臺灣博碩士論文加值系統

台灣中部都會與沿海地區最近幾年發生高污染事件仍以PM10為主要污染物，因此本研究的目的在於探討此地區PM2.5及PM2.5-10氣膠化學組成及污染源的貢獻量，都會及沿海地區的測站分別選擇台中市崇倫國中與梧棲鎮梧棲國小作為代表測站，當地的氣象觀測站與空氣品質監測站均鄰近此兩測站，實驗方面利用雙粒徑分道採樣器採集PM2.5及PM2.5-10氣膠微粒，並利用離子層析儀、元素分析儀與感應耦合電漿光譜分析儀分析其化學組成，主要採樣時間為1998年8月至1999年3月，都會測站共採集110組大氣氣膠樣本，而沿海地區則有92組。數據分析方面則利用主成份因子分析法與化學質量平衡法(CMB7)作為PM2.5及PM2.5-10氣膠微粒的污染源定性與定量之工具，同時應用貝氏模式、質量重組及高斯傳遞係數軌跡模式模擬案例。
依據PCA與CMB7模式分析中部都會與沿海地區之PM2.5及PM2.5-10氣膠微粒之結果，兩地區PM2.5及PM2.5-10氣膠微粒之污染源趨勢相當類似，PM2.5氣膠微粒之污染源以交通排放與二次氣膠為主，都會地區來自交通排放約佔34.1~84.8 %，沿海地區則約42.7~69.3 %來自交通排放，都會地區二次氣膠約佔17.8~28.4 %，沿海地區則介於18.1~25.9 %之間。而PM2.5-10氣膠微粒之污染源則以地殼物質與交通排放所佔比例較高，特別是都會地區中來自地殼物質約佔51.9~76.7 %，沿海地區則約24.0~74.8 %來自地殼物質。
結合兩氣膠粒徑數據，其中交通排放為都會區PM10氣膠微粒中最重要的污染源，其次分別為地殼物質、二次氣膠、農廢燃燒、工業排放及海鹽飛沫，而沿海地區除了海鹽飛沫的貢獻被發現較都會地區顯著外，亦有相同之污染源趨勢，研究發現兩地區之交通排放雖為第一大污染源，但高污染事件日發生時，農廢燃燒與二次氣膠為造成PM10濃度增加的主要來源，這些高污染事件日都會地區通常發生在秋季與冬季，而在沿海地區則只有可能發生在春季。
利用CMB7模式分析之個別污染源貢獻量散佈於貝氏模式所推估的5~ 95 %區間內，但適當的污染源選擇與足夠的大氣樣本往往可影響其結果，比較CMB7模式與其他模式之分析結果，CMB7模式分析之個別污染源貢獻量與質量再重組法(MRC)比較接近，而利用CMB7與GTx模式分析個別污染源貢獻量之差距較為顯著，特別是硫酸銨與硝酸銨，然而，研究發現PM2.5氣膠微粒兩者之解析有良好的關係，並以秋冬季節的數據解析結果之相關性較佳，GTx模式之優點是可提供受體點反軌跡途徑之污染貢獻量，其軌跡有助於解釋其影響的污染源。

PM10 was still the major pollutant during episodic events occurred in Taichung urban and coastal areas in recent years. Therefore the purpose of this study was to investigate the chemical compositions and the source contributions for PM2.5 and PM2.5-10 in these areas. In this study, Chunglun junior high school and Wuchi elementary school were chosen as the representative sites for Taichung urban and coastal areas, respectively. Weather service office and air quality monitoring stations were nearby the selected sites. Experimentally, dichotomous samplers were used to collect PM2.5 and PM2.5-10 aerosols, and the chemical compositions were analyzed by using ion chromatograph (IC), elemental analyzer (EA) and inductively coupled plasma mass spectrometry (ICP-MS). Totally 110 urban samples and 92 coastal samples were collected from August 1998 to March 1999. Principal component analysis (PCA) with varimax rotation and a chemical mass balance model version 7 (CMB7) were used to qualify and quantify, respectively, the source contributions to PM2.5 and PM2.5-10. In addition, Bayesian model, Mass Reconstruction (MRC) and Gaussian Trajectory transfer-coefficient modeling system (GTx) were also applied to analyze the special cases in this study.
The results obtained by using the PCA and the CMB modeling showed a similar pattern on the source contributions to PM2.5 and PM2.5-10 for both areas. Vehicle emissions and secondary aerosols were the major sources for PM2.5. Quantitatively, vehicle emissions accounted for 34.1 % to 84.8 % of the urban PM2.5 and 42.7 % to 69.3 % for the coastal PM2.5. There were 17.8 % to 28.4 % of PM2.5 contributed from secondary aerosols in urban area, while the secondary aerosols contributed 18.1 % to 25.9 % of the coastal PM2.5. However, crustal materials and vehicle emissions were the major sources for PM2.5-10. Especially the crustal materials contributed 51.9 % to 76.7 % of the urban PM2.5-10 and 24.0 % to 74.8 % of the coastal PM2.5-10.
In conclusion, vehicle emissions, crustal materials, secondary aerosols, vegetative burning, industry emissions and marine spray were the sources for PM10 in sequence in the urban area. The similar pattern was also observed in the coastal area, except the marine spray was found more significantly than that in the urban area. The contribution emitted from vehicle emission was indeed the most significant source during the episodic periods. But based on the increments of the contributory percentage, the vegetative burning and secondary aerosols were the influential sources causing the elevated PM10 at both sites during episodic periods. These episodic events always occurred in fall and winter in the urban area, but they could only happen in spring in the coastal area.
The contributions from each source calculated by using CMB7 model ranged from 5% to 95 % of those estimated by using Bayesian model. However, the validity of the source compositions and the sufficient aerosol samples were the limitations for using Bayesian model. Intercomparison of these results showed a better agreement between the estimations by using CMB7 and MRC. Although, there were differences of the individual source contributions in PM10 obtained by CMB7 and GTx models, especially for the contributions of ammonium sulfate and nitrate, however they were well correlated for the data obtained in fall and winter. Furthermore, the advantages of using GTx model could provide the backward trajectory from the receptor and the information of the major pollution sources.

摘要 I
Abstract III
目錄
圖目錄
表目錄
第一章 前言
1.1 研究緣起與目的
1.2 研究架構與內容
第二章 文獻回顧
2.1 中部都會與沿海地區之特性
2.1.1 中部都會與沿海地區之人文特性
2.1.2 中部都會與沿海地區之氣象特性
2.1.3 中部都會與沿海地區之污染排放特性
2.1.4 中部都會與沿海地區之氣膠特性
2.2 受體模式之研究發展及相關應用
2.2.1 國外之研究與應用
2.2.2 國內之研究與應用
第三章 研究方法
3.1 採樣與分析實驗
3.1.1 採樣地點選定
3.1.2 採樣時間
3.1.3 採樣儀器及採樣濾紙
3.1.4 大氣氣膠成分分析
3.2 數據處理與污染源定性分析方法
3.2.1 數據標準化處理
3.2.2 主成分因子求取
3.2.3 因子轉軸
3.2.4 因子共通性求取
3.3 污染源定量分析方法
3.3.1 化學質量平衡模式
3.3.2 貝氏模式
3.3.3 質量再重組方法
3.4 污染源成因分析方法
3.4.1 高斯傳遞係數模式
3.4.2 HYSPLIT模式
3.5 污染源排放組成資料庫蒐集建立
3.5.1 污染源排放組成蒐集
3.5.2 污染源之分類與採樣方法
3.5.3 污染源資料庫建立方法
第四章 結果與討論
4.1 大氣氣膠質量濃度與粒徑分析
4.1.1 氣膠質量濃度
4.1.2 氣膠粒徑分析
4.2 大氣氣膠成份分析
4.2.1 不同空氣品質狀態之氣膠微粒成份組成
4.2.2 氣膠微粒四季之差異比較
4.2.3 氣膠微粒日夜間之差異比較
4.3 污染源定性分析
4.3.1 污染物相關分析
4.3.2主成分因子分析
4.4 污染源定量分析
4.4.1 大氣樣品選擇與說明
4.4.2 污染源指紋資料選擇與說明
4.4.3 化學質量平衡受體模式分析
4.5 案例污染成因分析
4.5.1 貝氏模式之應用
4.5.2 質量再重組及高斯傳遞係數模式之應用
4.5.3 氣團逆推軌跡之應用
4.5.4 小結
第五章 結論與建議
5.1 結論
5.1.1 大氣氣膠特性與時空變異
5.1.2 大氣氣膠污染來源與成因分析
5.1.3 主要貢獻
5.2 建議
參考文獻
附錄A 採樣數據品保品管資料
附錄B 受體模式所使用之污染源指紋資料數據
附錄C 受體模式逐筆分析資料

Anttila, P., Paatero, P., Tapper, U. and Jarvinen, O., “Source Identification of Bulk Wet Deposition in Finland by Positive Matrix Factorization”, Atmospheric Environment, Vol. 29, No. 14, pp. 1705-1718 (1995).
Barker, D. R. and Diana, L. M., “Simple Method for Fitting Data When Both Variables Have Uncertainties”, The American Journal of Physics, Vol. 42, pp. 224-226 (1974).
Brook, J. R., Dann, T. F. and Burnett, R. T., “The Relationship Among TSP, PM10, PM2.5, and Inorganic Constituents of Atmospheric Particulate Matter at Multiple Canadian Locations”, Journal of the Air & Waste Management Association, Vol. 47, pp. 2-19 (1997).
Cadle, S. H. and Groblicki, P. J., “An Evaluation of Methods for the Determination of Organic and Elemental Carbon in Particulate Samples,” In: Wolff, G. T. and Klimisch, R. L., editors. “Particulate Carbon-Atmospheric Life Cycle”, Plenum Press, New York, pp. 89-109 (1982).
Carmichael, G. R., Zhang, Y., Chen, L. L., Hong, M. S. and Ueda, H., “Seasonal Variation of Aerosol Composition at Cheju Island, Korea” , Atmospheric Environment, Vol. 30, No. 13, pp. 2407-2416 (1996).
Chan, C. C., Nien, C. K. and Hwang, J. S., “Receptor Modeling of VOCs, CO, NOx, and THC in Taipei”, Atmospheric Environment, Vol. 30, No. 1, pp. 25-33 (1996).
Chan, Y. C., Simpson, R. W., Mctainsh, G. H, Vowles, P. D., Cohan, D. D. and Bailey, G. M., “Source Apportionment of PM2.5 and PM10 aerosols in Brisbane (Australia) by Receptor Modelling”, Atmospheric Environment, Vol. 33, pp. 3251-3268 (1999).
Chan, Y. C., Simpson, R. W., Mctainsh, G. H., Vowles, P. D., Cohen, D. D. and Bailey, G. M., “Characterisation of Chemical Species in PM2.5 and PM10 Aerosols in Brisbane, Australia”, Atmospheric Environment, Vol. 31, No. 22, pp. 3773-4785 (1997).
Chang, S. N., Hopke, P. K., Rheingrover, S. W. and Gordon, G. E., “Target Transformation Factor Analysis of Wind-Trajectory Selected Samples”, Paper No. 81-21.1, Air Pollution Control Association, Pittsburgh, PA, 14 pp. (1982).
Chen, K. S., Lin, C. F. and Chou, Y. M., “Determination of Source Contributions to Ambient PM2.5 in Kaohsiung, Taiwan, Using a Receptor Model”, Journal of the Air and Waste Management Association, Vol. 51, pp. 489-498 (2001).
Chen, W. C., Wang, C. S. and Wei, C. C., “An Assessment of Source Contributions to Ambient Aerosols in Central Taiwan”, Journal of the Air and Waste Management Association, Vol. 47, pp. 501-509 (1997).
Cheng, M. D. and Hopke, P. K., “Identification of Markers For Chemical Mass Balance Receptor Model”, Atmospheric Environment, Vol. 23, No. 6, pp. 1373-1384 (1989).
Cheng, M. T. and Tsai, Y. I., “Characterization of Visibility and Atmospheric Aerosols in Urban, Suburban and Remote Areas”, The Science of the Total Environment, Vol. 263, pp.101-114 (2000).
Cheng, M. T., Huang, C. Y., Cheng, J. M., Kuo, C. I., and Wang, C. F., “Source Characterization of PM2.5 and PM10 Emissions from Oil-fired Boilers in Central Taiwan”, The Proceeding of 2001 Conference on Aerosol Science and Technology, pp. 55-58 (2001).
Chio, C. P., Cheng, M. T. and Wang, C. F., “Source Apportionment to PM10 in Different Air Quality Conditions for Taichung Urban and Coastal Areas, Taiwan”, Atmospheric Environment, Vol. 38, pp. 6893-6905 (2004).
Chow, J. C., Fairley, D., Watson, J. G., DeMandel, R., Fujita, E. M., Lowenthal, D. H., Lu, Z., Frazier, C. A., Long, G. and Cordova, J., “Source Apportionment of Wintertime PM10 at San Jose, Calif.”, Journal of Environmental Engineering, pp. 378-387 (1995).
Chow, J. C., Liu, C. S., Cassmassi, J., Watson, J. G., Lu, Z. and Pritchett, L. C., “A Neighborhood-Scale Study of PM10 Source Contributions in Rubidoux, California”, Atmospheric Environment, Vol. 26A, No. 4, pp. 693-706 (1992).
Cornille, P., Maenhaut, W. and Pacyna, J. M., “Sources and Characteristics of the Atmospheric Aerosol Near Damascus, Syria”, Atmospheric Environment, Vol. 24A, No. 5, pp. 1083-1093, 1990.
Countess, R. J., Wolff, G. T. and Cadle, S. H., “The Denver Winter Aerosol: A Comprehensive Chemical Characterization”, Journal of the Air Pollution Control Association, Vol. 30, pp. 1194-1200 (1980)
Crutcher, E. R., “Light Microscopy as an Analytical Approach to Receptor Modeling”, In: Dattner, S. L. and Hopke, P. K., editors, “Receptor Models Applied to Contemporary Pollution Problems”, Proceedings No. SP-48, Air Pollution Control Association, Pittsburgh, PA, pp. 266-284 (1982).
Draxler, R. R. and Rolph, G. D., HYSPLIT (HYbrid Single-Particle Lagrangian Integrated Trajectory) Model access via NOAA ARL READY Website (http://www.arl.noaa.gov/ready/hysplit4.html), NOAA Air Resources Laboratory, Silver Spring, MD. (2003)
Dzubay, T. G. and Mamane, Y., “Use of Electron Microscopy Data in Receptor Models For PM10”, Atmospheric Environment, Vol. 23, No. 2, pp. 467-476 (1989).
Eldred, R. A., Cahill, T. A. and Flocchini, R. G., “Composition of PM2.5 and PM10 Aerosols in the IMPROVE Network” , Journal of the Air and Waste Management Association, Vol. 47, pp. 194-203 (1997).
Fang, G. C., Chang, C. N., Wu, Y. S., Fu, P. P. C., Yang, C. J., Chen, C. D. and Chang, S. C., “Ambient Suspended Particulate Matters and Related Chemical Species Study in Central Taiwan, Taichung During 1998-2001”, Atmospheric Environment, Vol. 36, pp. 1921-1928 (2002).
Ferrer, N. and Perez, J. J., “Letter to the Editors - Determination of Sources of Atmospheric Aerosol in the Neighborhood of Barcelona Based on Receptor Models”, Atmospheric Environment, Vol. 24B, No. 1, pp. 181-184, 1990.
Friedlander, S. K., “Chemical Element Balances and Identification of Air Pollution Sources”, Environmental Science and Technology, Vol. 7, pp. 235-240 (1973).
Gertler, A. W., Lowenthal, D. A. and Coulombe, W. G., “PM10 Source Apportionment Study in Bullhead City, Arizona”, Journal of the Air and Waste Management Association, Vol. 45, pp. 75-82 (1995).
Harrison, R. M., Smith, D. J., Pio, C. A. and Castro, L. M., “Comparative Receptor Modelling Study of Airborne Particulate Pollutants In Birmingham (United Kingdom), Coimbra (Portugal) and Lahore (Pakistan)”, Atmospheric Environment, Vol. 16, pp. 1352-2310 (1997).
Henry, R. C. and Hidy, G. M., “Multivariate Analysis of Particulate Sulfate and Other air Quality Variables by Principal Components - Part I. Annual Data from Los Angeles and New York”, Atmospheric Environment, Vol. 13, pp. 1581-1596 (1979).
Henry, R. C., Lewis, C. W., Hopke, P. K. and Williamson, H. J., “Review of Receptor Model Fundamentals”, Atmospheric Environment, Vol. 18, pp. 1507-1515 (1984).
Hidy, G. M. and Friedlander, S. K., “The Nature of the Los Angeles Aerosol”, 2nd IUAPPA Clean Air Congress, Washington, DC (1972).
Ho, K. F., Lee, S. C., Chow, J. C. and Watson, J. G., “Characterization of PM10 and PM2.5 Source Profiles for Fugitive Dust in Hong Kong”, Atmospheric Environment, Vol. 37, pp. 1023-1032 (2003).
Hopke, P. K. and Casuccio, G. S., “Scanning Electron Microscopy”, In: Hopke, P. K., editor, “Receptor Modeling for Air Quality Management”, Elsevier Science Publishing company Inc., New York, pp. 149-212 (1991).
Hopke, P. K., Gladney, E. S., Gorden, G. E., Zoller, W. H.and Jones, A. G., “The Use of Multivariate Analysis to Identify Sources of Selected Elements in Boston Urban Aerosol”, Atmospheric Environment, Vol. 10, pp. 1015-1025 (1976).
Houck, J. E., “Source Sampling for Receptor Modeling”, In: Hopke, P. K., editor, “Receptor Modeling for Air Quality Management”, Elsevier Science Publishing company Inc., New York, pp. 45-82 (1991).
Lee, E., Chan, C. K. and Paatero, P., “Application of Positive Matrix Factorization in Source Apportionment of Particulate Pollutants in Hong Kong”, Atmospheric Environment, Vol. 33, pp. 3201-3212 (1999).
Lowenthal, D. H., Borys, R. D. and Mosher, B. W., “Sources of Pollution Aerosol at Dye 3, Greenland”, Atmospheric Environment, Vol. 31, No. 22, pp. 3707-3717 (1997).
Mason, B., “Principles of Geochemistry”, 3rd Edition, Wiley, New York (1966)
Miller, M. S., Friedlander, S. K. and Hidy, G. M., “A Chemical Element Balance for the Pasadena Aerosol”, Journal of Colloid Interface Science, Vol. 39, pp. 165-176 (1972)
Miranda, J., Andrade, E., Lopez-Suarez, A., Ledesma, R., Cahill, T. A. and Wakabayashi, P. H., “A Receptor Model for Atmospheric Aerosols from a Southwestern Site in Mexico City”, Atmospheric Environment, Vol. 30, No. 20, pp. 3471-3479 (1996).
Mishra, V. K., Kim, K. H., Kang, C. H. and Choi, K. C., “Wintertime Sources and Distribution of Airborne Lead in Korea”, Atmospheric Environment, Vol. 38, pp. 2653-2664 (2004).
Mood, A. M., Graybill, F. A. and Boes, D. C., “Introduction to the Theory of Statistics”, McGraw-Hill Book Company, New York (1976).
Ohta, S. and Okita, T., “A Chemical Characterization of Atmospheric Aerosol in Sapporo”, Atmospheric Environment, Vol. 24A, No. 4, pp. 815-822 (1990).
Ohta, S., Hori, M., Yamagata, S. and Murao, N., “Chemical Characterization of Atmospheric Fine Particles in Sapporo with Determination of Water Content”, Atmospheric Environment, Vol. 32, pp. 1021-1025 (1998).
Okamoto, S., Hayashi, M., Nakajima, M., Kainuma, Y. and Shiozawa, K., “A Factor Analysis-Multiple Regression Model for Source Apportionment of Suspended Particulate Matter”, Atmospheric Environment, Vol. 24A, No. 8, pp. 2089-2097 (1990).
Olmez, I., Sheffield, A. E., Gordon, G. E., Houck, J. E., Pritchett, L. C., Cooper, J. A., Dzubay, T. G. and Bennett, R. L., “Compositions of Particles from Selected Sources in Philadelphia for Receptor Modeling Applications”, Journal of the Air Pollution Control Association, Vol. 38, No. 11, pp. 1392-1402 (1988).
Pio, C. A., Santos, I. M., Anacleto, T. D., Nunes, T. V., Leal, R. M., “Particulate and Gaseous Air Pollutant Levels at The Portuguese West Coast”, Atmospheric Environment, Vol. 25A, No. 3/4, pp.669-680 (1991).
Rahn, K. A., “Silicon and Aluminum in Atmospheric Aerosols: Crust-air Fractionation ?”, Atmospheric Environment, Vol 10 , pp 597-601 (1976).
Rojas, C. M., Artaxo, P. and Grieken, R. V., “Aerosols in Santiago De Chile: A Study Using Receptor Modeling with X-Ray Fluorescence and Single Particle Analysis”, Atmospheric Environment, Vol. 24B, No. 2, pp. 227-241 (1990).
Rolph, G. D., Real-time Environmental Applications and Display sYstem (READY) Website (http://www.arl.noaa.gov/ready/hysplit4.html), NOAA Air Resources Laboratory, Silver Spring, MD. (2003)
Salvador, P., Artinano, B., Alonso, D. G., Querol, X. and Alastuey A., “Identification and Characterisation of Sources of PM10 in Madrid (Spain) by Statistical Methods”, Atmospheric Environment, Vol. 38, pp. 435-447 (2004).
Sisler, J. F. and Malm, W. C., “The Relative Importance of Soluble Aerosols to Spatial and Seasonal Trends of Impaired Visibility in the United State”, Atmospheric Environment, Vol. 28, No. 5, pp. 851-862 (1994).
Thurston, G. D. and Lioy, P. J., “Receptor Modeling and Aerosol Transport”, Atmospheric Environment, Vol. 21, No. 3, pp. 687-698 (1987).
Tsai, Y. I. and Cheng, M. T., “Visibility and Aerosol Chemical Compositions Near the Coastal Area in Central Taiwan”, The Science of the Total Environment, Vol. 231, pp.37-51 (1999).
Tsai, Y. I. and Cheng, M. T., “Characterization of Chemical Species in Atmospheric Aerosols in a Metropolitan Basin”, Chemosphere, Vol. 54, pp. 1171-1181 (2004).
Tsuang, B. J. and Chao, J. P., “Development of a Circuit Model to Describe the Advection-Diffusion Equation for Air Pollution”, Atmospheric Environment, Vol. 31, pp. 639-657 (1997)
Tsuang, B. J., “Quantification on the Source/Receptor Relationship of Primary Pollutants and Secondary Aerosols by a Gaussian Plume Trajectory Model: Part I﹘Theory”, Atmospheric Environment, Vol. 37, pp. 3981-3991 (2003).
Tsuang, B. J., Chen, C. L., Lin, C. H., Cheng, M. T., Tsai, Y. I., Chio, C. P., Pan, R. C. and Kuo, P. H., “Quantification on the Source/Receptor Relationship of Primary Pollutants and Secondary Aerosols by a Gaussian Plume Trajectory Model: Part II. Case Study”, Atmospheric Environment, Vol. 37, pp. 3993-4006 (2003).
USEPA, "Receptor Model Source Composition Library", Environmental Protection Agency Research Triangle Park, NC., EPA-450/4-85-002 (1984).
USEPA, “A revised user’s guide to MESOPUFF II (V5.1)”, EPA 454/B-94-025, US Environment Protection Agency, Research Triangle Park, NC (1994).
USEPA, “Volatile Organic compound (VOC)/Particulate Matter (PM) Speciation Data System User’s Manual”, Environmental Protection Agency Research Triangle Park, NC., (1991).
Vega, E., Garcia, I., Apam, D., Ruiz, M. E. and Barbiaux, M., “Application of a Chemical Mass Balance Receptor Model to Respirable Particulate Matter in Mexico City”, Journal of the Air & Waste Management Association, Vol. 47, (1997).
Wang, C. F., Chen, W. H., Yang, M. H. and Chiang, P. C., “Microwave Decomposition for Airborne Particulate Matter for the Determination of Trace Elements by Inductively Coupled Plasma Mass Spectrometry”, Analyst, Vol. 120, pp.1681-1686 (1995).
Watson, J. G., “Chemical Element Balance Receptor Model Methodology for Assessing the Sources of Fine and Total Suspended Particulate Matter in Portland, Oregon”, Ph.D. Dissertation, Oregon Graduate Center, Beaverton, Oregon (1979).
Watson, J. G., Chow, J. C., Lowenthal, D. H., Pritchett, L. C., Frazier, C. A., Neuroth, G. R. and Robbins, R., “Differences in The Carbon Composition of Source Profiles For Diesel- And Gasoline-Powered Vehicles”, Atmospheric Environment, Vol. 28, pp.2493-2505 (1994).
Watson, J. G., Robinson, N. F., Chow, J. C., Henry, R. C., Kim, B. M., Pace, T. G., Meyer, E. L. and Nguyen, Q., “The USEPA/DRI Chemical Mass Balance Receptor Model, CMB 7.0”, Environmental Software, Vol. 5, No. 1, pp. 38-49 (1990).
Watson, J. G., Robinson, N. F., Lewis, C., Coulter, T., Chow, J. C., Fujita, E. M., Lownethal, D. H., Conner, T. L., Henry, R. C. and Willis, R. D., “Chemical Mass Balance Receptor Model Version 8 User’s Manual”, Desert Research Institute Document No. 1808.1D1 (1997).
中鼎與中技社, 「台灣地區空氣污染物排放量推估手冊」，行政院環保署專案報告，台北(2001)。
王秋森，「石化工廠產生的粒狀空氣污染物的受體模式之建立」，行政院國家科學委員會專題研究計畫，NSC 83-0421-B-002-318Z (1994)。
行政院環保署，「空氣品質保護25年紀實(1975-2000)」，台北(2000)。
吳啟文，「台灣中部都會區氣懸微粒粒徑分佈之污染物特性分析」，中央大學環境工程研究所碩士論文，中壢 (1996)。
莊進源、蔣本基、王執明、葉錫溶、楊末雄、林江山、沈世宏、 蔡惠澤，「高雄市空氣污染物受體模式建立之研究」，行政院衛生署環境保護局報告，高雄(1987)。
陳紀綸，「台中港地區大氣懸浮微粒污染來源分析」，碩士論文，國立中興大學環境工程研究所，台中(1999)。
程萬里、黃怡嘉，「中部地區臭氧及懸浮微粒與氣象因子之相關研究」，第十七屆空氣污染控制技術研討會論文集，第38-44頁。斗六 (2000)。
黃宗正、李正綱、曾錦富等，「台中發電廠南方空氣中懸浮微粒特性研究」，第九屆空氣污染控制技術研討會論文專輯，台南 (1992)。
蔣本基、沈世宏、楊末雄、王竹方、魏輝揮、張勝祺、陳堯中、王碧、林志鴻、鍾瑞源等，「台北地區交通污染與營建工程對空氣品質影響之研究及受體模式之確立」，行政院環境保護署報告 (1989)。
蔣本基、楊末雄、王竹方、張勝祺、魏耀揮、周仲島、望熙榮、鄭曼婷、詹長權、王秋森、杜悅元等，「台灣北、中部地區受體模式建立與應用研究(一)」，行政院環境保護署報告，EPA-82-E3F1-09-01 (1993)。
蔡瀛逸，「台灣中部都會及沿海地區能見度與大氣氣膠化學特性關係之研究」，博士論文，國立中興大學環境工程研究所，台中(1999)。
鄭曼婷、邱嘉斌、陳紀綸、王景良，「南高屏地區空氣品質總量管制研究﹘子計畫E2：既有指紋資料之彙整與受體模式在南高屏地區之應用」，行政院環境保護署研究報告，EPA-87-FA42-03-F5 (1998)。
鄭曼婷、陳昭忞、邱嘉斌，「鍋爐煙道排放PM2.5及PM10微粒之特性及化學組成」，國科會專題研究計劃期末報告，NSC 90-2211-E-005-014 (2002)。
鄭曼婷、程萬里、張艮輝、林沛練、莊秉潔、王竹方、郭崇義、林宗嵩、王重傑、黃景祥、白曛綾，「中部地區空氣污染總量管制技術資料建立與應用」，行政院環境保護署研究報告，EPA-89-FA11-03-231 (2000)。
賴沛君，「應用CMB受體模式分析懸浮微粒高污染事件之研究」，碩士論文，國立中興大學環境工程研究所，台中(2004)。
魏致中，「台灣麥寮地區大氣中懸浮微粒及微粒源化學組成之探討」，碩士論文，國立台灣大學職業醫學與工業衛生研究所，台北(1994)