论文信息 - Quantifying the impact of residential heating on the urban air quality in a typical European coal combustion region. - 字舞流文

Quantifying the impact of residential heating on the urban air quality in a typical European coal combustion region.

The present investigation, carried out as a case study in a typical major city situated in a European coal combustion region (Krakow, Poland), aims at quantifying the impact on the urban air quality of residential heating by coal combustion in comparison with other potential pollution sources such as power plants, industry, and traffic. Emissions were measured for 20 major sources, including small stoves and boilers, and the particulate matter (PM) was analyzed for 52 individual compounds together with outdoor and indoor PM10 collected during typical winter pollution episodes. The data were analyzed using chemical mass balance modeling (CMB) and constrained positive matrix factorization (CMF) yielding source apportionments for PM10, B(a)P, and other regulated air pollutants namely Cd, Ni, As, and Pb. The results are potentially very useful for planning abatement strategies in all areas of the world, where coal combustion in small appliances is significant. During the studied pollution episodes in Krakow, European air quality limits were exceeded with up to a factor 8 for PM10 and up to a factor 200 for B(a)P. The levels of these air pollutants were accompanied by high concentrations of azaarenes, known markers for inefficient coal combustion. The major culprit for the extreme pollution levels was demonstrated to be residential heating by coal combustion in small stoves and boilers (>50% for PM10 and >90% B(a)P), whereas road transport (<10% for PM10 and <3% for B(a)P), and industry (4-15% for PM10 and <6% for B(a)P) played a lesser role. The indoor PM10 and B(a)P concentrations were at high levels similar to those of outdoor concentrations and were found to have the same sources as outdoors. The inorganic secondary aerosol component of PM10 amounted to around 30%, which for a large part may be attributed to the industrial emission of the precursors SO2 and NOx.

Luisa Marelli | Peter Wåhlin | Stefan Tsakovski | Mar Viana | Annette Borowiak | Xavier Querol | Daniel Mira-Salama | Ute Hansen | Heikki Junninen | Covadonga Astorga | S. Tsakovski | P. Wåhlin | J. Mønster | X. Querol | M. Viana | C. Astorga | H. Junninen | G. Norris | B. Larsen | K. Stańczyk | F. Lagler | L. Marelli | A. Borowiak | M. Rey | J. Horák | Gary A Norris | Maria Rey | Bo R Larsen | Rachelle M Duvall | U. Hansen | Matthew Duane | Jacob Mønster | Kevin Douglas | Jose Cancelinha | Victtorio Forcina | Anne Müller | Fritz Lagler | Joanna Niedzialek | Bostian Paradiz | Jose Jimenez | Krzysztof Stanczyk | Jiri Horák | A. Müller | R. Duvall | M. Duane | D. Mira-Salama | J. Cancelinha | K. Douglas | V. Forcina | J. Niedzialek | B. Paradiž | J. Jimenez

[1] Tony Fletcher,et al. PM10 and PM2.5 concentrations in Central and Eastern Europe: results from the Cesar study , 2001 .

[2] P. Paatero,et al. Application of positive matrix factorization in source apportionment of particulate pollutants in Hong Kong , 1999 .

[3] James J. Schauer,et al. Source apportionment of airborne particulate matter using organic compounds as tracers , 1996 .

[4] J. Pastuszka. Study of PM-10 and PM-2.5 concentrations in southern Poland , 1997 .

[5] P. Lioy,et al. Source apportionment and source/sink relationships of PAHs in the coastal atmosphere of Chicago and Lake Michigan , 1999 .

[6] E. Sawicki,et al. THE QUANTITATIVE COMPOSITION OF AIR POLLUTION SOURCE EFFLUENTS IN TERMS OF AZA HETEROCYCLIC COMPOUNDS AND POLYNUCLEAR AROMATIC HYDROCARBONS. , 1965, Air and water pollution.

[7] M. Gallorini,et al. Comparative studies on the concentrations of some elements in the urban air particulate matter in Lodz City of Poland and in Milan, Italy. , 2003, Environment international.

[8] B. Turpin,et al. Polycyclic aromatic hydrocarbons in the indoor and outdoor air of three cities in the U.S. , 2002, Environmental science & technology.

[9] Hung-Yu Chen,et al. Azaarenes in the Aerosol of an Urban Atmosphere , 1998 .

[10] Christoph Hueglin,et al. Source apportionment of submicron organic aerosols at an urban site by factor analytical modelling of aerosol mass spectra , 2007 .

[11] Hugh Coe,et al. Source attribution of urban smog episodes caused by coal combustion , 2008 .

[12] M. Kleeman,et al. Source apportionment of secondary organic aerosol during a severe photochemical smog episode , 2007 .

[13] D. Locke,et al. Characterization of aza-arenes in basic organic portion of suspended particulate matter , 1977 .

[14] Y. E L E N,et al. Polycyclic Aromatic Hydrocarbons in the Indoor and Outdoor Air of Three Cities in the U , 2002 .

[15] Nigel N. Clark,et al. Variations in Speciated Emissions from Spark-Ignition and Compression-Ignition Motor Vehicles in California’s South Coast Air Basin , 2007, Journal of the Air & Waste Management Association.

[16] Eliseo Monfort,et al. Source origin of trace elements in PM from regional background, urban and industrial sites of Spain , 2007 .

[17] Christoph Hueglin,et al. Source attribution of submicron organic aerosols during wintertime inversions by advanced factor analysis of aerosol mass spectra. , 2008, Environmental science & technology.

[18] R. Löfstedt. Transboundary environmental problems: The case of the burning of coal in Poland for heating and electricity purposes , 1998 .

[19] Werner A. Stahel,et al. Contribution of road traffic to ambient fine particle concentrations (PM10) in Switzerland , 2000 .

[20] B. Kopcewicz,et al. Long-term measurements of iron-containing aerosols by Mössbauer spectroscopy in Poland , 2001 .

[21] P. Clausen,et al. Determination of basic azaarenes and polynuclear aromatic hydrocarbons in airborne particulate matter by gas chromatography , 1986 .

[22] Judith C. Chow,et al. Evaluation of organic markers for chemical mass balance source apportionment at the Fresno Supersite , 2006 .