissions from vehicles using reformulated gasolines and M85

The urban ozone air quality impact of exhaust emissions from vehicles using reformulated gasolines and flexible/variable-fuel vehicles using M85 has been studied using emissions data from the Auto/Oil Air Quality Improvement Research Program and a single-cell trajectory air quality model with two di...

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Veröffentlicht in:Atmospheric environment (1994) 1994, Vol.28 (17), p.2777-2787
Hauptverfasser: Chock, D.P., Winkler, S.L., Chang, T.Y., Rudy, S.J., Shen, Z.K.
Format: Artikel
Sprache:eng
Schlagworte:
Air quality
air quality model
Air. Soil. Water. Waste. Feeding
alternative fuels
Applied sciences
Atmospheric pollution
Biological and medical sciences
Carbon
chemical mechanisms
Chemical reactions
Environment. Living conditions
Exact sciences and technology
Gasoline
Mathematical models
Medical sciences
Ozone layer
Pollution
Pollution sources. Measurement results
Public health. Hygiene
Public health. Hygiene-occupational medicine
Q1
Reformulated gasolines
Toluene
trajectory box model
Transports
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container_end_page 2787
container_issue 17
container_start_page 2777
container_title Atmospheric environment (1994)
container_volume 28
creator Chock, D.P.
Winkler, S.L.
Chang, T.Y.
Rudy, S.J.
Shen, Z.K.
description The urban ozone air quality impact of exhaust emissions from vehicles using reformulated gasolines and flexible/variable-fuel vehicles using M85 has been studied using emissions data from the Auto/Oil Air Quality Improvement Research Program and a single-cell trajectory air quality model with two different chemical mechanisms (the updated version of Carbon-Bond-IV (CB4) and the LCC mechanism). Peak ozone concentrations are predicted for each fuel for all combinations of the following ambient conditions: low and high atmospheric dilution or mixing height, four NMOG/NO x ratios, two each of the initial NMOG concentration, the vehicular contribution to the ambient air, and the NMOG composition of the initial ambient mixture. The ozone impact of a fuel dependent strongly on the atmospheric dilution and NMOG/NO x ratio of an area. The differences in ozone impact among fuels are limited under the condition of high atmospheric dilution and a high NMOG/NO x ratio. The ozone-forming potentials (OFPs) for the exhaust emissions based on the maximum incremental reactivities (MIRs) for various fuels are generally well correlated with model-calculated peak ozone levels at a low NMOG/NO x ratio. These OFPs can serve to separate out fuels with rather different reactivities, but not fuels with comparable reactivities. Model-calculated ozone levels for various fuels based on CB4 and LCC mechanisms are relatively well correlated at low NMOG/NO x ratios, but much less so at higher ratios. Fuels with a high aromatic content, including high-toluene fuels, tend to be ranked more favorably by CB4 than by LCC. On the other hand, M85 is ranked more favorably by LCC than by CB4. Fuels with a low 90% boiling point and a low content of aromatics and olefins are generally less reactive. M85 would be an attractive fuel if the formaldehyde emissions could be curtailed significantly.
doi_str_mv 10.1016/1352-2310(94)90081-7
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Model-calculated ozone levels for various fuels based on CB4 and LCC mechanisms are relatively well correlated at low NMOG/NO x ratios, but much less so at higher ratios. Fuels with a high aromatic content, including high-toluene fuels, tend to be ranked more favorably by CB4 than by LCC. On the other hand, M85 is ranked more favorably by LCC than by CB4. Fuels with a low 90% boiling point and a low content of aromatics and olefins are generally less reactive. M85 would be an attractive fuel if the formaldehyde emissions could be curtailed significantly.</description><subject>Air quality</subject><subject>air quality model</subject><subject>Air. Soil. Water. Waste. Feeding</subject><subject>alternative fuels</subject><subject>Applied sciences</subject><subject>Atmospheric pollution</subject><subject>Biological and medical sciences</subject><subject>Carbon</subject><subject>chemical mechanisms</subject><subject>Chemical reactions</subject><subject>Environment. 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Model-calculated ozone levels for various fuels based on CB4 and LCC mechanisms are relatively well correlated at low NMOG/NO x ratios, but much less so at higher ratios. Fuels with a high aromatic content, including high-toluene fuels, tend to be ranked more favorably by CB4 than by LCC. On the other hand, M85 is ranked more favorably by LCC than by CB4. Fuels with a low 90% boiling point and a low content of aromatics and olefins are generally less reactive. M85 would be an attractive fuel if the formaldehyde emissions could be curtailed significantly.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/1352-2310(94)90081-7</doi><tpages>11</tpages></addata></record>
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identifier ISSN: 1352-2310
ispartof Atmospheric environment (1994), 1994, Vol.28 (17), p.2777-2787
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1873-2844
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source ScienceDirect Journals (5 years ago - present)
subjects Air quality
air quality model
Air. Soil. Water. Waste. Feeding
alternative fuels
Applied sciences
Atmospheric pollution
Biological and medical sciences
Carbon
chemical mechanisms
Chemical reactions
Environment. Living conditions
Exact sciences and technology
Gasoline
Mathematical models
Medical sciences
Ozone layer
Pollution
Pollution sources. Measurement results
Public health. Hygiene
Public health. Hygiene-occupational medicine
Q1
Reformulated gasolines
Toluene
trajectory box model
Transports
title Urban ozone air quality impact of emissions from vehicles using reformulated gasolines and M85
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