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| ???org.dspace.app.webui.jsptag.ItemTag.dcfield??? | Value | Language |
|---|---|---|
| dc.contributor.advisor | 丁育頡 | zh_TW |
| dc.contributor.advisor | Yu-Chieh Ting | en |
| dc.contributor.author | 柯宜汝 | zh_TW |
| dc.contributor.author | Yi-Ru Ko | en |
| dc.date.accessioned | 2023-10-03T16:17:04Z | - |
| dc.date.available | 2023-11-09 | - |
| dc.date.copyright | 2023-10-03 | - |
| dc.date.issued | 2023 | - |
| dc.date.submitted | 2023-08-02 | - |
| dc.identifier.citation | Ahmad, M., Manjantrarat, T., Rattanawongsa, W., Muensri, P., Saenmuangchin, R., Klamchuen, A., Aueviriyavit, S., Sukrak, K., Kangwansupamonkon, W. & Panyametheekul, S. 2022. Chemical Composition, Sources, and Health Risk Assessment of PM2.5 and PM10 in Urban Sites of Bangkok, Thailand. International Journal of Environmental Research and Public Health, 19.
Andreae, M. O. 1983. Soot Carbon and Excess Fine Potassium: Long-Range Transport of Combustion-Derived Aerosols. Science, 220, 1148-1151. Bai, Z., Zhang, L., Cheng, Y., Zhang, W., Mao, J., Chen, H., Li, L., Wang, L. & Chen, J. 2020. Water/Methanol-Insoluble Brown Carbon Can Dominate Aerosol-Enhanced Light Absorption in Port Cities. Environmental Science & Technology, 54, 14889-14898. Bond, T. C., Doherty, S. J., Fahey, D. W., Forster, P. M., Berntsen, T., Deangelo, B. J., Flanner, M. G., Ghan, S., Kärcher, B., Koch, D., Kinne, S., Kondo, Y., Quinn, P. K., Sarofim, M. C., Schultz, M. G., Schulz, M., Venkataraman, C., Zhang, H., Zhang, S., Bellouin, N., Guttikunda, S. K., Hopke, P. K., Jacobson, M. Z., Kaiser, J. W., Klimont, Z., Lohmann, U., Schwarz, J. P., Shindell, D., Storelvmo, T., Warren, S. G. & Zender, C. S. 2013. Bounding the role of black carbon in the climate system: A scientific assessment. Journal of Geophysical Research: Atmospheres, 118, 5380-5552. Budisulistiorini, S. H., Riva, M., Williams, M., Chen, J., Itoh, M., Surratt, J. D. & Kuwata, M. 2017. Light-Absorbing Brown Carbon Aerosol Constituents from Combustion of Indonesian Peat and Biomass. Environmental Science & Technology, 51, 4415-4423. Cao, T., Li, M., Zou, C., Fan, X., Song, J., Jia, W., Yu, C., Yu, Z. & Peng, P. 2021. Chemical composition, optical properties, and oxidative potential of water- and methanol-soluble organic compounds emitted from the combustion of biomass materials and coal. Atmospheric Chemistry and Physics, 21, 13187-13205. Carslaw, D. C. & Ropkins, K. 2012. openair — An R package for air quality data analysis. Environmental Modelling & Software, 27-28, 52-61. Castro, L. M., Pio, C. A., Harrison, R. M. & Smith, D. J. T. 1999. Carbonaceous aerosol in urban and rural European atmospheres: estimation of secondary organic carbon concentrations. Atmospheric Environment, 33, 2771-2781. Cecinato, A., Guerriero, E., Balducci, C. & Muto, V. 2014. Use of the PAH fingerprints for identifying pollution sources. Urban Climate, 10, 630-643. Charron, A., Polo-Rehn, L., Besombes, J. L., Golly, B., Buisson, C., Chanut, H., Marchand, N., Guillaud, G. & Jaffrezo, J. L. 2019. Identification and quantification of particulate tracers of exhaust and non-exhaust vehicle emissions. Atmospheric Chemistry and Physics, 19, 5187-5207. Chen, L.-W. A., Chow, J. C., Wang, X., Cao, J., Mao, J. & Watson, J. G. 2021. Brownness of Organic Aerosol over the United States: Evidence for Seasonal Biomass Burning and Photobleaching Effects. Environmental Science & Technology, 55, 8561-8572. Chen, Y. & Bond, T. C. 2010. Light absorption by organic carbon from wood combustion. Atmospheric Chemistry and Physics, 10, 1773-1787. Chen, Y., Ge, X., Chen, H., Xie, X., Chen, Y., Wang, J., Ye, Z., Bao, M., Zhang, Y. & Chen, M. 2018. Seasonal light absorption properties of water-soluble brown carbon in atmospheric fine particles in Nanjing, China. Atmospheric Environment, 187, 230-240. Chen, Y., Xie, X., Shi, Z., Li, Y., Gai, X., Wang, J., Li, H., Wu, Y., Zhao, X., Chen, M. & Ge, X. 2020. Brown carbon in atmospheric fine particles in Yangzhou, China: Light absorption properties and source apportionment. Atmospheric Research, 244, 105028. Chen, Z.-W., Ting, Y.-C., Huang, C.-H. & Ciou, Z.-J. 2023. Sources-oriented contributions to ozone and secondary organic aerosol formation potential based on initial VOCs in an urban area of Eastern Asia. Science of The Total Environment, 892, 164392. Cheng, Y., Cao, X.-B., Liu, J.-M., Yu, Q.-Q., Zhang, Q. & He, K.-B. 2023. Agricultural fire impacts on brown carbon during different seasons in Northeast China. Science of The Total Environment, 891, 164390. Cheng, Y., Engling, G., He, K. B., Duan, F. K., Ma, Y. L., Du, Z. Y., Liu, J. M., Zheng, M. & Weber, R. J. 2013. Biomass burning contribution to Beijing aerosol. Atmospheric Chemistry and Physics, 13, 7765-7781. Cheng, Y., He, K.-B., Du, Z.-Y., Engling, G., Liu, J.-M., Ma, Y.-L., Zheng, M. & Weber, R. J. 2016. The characteristics of brown carbon aerosol during winter in Beijing. Atmospheric Environment, 127, 355-364. Cheng, Y., He, K. B., Zheng, M., Duan, F. K., Du, Z. Y., Ma, Y. L., Tan, J. H., Yang, F. M., Liu, J. M., Zhang, X. L., Weber, R. J., Bergin, M. H. & Russell, A. G. 2011. Mass absorption efficiency of elemental carbon and water-soluble organic carbon in Beijing, China. Atmospheric Chemistry and Physics, 11, 11497-11510. Cheng, Y., Li, S.-M. & Leithead, A. 2006. Chemical Characteristics and Origins of Nitrogen-Containing Organic Compounds in PM2.5 Aerosols in the Lower Fraser Valley. Environmental Science & Technology, 40, 5846-5852. Chow, J. C., Watson, J. G., Chen, L. W. A., Chang, M. C. O., Robinson, N. F., Trimble, D. & Kohl, S. 2007. The IMPROVE_A Temperature Protocol for Thermal/Optical Carbon Analysis: Maintaining Consistency with a Long-Term Database. Journal of the Air & Waste Management Association, 57, 1014-1023. Chung, C. E., Ramanathan, V. & Decremer, D. 2012. Observationally constrained estimates of carbonaceous aerosol radiative forcing. Proceedings of the National Academy of Sciences, 109, 11624. Contini, D., Vecchi, R. & Viana, M. 2018. Carbonaceous Aerosols in the Atmosphere. Atmosphere, 9, 181. Dührkop, K., Fleischauer, M., Ludwig, M., Aksenov, A. A., Melnik, A. V., Meusel, M., Dorrestein, P. C., Rousu, J. & Böcker, S. 2019. SIRIUS 4: a rapid tool for turning tandem mass spectra into metabolite structure information. Nature Methods, 16, 299-302. Drugé, T., Nabat, P., Mallet, M., Michou, M., Rémy, S. & Dubovik, O. 2022. Modeling radiative and climatic effects of brown carbon aerosols with the ARPEGE-Climat global climate model. Atmospheric Chemistry and Physics, 22, 12167-12205. Famiyeh, L., Chen, K., Xu, J., Sun, Y., Guo, Q., Wang, C., Lv, J., Tang, Y.-T., Yu, H., Snape, C. & He, J. 2021. A review on analysis methods, source identification, and cancer risk evaluation of atmospheric polycyclic aromatic hydrocarbons. Science of The Total Environment, 789, 147741. Feng, Y., Ramanathan, V. & Kotamarthi, V. R. 2013. Brown carbon: a significant atmospheric absorber of solar radiation? Atmospheric Chemistry and Physics, 13, 8607-8621. Fleming, L. T., Lin, P., Roberts, J. M., Selimovic, V., Yokelson, R., Laskin, J., Laskin, A. & Nizkorodov, S. A. 2020. Molecular composition and photochemical lifetimes of brown carbon chromophores in biomass burning organic aerosol. Atmospheric Chemistry and Physics, 20, 1105-1129. Guascito, M. R., Pietrogrande, M. C., Decesari, S. & Contini, D. 2021. Oxidative Potential of Atmospheric Aerosols. Atmosphere, 12, 531. Harrison, M. a. J., Barra, S., Borghesi, D., Vione, D., Arsene, C. & Iulian Olariu, R. 2005. Nitrated phenols in the atmosphere: a review. Atmospheric Environment, 39, 231-248. Harrison, R. M., Smith, D. J. T. & Luhana, L. 1996. Source Apportionment of Atmospheric Polycyclic Aromatic Hydrocarbons Collected from an Urban Location in Birmingham, U.K. Environmental Science & Technology, 30, 825-832. He, X., Huang, X. H. H., Chow, K. S., Wang, Q., Zhang, T., Wu, D. & Yu, J. Z. 2018. Abundance and Sources of Phthalic Acids, Benzene-Tricarboxylic Acids, and Phenolic Acids in PM2.5 at Urban and Suburban Sites in Southern China. ACS Earth and Space Chemistry, 2, 147-158. Hecobian, A., Zhang, X., Zheng, M., Frank, N., Edgerton, E. S. & Weber, R. J. 2010. Water-Soluble Organic Aerosol material and the light-absorption characteristics of aqueous extracts measured over the Southeastern United States. Atmospheric Chemistry and Physics, 10, 5965-5977. Huang, R.-J., Yang, L., Cao, J., Chen, Y., Chen, Q., Li, Y., Duan, J., Zhu, C., Dai, W., Wang, K., Lin, C., Ni, H., Corbin, J. C., Wu, Y., Zhang, R., Tie, X., Hoffmann, T., O’dowd, C. & Dusek, U. 2018. Brown Carbon Aerosol in Urban Xi’an, Northwest China: The Composition and Light Absorption Properties. Environmental Science & Technology, 52, 6825-6833. Huang, R.-J., Yang, L., Shen, J., Yuan, W., Gong, Y., Guo, J., Cao, W., Duan, J., Ni, H., Zhu, C., Dai, W., Li, Y., Chen, Y., Chen, Q., Wu, Y., Zhang, R., Dusek, U., O’dowd, C. & Hoffmann, T. 2020. Water-Insoluble Organics Dominate Brown Carbon in Wintertime Urban Aerosol of China: Chemical Characteristics and Optical Properties. Environmental Science & Technology, 54, 7836-7847. Hui, L., Liu, X., Tan, Q., Feng, M., An, J., Qu, Y., Zhang, Y. & Cheng, N. 2019. VOC characteristics, sources and contributions to SOA formation during haze events in Wuhan, Central China. Science of The Total Environment, 650, 2624-2639. Hung, W.-T., Lu, C.-H., Wang, S.-H., Chen, S.-P., Tsai, F. & Chou, C. C. K. 2019. Investigation of long-range transported PM2.5 events over Northern Taiwan during 2005–2015 winter seasons. Atmospheric Environment, 217, 116920. Iinuma, Y., Böge, O., Gräfe, R. & Herrmann, H. 2010. Methyl-Nitrocatechols: Atmospheric Tracer Compounds for Biomass Burning Secondary Organic Aerosols. Environmental Science & Technology, 44, 8453-8459. Ji, D., Gao, W., Maenhaut, W., He, J., Wang, Z., Li, J., Du, W., Wang, L., Sun, Y., Xin, J., Hu, B. & Wang, Y. 2019. Impact of air pollution control measures and regional transport on carbonaceous aerosols in fine particulate matter in urban Beijing, China: insights gained from long-term measurement. Atmospheric Chemistry and Physics, 19, 8569-8590. Jiang, H., Li, J., Chen, D., Tang, J., Cheng, Z., Mo, Y., Su, T., Tian, C., Jiang, B., Liao, Y. & Zhang, G. 2020. Biomass burning organic aerosols significantly influence the light absorption properties of polarity-dependent organic compounds in the Pearl River Delta Region, China. Environment International, 144, 106079. Kaul, D. S., Gupta, T., Tripathi, S. N., Tare, V. & Collett, J. L. 2011. Secondary Organic Aerosol: A Comparison between Foggy and Nonfoggy Days. Environmental Science & Technology, 45, 7307-7313. Kautzman, K. E., Surratt, J. D., Chan, M. N., Chan, A. W. H., Hersey, S. P., Chhabra, P. S., Dalleska, N. F., Wennberg, P. O., Flagan, R. C. & Seinfeld, J. H. 2010. Chemical Composition of Gas- and Aerosol-Phase Products from the Photooxidation of Naphthalene. The Journal of Physical Chemistry A, 114, 913-934. Keyte, I. J., Harrison, R. M. & Lammel, G. 2013. Chemical reactivity and long-range transport potential of polycyclic aromatic hydrocarbons – a review. Chemical Society Reviews, 42, 9333-9391. Kim, H., Kim, J. Y., Jin, H. C., Lee, J. Y. & Lee, S. P. 2016. Seasonal variations in the light-absorbing properties of water-soluble and insoluble organic aerosols in Seoul, Korea. Atmospheric Environment, 129, 234-242. Kirillova, E. N., Andersson, A., Tiwari, S., Srivastava, A. K., Bisht, D. S. & Gustafsson, ö. 2014. Water-soluble organic carbon aerosols during a full New Delhi winter: Isotope-based source apportionment and optical properties. Journal of Geophysical Research: Atmospheres, 119, 3476-3485. Koch, B. P. & Dittmar, T. 2006. From mass to structure: an aromaticity index for high-resolution mass data of natural organic matter. Rapid Communications in Mass Spectrometry, 20, 926-932. Kourtchev, I., Godoi, R. H. M., Connors, S., Levine, J. G., Archibald, A. T., Godoi, A. F. L., Paralovo, S. L., Barbosa, C. G. G., Souza, R. a. F., Manzi, A. O., Seco, R., Sjostedt, S., Park, J. H., Guenther, A., Kim, S., Smith, J., Martin, S. T. & Kalberer, M. 2016. Molecular composition of organic aerosols in central Amazonia: an ultra-high-resolution mass spectrometry study. Atmospheric Chemistry and Physics, 16, 11899-11913. Kroll, J. H., Donahue, N. M., Jimenez, J. L., Kessler, S. H., Canagaratna, M. R., Wilson, K. R., Altieri, K. E., Mazzoleni, L. R., Wozniak, A. S., Bluhm, H., Mysak, E. R., Smith, J. D., Kolb, C. E. & Worsnop, D. R. 2011. Carbon oxidation state as a metric for describing the chemistry of atmospheric organic aerosol. Nature Chemistry, 3, 133-139. Kumar, V., Kothiyal, N. C. & Saruchi 2014. Studies on carcinogenic PAHs emission generated by vehicles and its correlation to fuel and engine types. Polish Journal of Chemical Technology, 16, 48-58. Lack, D. A. & Cappa, C. D. 2010. Impact of brown and clear carbon on light absorption enhancement, single scatter albedo and absorption wavelength dependence of black carbon. Atmospheric Chemistry and Physics, 10, 4207-4220. Laskin, A., Laskin, J. & Nizkorodov, S. A. 2015. Chemistry of Atmospheric Brown Carbon. Chemical Reviews, 115, 4335-4382. Laskin, J., Laskin, A., Nizkorodov, S. A., Roach, P., Eckert, P., Gilles, M. K., Wang, B., Lee, H. J. & Hu, Q. 2014. Molecular Selectivity of Brown Carbon Chromophores. Environmental Science & Technology, 48, 12047-12055. Lei, Y., Shen, Z., Wang, Q., Zhang, T., Cao, J., Sun, J., Zhang, Q., Wang, L., Xu, H., Tian, J. & Wu, J. 2018. Optical characteristics and source apportionment of brown carbon in winter PM2.5 over Yulin in Northern China. Atmospheric Research, 213, 27-33. Levinson, R., Akbari, H. & Berdahl, P. 2010. Measuring solar reflectance—Part I: Defining a metric that accurately predicts solar heat gain. Solar Energy, 84, 1717-1744. Li, C., Chen, P., Kang, S., Yan, F., Hu, Z., Qu, B. & Sillanpää, M. 2016. Concentrations and light absorption characteristics of carbonaceous aerosol in PM2.5 and PM10 of Lhasa city, the Tibetan Plateau. Atmospheric Environment, 127, 340-346. Li, M., Fan, X., Zhu, M., Zou, C., Song, J., Wei, S., Jia, W. & Peng, P. A. 2019. Abundance and Light Absorption Properties of Brown Carbon Emitted from Residential Coal Combustion in China. Environmental Science & Technology, 53, 595-603. Li, X., Yang, Y., Liu, S., Zhao, Q., Wang, G. & Wang, Y. 2020. Light absorption properties of brown carbon (BrC) in autumn and winter in Beijing: Composition, formation and contribution of nitrated aromatic compounds. Atmospheric Environment, 223, 117289. Liao, H. T., Lee, C. L., Tsai, W. C., Yu, J. Z., Tsai, S. W., Chou, C. C. K. & Wu, C. F. 2021. Source apportionment of urban PM2.5 using positive matrix factorization with vertically distributed measurements of trace elements and nonpolar organic compounds. Atmospheric Pollution Research, 12, 200-207. Lin, C.-Y., Liu, S. C., Chou, C. C. K., Huang, S.-J., Liu, C.-M., Kuo, C.-H. & Young, C.-Y. 2005. Long-range transport of aerosols and their impact on the air quality of Taiwan. Atmospheric Environment, 39, 6066-6076. Lin, C. Y., Sheng, Y. F., Chen, W. C., Chou, C. C. K., Chien, Y. Y. & Chen, W. M. 2021. Air quality deterioration episode associated with a typhoon over the complex topographic environment in central Taiwan. Atmospheric Chemistry and Physics, 21, 16893-16910. Lin, P., Aiona, P. K., Li, Y., Shiraiwa, M., Laskin, J., Nizkorodov, S. A. & Laskin, A. 2016. Molecular Characterization of Brown Carbon in Biomass Burning Aerosol Particles. Environmental Science & Technology, 50, 11815-11824. Lin, P., Fleming, L. T., Nizkorodov, S. A., Laskin, J. & Laskin, A. 2018. Comprehensive Molecular Characterization of Atmospheric Brown Carbon by High Resolution Mass Spectrometry with Electrospray and Atmospheric Pressure Photoionization. Analytical Chemistry, 90, 12493-12502. Lin, P., Liu, J., Shilling, J. E., Kathmann, S. M., Laskin, J. & Laskin, A. 2015. Molecular characterization of brown carbon (BrC) chromophores in secondary organic aerosol generated from photo-oxidation of toluene. Physical Chemistry Chemical Physics, 17, 23312-23325. Lin, P., Yu, J. Z., Engling, G. & Kalberer, M. 2012. Organosulfates in Humic-like Substance Fraction Isolated from Aerosols at Seven Locations in East Asia: A Study by Ultra-High-Resolution Mass Spectrometry. Environmental Science & Technology, 46, 13118-13127. Lin, T., Zhou, W., Zhao, S., Li, M. & Guo, Z. 2023. Source contribution of PCBs and OC/EC at a background site in the Yangtze River Estuary: insight from inter-comparison by Positive Matrix Factorization (PMF). Carbon Research, 2, 15. Liu, J., Bergin, M., Guo, H., King, L., Kotra, N., Edgerton, E. & Weber, R. J. 2013. Size-resolved measurements of brown carbon in water and methanol extracts and estimates of their contribution to ambient fine-particle light absorption. Atmospheric Chemistry and Physics, 13, 12389-12404. Liu, J., Scheuer, E., Dibb, J., Diskin, G. S., Ziemba, L. D., Thornhill, K. L., Anderson, B. E., Wisthaler, A., Mikoviny, T., Devi, J. J., Bergin, M., Perring, A. E., Markovic, M. Z., Schwarz, J. P., Campuzano-Jost, P., Day, D. A., Jimenez, J. L. & Weber, R. J. 2015a. Brown carbon aerosol in the North American continental troposphere: sources, abundance, and radiative forcing. Atmospheric Chemistry and Physics, 15, 7841-7858. Liu, S., Aiken, A. C., Gorkowski, K., Dubey, M. K., Cappa, C. D., Williams, L. R., Herndon, S. C., Massoli, P., Fortner, E. C., Chhabra, P. S., Brooks, W. A., Onasch, T. B., Jayne, J. T., Worsnop, D. R., China, S., Sharma, N., Mazzoleni, C., Xu, L., Ng, N. L., Liu, D., Allan, J. D., Lee, J. D., Fleming, Z. L., Mohr, C., Zotter, P., Szidat, S. & Prévôt, A. S. H. 2015b. Enhanced light absorption by mixed source black and brown carbon particles in UK winter. Nature Communications, 6, 8435. Mao, J., Cheng, Y., Bai, Z., Zhang, W., Zhang, L., Chen, H., Wang, L., Li, L. & Chen, J. 2022. Molecular characterization of nitrogen-containing organic compounds in the winter North China Plain. Science of The Total Environment, 838, 156189. Mastral, A. M., CallÙn, M. S., GarcÝa, T. & Lopez, J. M. 2001. Benzo(a)pyrene, Benzo(a)anthracene, and Dibenzo(a,h)anthracene Emissions from Coal and Waste Tire Energy Generation at Atmospheric Fluidized Bed Combustion (AFBC). Environmental Science & Technology, 35, 2645-2649. Miao, Y., Che, H., Zhang, X. & Liu, S. 2021. Relationship between summertime concurring PM2.5 and O3 pollution and boundary layer height differs between Beijing and Shanghai, China. Environmental Pollution, 268, 115775. Mohr, C., Lopez-Hilfiker, F. D., Zotter, P., Prévôt, A. S. H., Xu, L., Ng, N. L., Herndon, S. C., Williams, L. R., Franklin, J. P., Zahniser, M. S., Worsnop, D. R., Knighton, W. B., Aiken, A. C., Gorkowski, K. J., Dubey, M. K., Allan, J. D. & Thornton, J. A. 2013. Contribution of Nitrated Phenols to Wood Burning Brown Carbon Light Absorption in Detling, United Kingdom during Winter Time. Environmental Science & Technology, 47, 6316-6324. Ni, H., Huang, R. J., Cao, J., Guo, J., Deng, H. & Dusek, U. 2019. Sources and formation of carbonaceous aerosols in Xi'an, China: primary emissions and secondary formation constrained by radiocarbon. Atmospheric Chemistry and Physics, 19, 15609-15628. Park, S., Yu, G.-H. & Lee, S. 2018. Optical absorption characteristics of brown carbon aerosols during the KORUS-AQ campaign at an urban site. Atmospheric Research, 203, 16-27. Park, S. S. & Cho, S. Y. 2011. Tracking sources and behaviors of water-soluble organic carbon in fine particulate matter measured at an urban site in Korea. Atmospheric Environment, 45, 60-72. Patel, N. & Ali, A. Chrysene: a carcinogen and its microbial degradation. 2014. Qi, L., Chen, M., Stefenelli, G., Pospisilova, V., Tong, Y., Bertrand, A., Hueglin, C., Ge, X., Baltensperger, U., Prévôt, A. S. H. & Slowik, J. G. 2019. Organic aerosol source apportionment in Zurich using an extractive electrospray ionization time-of-flight mass spectrometer (EESI-TOF-MS) – Part 2: Biomass burning influences in winter. Atmospheric Chemistry and Physics, 19, 8037-8062. Qi, M., Jiang, L., Liu, Y., Xiong, Q., Sun, C., Li, X., Zhao, W. & Yang, X. 2018. Analysis of the Characteristics and Sources of Carbonaceous Aerosols in PM2.5 in the Beijing, Tianjin, and Langfang Region, China. International journal of environmental research and public health, 15, 1483. Rana, A., Dey, S., Rawat, P., Mukherjee, A., Mao, J., Jia, S., Khillare, P. S., Yadav, A. K. & Sarkar, S. 2020. Optical properties of aerosol brown carbon (BrC) in the eastern Indo-Gangetic Plain. Science of The Total Environment, 716, 137102. Rhead, M. M. & Pemberton, R. D. 1996. Sources of Naphthalene in Diesel Exhaust Emissions. Energy & Fuels, 10, 837-843. Ruttkies, C., Schymanski, E. L., Wolf, S., Hollender, J. & Neumann, S. 2016. MetFrag relaunched: incorporating strategies beyond in silico fragmentation. Journal of Cheminformatics, 8, 3. Samburova, V., Connolly, J., Gyawali, M., Yatavelli, R. L. N., Watts, A. C., Chakrabarty, R. K., Zielinska, B., Moosmüller, H. & Khlystov, A. 2016. Polycyclic aromatic hydrocarbons in biomass-burning emissions and their contribution to light absorption and aerosol toxicity. Science of The Total Environment, 568, 391-401. Sarkar, C., Venkataraman, C., Yadav, S., Phuleria, H. C. & Chatterjee, A. 2019. Origin and properties of soluble brown carbon in freshly emitted and aged ambient aerosols over an urban site in India. Environmental Pollution, 254, 113077. Shakya, K. M., Ziemba, L. D. & Griffin, R. J. 2010. Characteristics and Sources of Carbonaceous, Ionic, and Isotopic Species of Wintertime Atmospheric Aerosols in Kathmandu Valley, Nepal. Aerosol and Air Quality Research, 10, 219-230. Shamjad, P. M., Tripathi, S. N., Pathak, R., Hallquist, M., Arola, A. & Bergin, M. H. 2015. Contribution of Brown Carbon to Direct Radiative Forcing over the Indo-Gangetic Plain. Environmental Science & Technology, 49, 10474-10481. Shen, Z., Zhang, Q., Cao, J., Zhang, L., Lei, Y., Huang, Y., Huang, R. J., Gao, J., Zhao, Z., Zhu, C., Yin, X., Zheng, C., Xu, H. & Liu, S. 2017. Optical properties and possible sources of brown carbon in PM2.5 over Xi'an, China. Atmospheric Environment, 150, 322-330. Simoneit, B. R. T., Medeiros, P. M. & Didyk, B. M. 2005. Combustion Products of Plastics as Indicators for Refuse Burning in the Atmosphere. Environmental Science & Technology, 39, 6961-6970. Simoneit, B. R. T., Rushdi, A. I., Bin Abas, M. R. & Didyk, B. M. 2003. Alkyl Amides and Nitriles as Novel Tracers for Biomass Burning. Environmental Science & Technology, 37, 16-21. Singh, G., Jakhar, R., Raj, R. K. & Sachar, D. P. 2022. A Comprehensive Study on Impacts of Air Pollution on Environment and Human Health. International Journal of Recent Technology and Engineering (IJRTE), 11. Singh, S. & Gokhale, S. 2021. Source apportionment and light absorption properties of black and brown carbon aerosols in the Brahmaputra River valley region. Urban Climate, 39, 100963. Slade, J. H., Ault, A. P., Bui, A. T., Ditto, J. C., Lei, Z., Bondy, A. L., Olson, N. E., Cook, R. D., Desrochers, S. J., Harvey, R. M., Erickson, M. H., Wallace, H. W., Alvarez, S. L., Flynn, J. H., Boor, B. E., Petrucci, G. A., Gentner, D. R., Griffin, R. J. & Shepson, P. B. 2019. Bouncier Particles at Night: Biogenic Secondary Organic Aerosol Chemistry and Sulfate Drive Diel Variations in the Aerosol Phase in a Mixed Forest. Environmental Science & Technology, 53, 4977-4987. Soleimanian, E., Mousavi, A., Taghvaee, S., Shafer, M. M. & Sioutas, C. 2020. Impact of secondary and primary particulate matter (PM) sources on the enhanced light absorption by brown carbon (BrC) particles in central Los Angeles. Science of The Total Environment, 705, 135902. Srinivas, B. & Sarin, M. M. 2013. Light absorbing organic aerosols (brown carbon) over the tropical Indian Ocean: impact of biomass burning emissions. Environmental Research Letters, 8, 044042. Srinivas, B. & Sarin, M. M. 2014. Brown carbon in atmospheric outflow from the Indo-Gangetic Plain: Mass absorption efficiency and temporal variability. Atmospheric Environment, 89, 835-843. Sun, J., Xie, C., Xu, W., Chen, C., Ma, N., Xu, W., Lei, L., Li, Z., He, Y., Qiu, Y., Wang, Q., Pan, X., Su, H., Cheng, Y., Wu, C., Fu, P., Wang, Z. & Sun, Y. 2021. Light absorption of black carbon and brown carbon in winter in North China Plain: comparisons between urban and rural sites. Science of The Total Environment, 770, 144821. Szopa, S., Naik, V., Adhikary, B., Artaxo, P., Berntsen, T., Collins, W. D., Fuzzi, S., Gallardo, L., Kiendler-Scharr, A., Klimont, Z., Liao, H., Unger, N. & Zanis, P. 2021. 2021: Short-Lived Climate Forcers. In: Masson-Delmotte, V., Zhai, P., Pirani, A., Connors, S. L., Péan, C., Berger, S., Caud, N., Chen, Y., Goldfarb, L., Gomis, M. I., Huang, M., Leitzell, K., Lonnoy, E., Matthews, J. B. R., Maycock, T. K., Waterfield, T., Yelekçi, O., Yu, R. & Zhou, B. (eds.) In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA. Takasuga, T., Makino, T., Umetsu, N. & Senthilkumar, K. 2003. Quantitative analysis of toxic compounds formed from combustion of some plastic materials and newspaper. Organohalogen compounds, 63, 86-89. Tang, J., Li, J., Su, T., Han, Y., Mo, Y., Jiang, H., Cui, M., Jiang, B., Chen, Y., Tang, J., Song, J., Peng, P. & Zhang, G. 2020. Molecular compositions and optical properties of dissolved brown carbon in biomass burning, coal combustion, and vehicle emission aerosols illuminated by excitation–emission matrix spectroscopy and Fourier transform ion cyclotron resonance mass spectrometry analysis. Atmospheric Chemistry and Physics, 20, 2513-2532. TEPA 2021. Taiwan Emission Data System (TEDS) 11.1. Taiwan Environmental Protection Administration. Thurston, G. D., Ito, K. & Lall, R. 2011. A source apportionment of U.S. fine particulate matter air pollution. Atmospheric Environment, 45, 3924-3936. Tsai, I. C., Lee, C.-Y., Lung, S.-C. C. & Su, C.-W. 2021. Characterization of the vehicle emissions in the Greater Taipei Area through vision-based traffic analysis system and its impacts on urban air quality. Science of The Total Environment, 782, 146571. Tu, P., Hall, W. a. I. V. & Johnston, M. V. 2016. Characterization of Highly Oxidized Molecules in Fresh and Aged Biogenic Secondary Organic Aerosol. Analytical Chemistry, 88, 4495-4501. Uria-Tellaetxe, I. & Carslaw, D. C. 2014. Conditional bivariate probability function for source identification. Environmental Modelling & Software, 59, 1-9. Viidanoja, J., Sillanpää, M., Laakia, J., Kerminen, V.-M., Hillamo, R., Aarnio, P. & Koskentalo, T. 2002. Organic and black carbon in PM2.5 and PM10: 1 year of data from an urban site in Helsinki, Finland. Atmospheric Environment, 36, 3183-3193. Wang, G., Cheng, S., Li, J., Lang, J., Wen, W., Yang, X. & Tian, L. 2015. Source apportionment and seasonal variation of PM2.5 carbonaceous aerosol in the Beijing-Tianjin-Hebei Region of China. Environmental Monitoring and Assessment, 187, 143. Wang, L., Arey, J. & Atkinson, R. 2006. Kinetics and Products of Photolysis and Reaction with OH Radicals of a Series of Aromatic Carbonyl Compounds. Environmental Science & Technology, 40, 5465-5471. Wang, Q., Ye, J., Wang, Y., Zhang, T., Ran, W., Wu, Y., Tian, J., Li, L., Zhou, Y., Hang Ho, S. S., Dang, B., Zhang, Q., Zhang, R., Chen, Y., Zhu, C. & Cao, J. 2019. Wintertime Optical Properties of Primary and Secondary Brown Carbon at a Regional Site in the North China Plain. Environmental Science & Technology, 53, 12389-12397. Wang, Q., Zhou, Y., Ma, N., Zhu, Y., Zhao, X., Zhu, S., Tao, J., Hong, J., Wu, W., Cheng, Y. & Su, H. 2022. Review of Brown Carbon Aerosols in China: Pollution Level, Optical Properties, and Emissions. Journal of Geophysical Research: Atmospheres, 127, e2021JD035473. Wang, W., Zhang, Y., Jiang, B., Chen, Y., Song, Y., Tang, Y., Dong, C. & Cai, Z. 2021. Molecular characterization of organic aerosols in Taiyuan, China: Seasonal variation and source identification. Science of The Total Environment, 800, 149419. Wang, X., Hayeck, N., Brüggemann, M., Abis, L., Riva, M., Lu, Y., Wang, B., Chen, J., George, C. & Wang, L. 2020a. Chemical Characteristics and Brown Carbon Chromophores of Atmospheric Organic Aerosols Over the Yangtze River Channel: A Cruise Campaign. Journal of Geophysical Research: Atmospheres, 125, e2020JD032497. Wang, X., Hayeck, N., Brüggemann, M., Yao, L., Chen, H., Zhang, C., Emmelin, C., Chen, J., George, C. & Wang, L. 2017. Chemical Characteristics of Organic Aerosols in Shanghai: A Study by Ultrahigh-Performance Liquid Chromatography Coupled With Orbitrap Mass Spectrometry. Journal of Geophysical Research: Atmospheres, 122, 11,703-11,722. Wang, X., Heald, C. L., Ridley, D. A., Schwarz, J. P., Spackman, J. R., Perring, A. E., Coe, H., Liu, D. & Clarke, A. D. 2014. Exploiting simultaneous observational constraints on mass and absorption to estimate the global direct radiative forcing of black carbon and brown carbon. Atmospheric Chemistry and Physics, 14, 10989-11010. Wang, Y., Chen, Y., Wu, Z., Shang, D., Bian, Y., Du, Z., Schmitt, S. H., Su, R., Gkatzelis, G. I., Schlag, P., Hohaus, T., Voliotis, A., Lu, K., Zeng, L., Zhao, C., Alfarra, M. R., Mcfiggans, G., Wiedensohler, A., Kiendler-Scharr, A., Zhang, Y. & Hu, M. 2020b. Mutual promotion between aerosol particle liquid water and particulate nitrate enhancement leads to severe nitrate-dominated particulate matter pollution and low visibility. Atmospheric Chemistry and Physics, 20, 2161-2175. Wu, G., Ram, K., Fu, P., Wang, W., Zhang, Y., Liu, X., Stone, E. A., Pradhan, B. B., Dangol, P. M., Panday, A. K., Wan, X., Bai, Z., Kang, S., Zhang, Q. & Cong, Z. 2019. Water-Soluble Brown Carbon in Atmospheric Aerosols from Godavari (Nepal), a Regional Representative of South Asia. Environmental Science & Technology, 53, 3471-3479. Wu, G., Wan, X., Gao, S., Fu, P., Yin, Y., Li, G., Zhang, G., Kang, S., Ram, K. & Cong, Z. 2018. Humic-Like Substances (HULIS) in Aerosols of Central Tibetan Plateau (Nam Co, 4730 m asl): Abundance, Light Absorption Properties, and Sources. Environmental Science & Technology, 52, 7203-7211. Xie, M., Chen, X., Hays, M. D., Lewandowski, M., Offenberg, J., Kleindienst, T. E. & Holder, A. L. 2017a. Light Absorption of Secondary Organic Aerosol: Composition and Contribution of Nitroaromatic Compounds. Environmental Science & Technology, 51, 11607-11616. Xie, M., Hays, M. D. & Holder, A. L. 2017b. Light-absorbing organic carbon from prescribed and laboratory biomass burning and gasoline vehicle emissions. Scientific Reports, 7, 7318. Xie, M., Zhao, Z., Holder, A. L., Hays, M. D., Chen, X., Shen, G., Jetter, J. J., Champion, W. M. & Wang, Q. 2020. Chemical composition, structures, and light absorption of N-containing aromatic compounds emitted from burning wood and charcoal in household cookstoves. Atmospheric Chemistry and Physics, 20, 14077-14090. Yan, C., Zheng, M., Bosch, C., Andersson, A., Desyaterik, Y., Sullivan, A. P., Collett, J. L., Zhao, B., Wang, S., He, K. & Gustafsson, ö. 2017. Important fossil source contribution to brown carbon in Beijing during winter. Scientific Reports, 7, 43182. Yan, C., Zheng, M., Sullivan, A. P., Bosch, C., Desyaterik, Y., Andersson, A., Li, X., Guo, X., Zhou, T., Gustafsson, ö. & Collett, J. L. 2015. Chemical characteristics and light-absorbing property of water-soluble organic carbon in Beijing: Biomass burning contributions. Atmospheric Environment, 121, 4-12. Yan, J., Wang, X., Gong, P., Wang, C. & Cong, Z. 2018. Review of brown carbon aerosols: Recent progress and perspectives. Science of The Total Environment, 634, 1475-1485. Yang, J., Au, W. C., Law, H., Lam, C. H. & Nah, T. 2021. Formation and evolution of brown carbon during aqueous-phase nitrate-mediated photooxidation of guaiacol and 5-nitroguaiacol. Atmospheric Environment, 254, 118401. Yang, J., Xu, W. & Cheng, H. 2018. Seasonal Variations and Sources of Airborne Polycyclic Aromatic Hydrocarbons (PAHs) in Chengdu, China. Atmosphere, 9. Yassine, M. M., Harir, M., Dabek-Zlotorzynska, E. & Schmitt-Kopplin, P. 2014. Structural characterization of organic aerosol using Fourier transform ion cyclotron resonance mass spectrometry: Aromaticity equivalent approach. Rapid Communications in Mass Spectrometry, 28, 2445-2454. Zhang, C., Liu, X., Zhang, Y., Tan, Q., Feng, M., Qu, Y., An, J., Deng, Y., Zhai, R., Wang, Z., Cheng, N. & Zha, S. 2021. Characteristics, source apportionment and chemical conversions of VOCs based on a comprehensive summer observation experiment in Beijing. Atmospheric Pollution Research, 12, 230-241. Zhang, L., Hu, B., Liu, X., Luo, Z., Xing, R., Li, Y., Xiong, R., Li, G., Cheng, H., Lu, Q., Shen, G. & Tao, S. 2022a. Variabilities in Primary N-Containing Aromatic Compound Emissions from Residential Solid Fuel Combustion and Implications for Source Tracers. Environmental Science & Technology, 56, 13622-13633. Zhang, L., Son, J. H., Bai, Z., Zhang, W., Li, L., Wang, L. & Chen, J. 2022b. Characterizing Atmospheric Brown Carbon and Its Emission Sources during Wintertime in Shanghai, China. Atmosphere, 13. Zhang, T., Shen, Z., Zhang, L., Tang, Z., Zhang, Q., Chen, Q., Lei, Y., Zeng, Y., Xu, H. & Cao, J. 2020a. PM2.5 Humic-like substances over Xi'an, China: Optical properties, chemical functional group, and source identification. Atmospheric Research, 234, 104784. Zhang, X., Li, Z., Wang, F., Song, M., Zhou, X. & Ming, J. 2020b. Carbonaceous Aerosols in PM1, PM2.5, and PM10 Size Fractions over the Lanzhou City, Northwest China. Atmosphere, 11, 1368. Zhang, X., Lin, Y.-H., Surratt, J. D. & Weber, R. J. 2013. Sources, Composition and Absorption Ångström Exponent of Light-absorbing Organic Components in Aerosol Extracts from the Los Angeles Basin. Environmental Science & Technology, 47, 3685-3693. Zhao, R., Zhang, Q., Xu, X., Wang, W., Zhao, W., Zhang, W. & Zhang, Y. 2022. Light absorption properties and molecular compositions of water-soluble and methanol-soluble organic carbon emitted from wood pyrolysis and combustion. Science of The Total Environment, 809, 151136. Zhou, Y., West, C. P., Hettiyadura, A. P. S., Pu, W., Shi, T., Niu, X., Wen, H., Cui, J., Wang, X. & Laskin, A. 2022. Molecular Characterization of Water-Soluble Brown Carbon Chromophores in Snowpack from Northern Xinjiang, China. Environmental Science & Technology, 56, 4173-4186. Zhu, C.-S., Li, L.-J., Huang, H., Dai, W.-T., Lei, Y.-L., Qu, Y., Huang, R.-J., Wang, Q.-Y., Shen, Z.-X. & Cao, J.-J. 2020. n-Alkanes and PAHs in the Southeastern Tibetan Plateau: Characteristics and Correlations With Brown Carbon Light Absorption. Journal of Geophysical Research: Atmospheres, 125, e2020JD032666. Zhu, C.-S., Qu, Y., Huang, H., Chen, J., Dai, W.-T., Huang, R.-J. & Cao, J.-J. 2021. Black Carbon and Secondary Brown Carbon, the Dominant Light Absorption and Direct Radiative Forcing Contributors of the Atmospheric Aerosols Over the Tibetan Plateau. Geophysical Research Letters, 48, e2021GL092524. | - |
| dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/90482 | - |
| dc.description.abstract | 近年來褐碳(BrC)因其對空氣品質、氣候變遷及人體健康皆有重大影響而逐漸受到全世界的關注,然而其光學特性、化學組成及來源卻相當複雜,且會隨著時間與空間變化,進而貢獻不同的輻射吸收程度,因此本研究旨在探討BrC之光學特性、發色團組成、潛在來源及其對輻射吸收的貢獻。本研究於臺北都會區採集2021年1月到11月之細懸浮微粒(PM2.5),除了分析其化學組成外,亦量化了分別由水及甲醇萃取出的溶解性有機碳(WSOC和MSOC)之光學特性,此外亦藉由高效能液相層析串聯高解析質譜儀(HPLC-DAD-HRMS)來分析MSOC樣品中的BrC發色團。
根據本研究的結果不僅發現MSOC的光吸收高於WSOC,兩者之光學特性的季節變化亦呈現不同趨勢。WSOC之年質量吸收效率為0.33–1.43 m2 g-1,其中以冬季最大,夏季最小;MSOC則為0.26–1.50 m2 g-1,其中以春季最大和秋季最小;而WSOC和MSOC的年平均吸光埃指數分別為6.05 ± 0.56和5.27 ± 0.59。此兩種萃取物在近紫外光波長範圍內相對於元素碳貢獻的太陽輻射高於在整個太陽光譜範圍內的貢獻,說明了BrC在近紫外光波長處輻射吸收的重要性。本研究亦發現BrC可能源於化石燃料燃燒之交通排放及附近火化場的生質燃燒。此外,已鑑定出的BrC發色團呈現出季節性(冬季、夏季)和事件日與非事件日之間的差異,在冬季及夏季樣品中鑑定出的發色團中包括CHO、CHON及CHOS化合物,其中鑑定出與交通排放、生質燃燒或二次形成有關的苯二甲酸、硝基芳香族化合物、多環芳香烴以及與船隻引擎尾氣排放有關的CHOS化合物;而硝基芳香族化合物和多環芳香烴皆對光吸收有重要之貢獻,其中又以硝基酚類化合物在波長366奈米處的貢獻最為顯著,亦顯示出硝基酚類化合物在BrC光吸收中扮演的重要角色。此外,本研究中鑑定出的多環芳香烴大多以芘為核心結構;而脂肪族化合物則在冬季非事件日與夏季中較常出現。總而言之,本研究的結果揭示臺灣之BrC對當地和區域之空氣品質及氣候有舉足輕重的影響,因此其重要性不容小覷。 | zh_TW |
| dc.description.abstract | Brown carbon (BrC) has been of major concern worldwide due to its significant impact on air quality, climate change and human health. However, the optical properties, chemical constituents and sources of BrC are certainly complex and would change with the variability of spatial and temporal characteristics, leading to different contributions to radiative forcing. Therefore, this study aims to comprehensively investigate the optical properties, chemical constituents and potential sources of BrC. In this study, daily PM2.5 samples were collected from January to November 2021 in the Taipei metropolitan area. The chemical compositions of PM2.5 and optical properties of water-soluble and methanol-soluble organic carbon (WSOC and MSOC) were evaluated and quantified. The BrC chromophores of MSOC were further identified using a high-performance liquid chromatography-diode array detector-electrospray ionization high-resolution mass spectrometer (HPLC-DAD-HRMS) platform.
The results showed that the light absorption of MSOC was higher than that of WSOC, while the seasonal variations of the optical properties of WSOC and MSOC were also observed. The annual mass absorption efficiency of WSOC ranged from 0.33 to 1.43 m2 g-1, with the highest value in winter and lowest value in summer, whereas that of MSOC was 0.26–1.50 m2 g-1, with the highest value in spring and lowest value in autumn. The annual average of absorption Ångström exponent of WSOC and MSOC was 6.05 ± 0.56 and 5.27 ± 0.59, respectively. The estimated fractional contributions of radiative forcing of both extracts relative to elemental carbon in the near ultraviolet wavelength (UV) ranges were higher than those in the whole range of the solar spectrum. This suggested the importance of the light absorption of BrC at the near UV wavelengths. The sources of BrC were identified as traffic emissions and biomass burning from adjacent crematoria. In addition, the identified BrC chromophores exhibited the differences between non-polluted winter and summer, as well as non-polluted winter and polluted winter. The compounds identified in both winter and summer included CHO, CHON and CHOS compounds. Phthalic acids (C8H6O4), nitroaromatic compounds (NACs) and polycyclic aromatic hydrocarbons (PAHs) were identified and associated with vehicle emissions and/or biomass burning or secondary formation, while the identified CHOS compounds were pointed out to be generated from ship engine exhaust emissions. NACs and PAHs were observed to significantly contribute to light absorption, especially the light absorption of nitrophenolic compounds (NPs) at the wavelength of 366 nm, highlighting the significant role of these NPs in near UV wavelengths. The light absorption of the compounds identified in winter was most significant at the wavelength of 365 nm, while that in summer was at 300–350 nm. Moreover, the condensed aromatic compounds identified in this study were mostly classified as pyrene core structures. The presence of aliphatic compounds was prevalent during non-polluted winter and summer periods. To sum up, the findings in this study highlight that the significant impact of BrC in Taiwan on local and regional air quality as well as the climate should not be ignored, and need to be further investigated. | en |
| dc.description.provenance | Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-10-03T16:17:04Z No. of bitstreams: 0 | en |
| dc.description.provenance | Made available in DSpace on 2023-10-03T16:17:04Z (GMT). No. of bitstreams: 0 | en |
| dc.description.tableofcontents | 口試委員會審定書 I
誌謝 II 摘要 III Abstract IV Content VI List of figures VIII List of tables X Chapter 1 Introduction 1 1.1 Fine particulate matter and carbonaceous aerosols 1 1.2 Optical properties of BrC 2 1.3 Chemical constituents of BrC 4 1.4 Motivation and objectives 6 Chapter 2 Method 8 2.1 Sampling 9 2.2 Extraction 10 2.3 Optical properties analysis 10 2.4 Chemical compositions analysis 11 2.5 HPLC-DAD-HRMS 12 2.6 Data analysis 13 2.6.1 EC-tracer method 13 2.6.2 Radiative forcing of BrC relative to EC 13 2.6.3 Conditional bivariate probability function 14 2.6.4 Species identification 14 2.6.5 Statistical analysis 16 2.6.6 Molecular characteristic analysis 17 Chapter 3 Results and Discussion 18 3.1 PM2.5 and its chemical compositions 18 3.2 Optical properties of BrC 21 3.3 Potential sources of BrC 27 3.4 Chemical characteristics of BrC chromophores 30 3.4.1 Tentative BrC chromophores 31 3.4.2 Relative contribution to total light absorption of BrC chromophores 41 3.4.3 Tentative BrC chromophores in polluted winter samples 44 3.4.4 Molecular characterization of identified compounds 48 Chapter 4 Conclusion and Recommendation 51 4.1 Conclusion 51 4.2 Future remarks and recommendation 53 References 54 Supplemental information 66 | - |
| dc.language.iso | en | - |
| dc.subject | 硝基芳香族化合物 | zh_TW |
| dc.subject | 褐碳 | zh_TW |
| dc.subject | 細懸浮微粒 | zh_TW |
| dc.subject | 來源解析 | zh_TW |
| dc.subject | 發色團 | zh_TW |
| dc.subject | 多環芳香烴 | zh_TW |
| dc.subject | 光學特性 | zh_TW |
| dc.subject | PM2.5 | en |
| dc.subject | NACs | en |
| dc.subject | PAHs | en |
| dc.subject | chromophore | en |
| dc.subject | source identification | en |
| dc.subject | optical properties | en |
| dc.subject | brown carbon | en |
| dc.title | 臺北都會區褐碳之光學特性、物種解析與潛在來源之探討 | zh_TW |
| dc.title | Optical properties, chemical constituents and potential sources of brown carbon in Taipei urban area | en |
| dc.type | Thesis | - |
| dc.date.schoolyear | 111-2 | - |
| dc.description.degree | 碩士 | - |
| dc.contributor.oralexamcommittee | 蔡瀛逸;趙浩然;程裕祥 | zh_TW |
| dc.contributor.oralexamcommittee | Ying-I Tsai;How-ran Chao;Yu-Hsiang Cheng | en |
| dc.subject.keyword | 細懸浮微粒,褐碳,光學特性,來源解析,發色團,多環芳香烴,硝基芳香族化合物, | zh_TW |
| dc.subject.keyword | PM2.5,brown carbon,optical properties,source identification,chromophore,PAHs,NACs, | en |
| dc.relation.page | 89 | - |
| dc.identifier.doi | 10.6342/NTU202302155 | - |
| dc.rights.note | 同意授權(全球公開) | - |
| dc.date.accepted | 2023-08-07 | - |
| dc.contributor.author-college | 工學院 | - |
| dc.contributor.author-dept | 環境工程學研究所 | - |
| dc.date.embargo-lift | 2028-07-31 | - |
| Appears in Collections: | 環境工程學研究所 | |
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|---|---|---|---|
| ntu-111-2.pdf Until 2028-07-31 | 4.27 MB | Adobe PDF |
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