Particulate matter in indoor spaces: known facts and the knowledge gaps

• Autorzy: Rogula-Kopiec P. , Pastuszka J.S. , Rogula-Kozlowska W. , Majewski G.

Warianty tytułu

PL

Pył zawieszony w pomieszczeniach: znane fakty i luki w stanie wiedzy

• Języki publikacji: EN

Abstrakty

EN

As people spend most of the time in closed spaces (flats, workplaces, schools etc.), the indoor air has been researched for many years all over the world. Particulate matter (PM) is one of the most often examined pollutants in the indoor and outdoor air. The following study presents the facts about PM in closed spaces and the most often taken actions. The least known aspects related to the indoor air pollution with PM are demonstrated. The indoor space of various service and office buildings/facilities (not related to production, i.e. offices, shops, beauty parlours, restaurant kitchens, restaurants, pubs etc.) seem to be an unrecognized area in the air pollution studies. Importantly, a great number of people work in such spaces all over the world and thus spend there a large part of their lives.

PL

Ponieważ większość życia ludzie spędzają w pomieszczeniach zamkniętych (mieszkania, miejsca pracy, szkoły, itp.), powietrze wewnętrzne jest od wielu lat przedmiotem zainteresowania grup badaczy na całym świecie. Jednym z najczęściej badanych zanieczyszczeń w powietrzu wewnętrznym jest, podobnie jak w powietrzu zewnętrznym, pył zawieszony, PM. W pracy przedstawiono udokumentowane fakty dotyczące PM w pomieszczeniach zamkniętych i najczęściej podejmowane kierunki działań w tym zakresie. Wskazano również obszar najsłabiej rozpoznany pod względem zanieczyszczenia powietrza pyłem zawieszonym. Przestrzeń wewnętrzna różnego rodzaju obiektów usługowo - biurowych (nieprodukcyjnych, tj. biura, sklepy, salony urody, kuchnie restauracyjne, restauracje, puby itp.) wydaje się być zupełnie nierozpoznanym obszarem jeżeli chodzi o zanieczyszczenie powietrza. Tymczasem, właśnie w takich obiektach pracuje i tym samym spędza dużą część swojego życia mnóstwo osób na całym świecie.

Słowa kluczowe

EN

indoor environment; indoor air; indoor aerosol; particulate matter; suspended dust; resuspension; dust emission; emission source; housing condition; work condition

• Wydawca: -
• Czasopismo: Annals of Warsaw University of Life Sciences - SGGW. Land Reclamation
• Rocznik: 2015
• Tom: 47
• Numer: 1
• Opis fizyczny: p.43-54,ref.

Twórcy

autor

Rogula-Kopiec P.

• Institute of Environmental Engineering, Polish Academy of Sciences, M.Sklodowska-Curie 34, 41-819 Zabrze, Poland

autor

Pastuszka J.S.

• Department of Air Protection, Silesian University of Technology, Poland

autor

Rogula-Kozlowska W.

• Institute of Environmental Engineering, Polish Academy of Sciences, M.Sklodowska-Curie 34, 41-819 Zabrze, Poland

autor

Majewski G.

• Faculty of Civil and Environmental Engineering, Warsaw University of Life Sciences – SGGW, Warsaw, Poland

Bibliografia

• ALVES C.A., URBAN R.C., PEGAS P.N., NUNES T. 2014. Indoor/Outdoor relationships between PM10 and associated organic compounds in a primary school. Aerosol and Air Quality Research 14 (1), 86-98.
• CHEN C., ZHAO B. 2011: Review of relationship between indoor and outdoor particles: I/O ratio, infiltration factor and penetration factor. Atmos. Environ. 45 (2), 275-288.
• CHOW J.C. 1995: Measurement methods to determine compliance with ambient air quality standards for suspended particles. J. Air Waste Manage Assoc. 45, 320-382.
• COLBECK I., NASIR Z.A., ALI Z. 2010: Characteristics of indoor/outdoor particulate pollution in urban and rural residential environment of Pakistan. Indoor Air 20 (1), 40-51.
• DOCKERY D.W., SPENGLER J.D. 1981: Indoor-Outdoor Relationship of Respirable Sulfates and Particles. Atmos. Environ. 15, 335-343.
• DUDZIŃSKA M.R. (Ed.) 2011: Management of Indoor Air Quality. Taylor & Francis Group, London, CRC Press/Balkema.
• ENGLERT N. 2004: Fine particles and human health - a review of epidemiological studies. Toxicol. Lett. 149, 235-242.
• GÓRNY R., JĘDRZEJCZAK A., PASTUSZKA J.S. 1995: Airborne particles and heavy metals in upper Silesia outdoors and indoors. Roczn. PZH. XLVI (2), 151-161.
• GODISH T. 2000: Indoor Environmental Quality. CRC Press, Boca Raton, 456.
• GURLEY E.S., SALJE H., HOMAIRA N., RAM P.K., HAQUE R., PETRI W.A. AZZIZ--BAUMGARTNER E. 2013: Seasonal concentrations and determinants of indoor particulate matter in a low-income community in Dhaka, Bangladesh. Environ. Res. 121, 11-16.
• HINDS W.C. 1998: Aerosol Technology. Properties, Behavior, and Measurement of Airborne Particles. Second Edition. John Wiley & Sons, New York.
• JONES N.C., THORNTON C.A., MARK D., HARRISON R.M. 2000: Indoor/Outdoor Relationships of Particulate Matter in Domestic Homes with Roadside, Urban and Rural Locations. Atmos. Environ. 34, 2603-2612.
• KLEJNOWSKI K., PASTUSZKA J.S., ROGU-LA-KOZŁOWSKA W., TALIK E., KRASA A. 2012: Mass Size Distribution and Chemical Composition of the Surface Layer of Summer and Winter Airborne Particles in Zabrze, Poland. Bull. Environ. Contam. Toxicol. 88 (2), 255-259.
• LEVY J.I., LEE K., SPENGLER J.D., YANA-GISAWA Y., BISHOF W., BRAATHEN O., CHUNG Y., COWARD S., GUTSCHMIDT K., JIN K., KORENAGA T., OHKODA Y., MENESES F., PASTUSZKA J., PATIL R.S., QUING X., RAIZENNE M., SALONEN R.O., SEGA K., SEIFERT B., SHAH S., TORRES E., YOON D., ZHANG X. 1998: Impact of residential nitrogen dioxide exposure on personal exposure: an international study. J. Air Waste Manage Assoc. 48, 553-560.
• LI C.S., LIN C.H. 2003: Carbon Profile of Residential Indoor PM1 and PM2.5 in the Subtropical Region. Atmos. Environ. 37, 881-888.
• LIOY P.J., FAN Z, ZHANG J., GEORGOPOU-LOS P., WANG S.W., OHMAN-STRICK-LAND P., WU X., ZHU X., HARRINGTON J., TANG X., MENG Q., JUNG K.H., KWON J., HERNANDEZ M., BONNANO L., HELD J., NEAL J. 2011: Personal and ambient exposures to air toxics in Camden, New Jersey. Res. Rep. Health Eff. Inst. 160, 3-127.
• LIPPMAN M. 2009: Environmental Toxicants: Human Exposures and Their Health Effects. John Wiley & Sons, New York, 987.
• LIS D.O., PASTUSZKA J.S. 1997: Bacterial and fungal aerosol in homes without and with mold problem in Upper Silesia, Poland. Preliminary results. J. Aerosol Sci. 28, 665-666.
• LONG C.M., SUH H.H., KOUTRAKIS P. 2000: Characterization of Indoor Particle Sources Using Continuous Mass and Size Monitors. J. Air Waste Manage Assoc. 50, 1236-1250.
• MAJEWSKI G., ĆWIEK K. 2013: Effect of a different degree of anthropogenic trans-formation on the formation of bioclimatic conditions - Warsaw case study. Ann. Warsaw Univ. of Life Sci. - SGGW, Land Reclamation 45 (1), 97-109.
• MONN C. 2001: Exposure Assessment of Air Pollutants: A Review on Spatial Heterogeneity and Indoor/Outdoor/Personal Exposure to Suspended Particulate Matter, Nitrogen, Dioxide and Ozone. Atmos. Environ. 35, 1-32.
• MORAWSKA L., SALTHAMMER T. 2006: Indoor Environment. Airborne Particles and Settled Dust. John Wiley & Sons, New York.
• OSTRO B., FENG W.Y., BROADWIN R., GREEN S., LIPSETT M. 2007: The effects of components of fine particulate air pollution on mortality in California: results from CAL-FINE. Environ. Health Persp. 115, 13-19.
• ÖZKAYNAK H., XUE J SPENGLER J., WALLACE L., PELLIZZARI E., JENKINS P. 1996: Personal Exposure to Airborne Particles and Metals: Results fro the Particle Team Study in Riverside, C.A. J. Expo. Sci. Environ. Epidemiol. 6, 57-78.
• PASTUSZKA J.S., ZEJDA J.E., WLAZŁO A., LIS D.O., MALISZEWSKA I. 1998: Occurrence of bronchial asthmas symptoms in children, and the level of exposure to dust, bacterial and fungal aerosols in Sosnowiec apartments. Problemy Ekologii 5, 171-173.
• PASTUSZKA J.S., MARCHWIŃSKA-WYR-WAŁ E., WLAZŁO A. 2005: Bacterial aerosol in the Silesian hospitals: preliminary results. Pol. J. Environ. Studies 14, 883-890.
• PASTUSZKA J.S., ROGULA-KOZŁOWSKA W., ZAJUSZ-ZUBEK E. 2010: Characterization of PM10 and PM2.5 and associated heavy metals at the crossroads and urban background site in Zabrze, Upper Silesia, Poland, during the smog episodes. Environ. Monit. Assess. 168, 613-627.
• PASTUSZKA J.S., WAWROŚ A., TALIK E., PAW U.K.T. 2003: Optical and chemical characteristics of the atmospheric aerosol in four towns in southern Poland. Sci. Tot. Environ. 309, 237-251.
• PASTUSZKA J.S., KYAW., THA PAW U., LIS D.O., WLAZŁO A., ULFIG K. 2000: Bacterial and fungal aerosol in indoor environment in Upper Silesia, Poland. Atmos. Environ. 34, 3833-3842.
• POLEDNIK B. 2013: Particulate matter and student exposure in school classrooms in Lublin, Poland. Environ. Res. 120, 134-139.
• POLLARD S.L., WILLIAMS D.L., BREYSSE P.N. 2014: A cross-sectional study of determinants of indoor environmental exposures in households with and without chronic exposure to biomass fuel smoke. Environ. Health 13 (1), 21.
• ROGULA-KOZŁOWSKA W., BŁASZCZAK B., SZOPA S., KLEJNOWSKI K., SÓWKA I., ZWOŹDZIAK A., JABŁOŃSKA M., MATHEWS B. 2013: PM2.5 in the central part of Upper Silesia, Poland: concentrations, elemental composition, and mobility of components. Environ. Monit. Assess. 185, 581-601.
• ROGULA-KOZŁOWSKA W., KLEJNOWSKI K., ROGULA-KOPIEC P., OŚRÓDKA L., KRAJNY E., BŁASZCZAK B, MATHEWS B. 2014: Spatial and seasonal variability of the mass concentration and chemical composition of PM2.5 in Poland. Air Qual. Atmos. Health. 7, 41-58.
• ROGULA-KOZŁOWSKA W., KLEJNOWSKI K. 2013: Submicrometer aerosol in rural and urban backgrounds in Southern Poland primary and secondary components of PM1. Bull. Environ. Contam. Toxicol. 90 (1), 103-109.
• SCHROEDER W.H., DOBSON M., KANE D.M.,JOHNSON N.D. 1987: Toxic trace elements associated with airborne particulate matter: a review. J. Air Pollut. Control Assoc. 37, 1267-1285.
• SILLANPÄÄ M., HILLAMO R., SAARIKOSKI S., FREY A., PENNANEN A., MAKKONEN U., SPOLNIK Z., VAN GRIEKEN R., BRA-NIŠ M., BRUNEKREEF B., CHALBOT M.C., KUHLBUSCH T., SUNYER J., KER-MINEN V.M., KULMALA M., SALONEN R.O. 2006: Chemical composition and mass closure of particulate matter at six urban sites in Europe. Atmos. Environ. 40, 212-223.
• SIMONI M., BIAVATTI P., CARROZZI L., VIEGI G., PAOLETTI P., MATTEUCCI G., ZILIANI G.L., IOANNILLI E., SAPIGNI T. 1998: Po Tiver Delta (North Italy) Indoor Epidemiological Study: Home Characteristics, Indoor Pollutants, And Subjects' Daily Activity Pattern. Indoor Air 8, 70-79.
• SÓWKA I., ZWOŹDZIAK A., TRZEPLA--NABAGLO K., SKRĘTOWICZ M., ZWOŹDZIAK J. 2012: PM2.5 elemental composition and source apportionment in residential area of Wrocław, Poland. Environ. Prot. Eng. 38, 73-79.
• WHITBY K.J. 1978: The Physical Characteristics of Sulfur Aerosol. Atmos. Environ. 12, 135-139.
• WICHMANN H.E. 2004: Health effects of particles in ambient air. Int. J. Hyg. Environ. Heal. 207, 399-407.
• WOROBIEC A., SAMEK L., KRATA A., Van MEEL K., KRUPINSKA B., STEFANIAK E.A., Van GRIEKEN R. 2010: Transport and deposition of airborne pollutants in exhibition areas located in historical buildings - study in Wawel Castle Museum in Cracow, Poland. Journal of Cultural Heritage 11 (3), 354-359.
• YOCOM J.E. 1982: Indoor-Outdoor Air Quality Relationships. A Critical Review. J. Air Con-trolAssoc. 32, 500-520.
• ZHANG W., LEI T., LIN Z.Q., ZHANG H.S., YANG D.F., XI Z.G., CHEN J.H., WANG W. 2011: Pulmonary toxicity study in rats with PM10 and PM2.5: differential responses related to scale and composition. Atmos. Environ. 45, 1034-1041.
• ZWOŹDZIAK A., SÓWKA I., KRUPIŃSKA B., ZWOŹDZIAK J., NYCH A. 2013: Infiltration or indoor sources as determinants of the elemental composition of particulate matter inside a school in Wrocław, Poland? Build. Environ. 66, 173-180.

Identyfikatory

DOI

10.1515/sggw-2015-0004