Global_Environmental_Research_Vol.27No.1
53/80

Burnett, R.T., Pope, C.A. III, Ezzati, M., Olives, C., Lim, S.S., Mehta, S., Shin, H.H., Singh, G., Hubbell, B., Brauer, M., Anderson, H.R., Smith, K.R., Balmes, J.R., Bruce, N.G., Kan, H., Laden, F., Prüss-Ustün, A., Turner, M.C., Gapstur, S.M., Diver, W.R. and Cohen, A. (2014) An integrated risk function for estimating the global burden of disease attributable to ambient fine particulate matter exposure. Environmental Health Perspectives, 122: 397−403. Cao, J.J., Wu, F., Chow, J.C., Lee, S.C., Li, Y., Chen, S.W., An, Z.S., Fung, K.K., Watson, J.G., Zhu, C.S. and Liu, S.X. (2005) Characterization and source apportionment of atmospheric organic and elemental carbon during fall and winter of 2003 in Xi’an, China. Atmospheric Chemistry and Physics, 5: 3127−3137. Chen, Y., Takeuchi, M., Nah, T., Xu, L., Canagaratna, M.R., Stark, H., Baumann, K., Canonaco, F., Prévôt, A.S.H., Huey, L.G., Weber, R.J. and Ng, N.L. (2020) Chemical characterization of secondary organic aerosol at a rural site in the southeastern US: Insights from simultaneous high-resolution time-of-flight aerosol mass spectrometer (HR-ToF-AMS) and FIGAERO chemical ionization mass (CIMS) measurements. Atmospheric Chemistry and Physics, 20: 8421–8440. Chen, L.W.A., Verburg, P., Shackelford, A., Zhu, D., Susfalk, R., Chow, J.C. and Watson, J.G. (2010) Moisture effects on carbon and nitrogen emission from burning of wildland biomass. Atmospheric Chemistry and Physics, 10: 6617−6625. Cheong, K.H., Ngiam, N.J., Morgan,G.G., Pek, P.P., Tan, B.Y.-Q., Lai, J.W., Koh, J.M., Ong, M.E.H. and Ho, A.F.W. (2019) Acute health impacts of the Southeast Asian transboundary haze problem—A review. International Journal of Environmental Research and Public Health, 16: 3286. Chuang, M.T., Chou, C.C.K., Sopajaree, K., Lin, N.H., Wang, J.L., Sheu, G.R., Chang, Y.J. and Lee, C.T. (2013) Characterization of aerosol chemical properties from near-source biomass burning in the northern Indochina during 7-SEAS/Dongsha experiment. Atmospheric Environment, 78: 72−81. Crippa, P., Castruccio, S., Archer-Nicholls, S., Lebron, G.B., Kuwata, M., Thota, A., Sumin, S., Butt, E., Wiedinmyer, C. and Spracklen, D.V. (2016) Population exposure to hazardous air quality due to the 2015 fires in Equatorial Asia. Scientific Reports, 6: 37074. Crump, J. (ed.) (2017) Smoke on Water: Countering Global Threats from Peatland Loss and Degradation. Nairobi and Arendal: United Nations Environment Programme and GRID-Arendal. Retrieved from https://www.grida.no/publications/355 (accessed 3 April 2023) Fabbri, D., Torri, C., Simoneit, B.R.T., Marynowski, L., Rushidi, A.I. and Fabiańska, M.J. (2009) Levoglucosan and other cellulose and lignin markers in emissions from burning of Miocene lignites. Atmospheric Environment, 43: 2286−2295. Field, R.D., van der Werf, G.R., Fanin, T., Fetzer, E.J., Fuller, R., Jethva, Levye, H., Liveseyd, N.J., Luod, M., Torrese, O. and Worden, H.M. (2016) Indonesian fire activity and smoke pollution in 2015 show persistent nonlinear sensitivity to El Niño-induced drought. Proceedings of the National Academy of Sciences of the United States of America, 113(33): 9204–9209. Frka, S., Grgić, I., Turšič, J., Gini, M.I. and Eleftheriadis, K. (2018) Seasonal variability of carbon in humic-like matter of ambient size-segregated water soluble organic aerosols from urban background environment. Atmospheric Environment, 173: 239−247. Fröhlich, R., Cubison, M.J., Slowik, J.G., Bukowiecki, N., Prévôt, A.S.H., Baltensperger, U., Schneider, J., Kimmel, J.R., Gonin, M., Rohner, U., Worsnop, D.R. and Jayne, J.T. (2013) The ToF-ACSM: A portable aerosol chemical speciation monitor with TOFMS detection. Atmospheric Measurement Techniques, 6: Chemical Properties of the Southeast Asian Haze from Indonesian Peatland Fires spectrometer 225–3241. Girkin, N.T., Coper, H.V., Ledger, M.J., O’Reilly, P., Thornton, S.A., Åkesson, C.M., Cole, L.E.S., Hapsari, K.A., Hawthorne, D. and Roucoux, K.H. (2022) Tropical peatlands in the Anthropocene: The present and the future. Anthropocene, 40: 100354. Glauber, A.J., Moyer, S., Adriani, M. and Iwan, G. (2016). The Cost of Fire: An Economic Analysis of Indonesia’s 2015 Fire Crisis. Indonesia Sustainable Landscapes Knowledge Note No. 1. Jakarta: World Bank. Retrieved from https://openknowledge. worldbank.org/handle/10986/23840 (accessed 7 May 2023) Huang, X., Ding, K., Liu, J., Wang, Z., Tang, R., Xue, L., Wang, H., Zhang, Q., Tan, Z.-M., Fu, C., Davis, S.J., Andreae, M.O. and Ding, A. (2023) Smoke-weather interaction affects extreme wildfires in diverse coastal regions. Science, 379: 457–461. Huang, X. and Rein, G. (2014) Smouldering combustion of peat in wildfires: Inverse modelling of the drying and the thermal and oxidative decomposition kinetics. Combustion and Flame, 161: 1633−1644. Jahn, L.G., Jahl, L.G., Bland, G.D., Bowers, B.B., Monroe, L.W. and Sullivan, R.C. (2021) Metallic and crustal elements in biomass-burning aerosol and ash: Prevalence, significance, and similarity to soil particles. ACS Earth and Space Chemistry, 5(1): 136–148. Joosten, H. (2009) The Global Peatland CO2 Picture: Peatland Status and Drainage Related Emissions in All Countries of the World, p. 7, Wetlands International, Ede, the Netherlands. Koplitz, S.N., Mickley, L.J., Marlier, M.E., Buonocore, J.J., Kim, P.S., Liu, T., Sulprizio, M.P, DeFries, R.S., Jacob, D.J., Schwartz. J., Pongsiri, M. and Myers, S.S. (2016) Public health impacts of the severe haze in Equatorial Asia in September–October 2015: Demonstration of a new fire management strategies to reduce downwind smoke exposure. Environmental Research Letters, 11(9): 094023. Lohberger, S., Stängel, M., Atwood, E.C. and Siegert, F. (2018) Spatial evaluation of Indonesia’s 2015 fire-affected area and estimated carbon emissions using Sentinel-1. Global Change Biology, 24(2): 644–654. Lopez-Hilfiker, F.D., Pospisilova, V., Huang, W., Kalberer, M., Mohr, C., Stefenelli, G., Thornton, J.A., Baltensperger, U., Prevot, A.S.H. and Slowik, J.G. (2019) An extractive electrospray ionization time-of-flight mass spectrometer (EESI-TOF) for online measurement particles. Atmospheric Measurement Techniques, 12: 4867–4886. Mouteva, G.O., Czimczik1, C.I., Fahrni, S.M., Wiggins, E.B., Rogers, B.M., Veraverbeke, S., Xu, X., Santos, G.M., Henderson, J., Miller, C.E. and Randerson, J.T. (2015) Black carbon aerosol dynamics and isotopic composition in Alaska linked with boreal fire emissions and depth of burn in organic soils. Global Biogeochemical Cycles, 29: 1977–2000. Omar, M.S., Ifandi, E., Sukri, R.S., Kalaitzidis, S., Christanis, K., Lai, D.T.C., Bashir, S. and Tsikouras, B. (2022) Peatlands in Southeast Asia: A comprehensive geological review. Earth- Science Reviews, 232: 104149. Page, S.E., Rieley, J.O. and Banks, C.J. (2011) Global and regional importance of the tropical peatland carbon pool. Global Change Biology, 17: 798–818. Park, M., Joo, H.S., Lee, K., Jang, M., Kim, S.D., Kim, I., Borlaza, L.J.S., Lim, H., Shin, H., Chung, K.-H., Choi, Y.-H., Park, S.G., Bae, M.-S., Lee, J., Song, H. and Park, K. (2018) Differential toxicities of fine particulate matters from various sources. Scientific Reports, 8: 170078. Peng, B., Dong, Q., Li, F., Wang, T., Qiu, X. and Zhu, T. (2023) A systematic aromatic hydrocarbon derivatives: occurrences, levels, biotransformation, exposure biomarkers, and toxicity. Environment Science & Technology, 57: 15314−15335. framework atmospheric of review of polycyclic informing for aerosol 47

元のページ  ../index.html#53

このブックを見る