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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 闕蓓德 | zh_TW |
dc.contributor.advisor | Pei-Te Chiueh | en |
dc.contributor.author | 龔芝瑩 | zh_TW |
dc.contributor.author | Zhi-Ying Kung | en |
dc.date.accessioned | 2023-07-31T16:18:26Z | - |
dc.date.available | 2023-11-09 | - |
dc.date.copyright | 2023-07-31 | - |
dc.date.issued | 2022 | - |
dc.date.submitted | 2023-04-08 | - |
dc.identifier.citation | AirNow-International. (n.d.). AirNow-International Community forum.
Alberini, A., & Ščasný, M. (2013). Exploring heterogeneity in the value of a statistical life: Cause of death v. risk perceptions. Ecological Economics, 94, 143-155. Alexeeff, S. E., Liao, N. S., Liu, X., Van Den Eeden, S. K., & Sidney, S. (2021). Long‐term PM2. 5 exposure and risks of ischemic heart disease and stroke events: review and meta‐analysis. Journal of the American Heart Association, 10(1), e016890. Al-Kindi, S. G., Brook, R. D., Biswal, S., & Rajagopalan, S. (2020). Environmental determinants of cardiovascular disease: lessons learned from air pollution. Nature Reviews Cardiology, 17(10), 656-672. American heart association (2021). Leading cardiovascular organizations call for urgent action to reduce air pollution. Retrieved from https://newsroom.heart.org/news/leading-cardiovascular-organizations-call-for-urgent-action-to-reduce-air-pollution An, J., & Heshmati, A. (2019). The relationship between air pollutants and healthcare expenditure: empirical evidence from South Korea. Environmental Science and Pollution Research, 26(31), 31730-31751. Ananthapavan, J., Moodie, M., Milat, A. J., & Carter, R. (2021). Systematic review to update ‘value of a statistical life’estimates for Australia. International journal of environmental research and public health, 18(11), 6168 Bai, L. I., Shin, S., Burnett, R. T., Kwong, J. C., Hystad, P., van Donkelaar, A., ... & Chen, H. (2019). Exposure to ambient air pollution and the incidence of congestive heart failure and acute myocardial infarction: A population-based study of 5.1 million Canadian adults living in Ontario. Environment international, 132, 105004. BenMAP. (2022). BenMAP-CE Manual and Appendices. Retrieved from https://www.epa.gov/benmap/benmap-ce-manual-and-appendices. Bertram, M. Y., Lauer, J. A., De Joncheere, K., Edejer, T., Hutubessy, R., Kieny, M. P., & Hill, S. R. (2016). Cost–effectiveness thresholds: pros and cons. Bulletin of the World Health Organization, 94(12), 925. Bhaskaran, K., Hajat, S., Armstrong, B., Haines, A., Herrett, E., Wilkinson, P., & Smeeth, L. (2011). The effects of hourly differences in air pollution on the risk of myocardial infarction: case crossover analysis of the MINAP database. Bmj, 343. Chan, C. C., Chuang, K. J., Chien, L. C., Chen, W. J., & Chang, W. T. (2006). Urban air pollution and emergency admissions for cerebrovascular diseases in Taipei, Taiwan. European heart journal, 27(10), 1238-1244. Chang, Q., Liu, S., Chen, Z., Zu, B., & Zhang, H. (2020). Association between air pollutants and outpatient and emergency hospital visits for childhood asthma in Shenyang city of China. International Journal of Biometeorology, 64(9), 1539-1548. Chen, F., & Chen, Z. (2021). Cost of economic growth: Air pollution and health expenditure. Science of the Total Environment, 755, 142543. Cheng, B., Zhou, J., Ma, Y., Zhang, Y., Wang, H., Chen, Y., ... & Feng, F. (2022). Association between atmospheric particulate matter and emergency room visits for cerebrovascular disease in Beijing, China. Journal of Environmental Health Science and Engineering, 1-11. Cheng, J., Su, H., & Xu, Z. (2021). Intraday effects of outdoor air pollution on acute upper and lower respiratory infections in Australian children. Environmental Pollution, 268, 115698. Chung, J. W., Bang, O. Y., Ahn, K., Park, S. S., Park, T. H., Kim, J. G., ... & Bae, H. J. (2017). Air pollution is associated with ischemic stroke via cardiogenic embolism. Stroke, 48(1), 17-23. Cromar, K. R., Ghazipura, M., Gladson, L. A., & Perlmutt, L. (2020). Evaluating the US Air Quality Index as a risk communication tool: Comparing associations of index values with respiratory morbidity among adults in California. PloS one, 15(11), e0242031. Desqueyroux, H., Pujet, J. C., Prosper, M., Le Moullec, Y., & Momas, I. (2002). Effects of air pollution on adults with chronic obstructive pulmonary disease. Archives of Environmental Health: An International Journal, 57(6), 554-560. Dong, G. H., Qian, Z., Xaverius, P. K., Trevathan, E., Maalouf, S., Parker, J., ... & Simckes, M. (2013). Association between long-term air pollution and increased blood pressure and hypertension in China. Hypertension, 61(3), 578-584. Elbarbary, M., Oganesyan, A., Honda, T., Kelly, P., Zhang, Y., Guo, Y., ... & Negin, J. (2020). Ambient air pollution, lung function and COPD: cross-sectional analysis from the WHO Study of AGEing and adult health wave 1. BMJ open respiratory research, 7(1), e000684. Evans, M. F., & Smith, V. K. (2006). Do we really understand the age–VSL relationship?. Resource and Energy Economics, 28(3), 242-261. Fann, N., Alman, B., Broome, R. A., Morgan, G. G., Johnston, F. H., Pouliot, G., & Rappold, A. G. (2018). The health impacts and economic value of wildland fire episodes in the US: 2008–2012. Science of the total environment, 610, 802-809. Fann, N., Lamson, A. D., Anenberg, S. C., Wesson, K., Risley, D., & Hubbell, B. J. (2012). Estimating the national public health burden associated with exposure to ambient PM2.5 and ozone. Risk Analysis: An International Journal, 32(1), 81-95. Franklin, M., Zeka, A., & Schwartz, J. (2007). Association between PM2. 5 and all-cause and specific-cause mortality in 27 US communities. Journal of exposure science & environmental epidemiology, 17(3), 279-287. Guo, Y., Zeng, H., Zheng, R., Li, S., Barnett, A. G., Zhang, S., ... & Williams, G. (2016). The association between lung cancer incidence and ambient air pollution in China: A spatiotemporal analysis. Environmental research, 144, 60-65. Hadian, M., Raeissi, P., & Harati Khalilabad, T. (2020). The economic burden of mortality and morbidity due to air pollution in Tehran, Iran: a systematic review. Air Quality, Atmosphere & Health, 13(8), 1001-1011. Hajat, S., Haines, A., Goubet, S. A., Atkinson, R. W., & Anderson, H. R. (1999). Association of air pollution with daily GP consultations for asthma and other lower respiratory conditions in London. Thorax, 54(7), 597-605. Hammitt, J. K., & Haninger, K. (2010). Valuing fatal risks to children and adults: Effects of disease, latency, and risk aversion. Journal of risk and Uncertainty, 40(1), 57-83. Hao, Y., Balluz, L., Strosnider, H., Wen, X. J., Li, C., & Qualters, J. R. (2015). Ozone, fine particulate matter, and chronic lower respiratory disease mortality in the United States. American journal of respiratory and critical care medicine, 192(3), 337-341. Henrotin, J. B., Besancenot, J. P., Bejot, Y., & Giroud, M. (2007). Short-term effects of ozone air pollution on ischaemic stroke occurrence: a case-crossover analysis from a 10-year population-based study in Dijon, France. Occupational and environmental medicine, 64(7), 439-445. Ho, A. F. W., Tan, B. Y. Q., Zheng, H., Leow, A. S. T., Pek, P. P., Liu, N., ... & Aik, J. (2022). Association of air pollution with acute ischemic stroke risk in Singapore: a time-stratified case-crossover study. International Journal of Stroke, 17474930211066745. Huang, F., Pan, B., Wu, J., Chen, E., & Chen, L. (2017). Relationship between exposure to PM2. 5 and lung cancer incidence and mortality: A meta-analysis. Oncotarget, 8(26), 43322. Hubbell, B. J., Hallberg, A., McCubbin, D. R., & Post, E. (2005). Health-related benefits of attaining the 8-hr ozone standard. Environmental health perspectives, 113(1), 73-82. International Agency for Research on Cancer. (2013, October 17). IARC: Outdoor air pollution a leading environmental cause of cancer deaths. Retrieved from: https://www.iarc.who.int/wp-content/uploads/2018/07/pr221_E.pdf. Jaafar, H., Razi, N. A., Azzeri, A., Isahak, M., & Dahlui, M. (2018). A systematic review of financial implications of air pollution on health in Asia. Environmental Science and Pollution Research, 25(30), 30009-30020. Jie, G. U. O., Mingyue, M. A., Chunling, X. I. A. O., Chunqing ZHANG, J. C., Hong, L. I. N., Yiming, D. U., & Min, L. I. U. (2018). Association of air pollution and mortality of acute lower respiratory tract infections in Shenyang, China: a time series analysis study. Iranian journal of public health, 47(9), 1261. Kan, H., London, S. J., Chen, G., Zhang, Y., Song, G., Zhao, N., ... & Chen, B. (2008). Season, sex, age, and education as modifiers of the effects of outdoor air pollution on daily mortality in Shanghai, China: The Public Health and Air Pollution in Asia (PAPA) Study. Environmental health perspectives, 116(9), 1183-1188. Karimi, S. M., Maziyaki, A., Moghadam, S. A., Jafarkhani, M., Zarei, H., Moradi-Lakeh, M., & Pouran, H. (2020). Continuous exposure to ambient air pollution and chronic diseases: prevalence, burden, and economic costs. Reviews on Environmental Health, 35(4), 379-399. Keoni Everington(2019).Taiwan has 15th highest lung cancer rate in world. Taiwan News. Retrived from https://www.taiwannews.com.tw/en/news/3825780. Kim, K. H., Kabir, E., & Kabir, S. (2015). A review on the human health impact of airborne particulate matter. Environment international, 74, 136-143. Lai, H. C., Hsiao, M. C., Liou, J. L., Lai, L. W., Wu, P. C., & Fu, J. S. (2020). Using costs and health benefits to estimate the priority of air pollution control action plan: a case study in Taiwan. Applied Sciences, 10(17), 5970. Lee, Y. M., Lee, J. H., Kim, H. C., & Ha, E. (2020). Effects of PM10 on mortality in pure COPD and asthma-COPD overlap: difference in exposure duration, gender, and smoking status. Scientific reports, 10(1), 1-10. Lepeule, J., F. Laden, D. Dockery, J. Schwartz (2012), “Chronic exposure to fine particles and mortality: an extended follow-up of the Harvard Six Cities Study from 1974 to 2009,” Environmental health perspectives, 120(7): 965. Liou, J. L. (2019a). Health Benefit of Particulate Matter Reductuon in Taiwan-Application of Benefits per Ton Method: Chung-Hua Institution for Economic Research. Liou, J. L. (2019b), “Effect of Income Heterogeneity on Valuation of Mortality Risk in Taiwan: An Application of Unconditional Quantile Regression Method,” International Journal of Environmental Research and Public Health, 16(9): 1620. Liu, G., Sun, B., Yu, L., Chen, J., Han, B., Li, Y., & Chen, J. (2020). The gender-based differences in vulnerability to ambient air pollution and cerebrovascular disease mortality: evidences based on 26781 deaths. Global Heart, 15(1). Liu, Y. M., & Ao, C. K. (2021). Effect of air pollution on health care expenditure: Evidence from respiratory diseases. Health Economics, 30(4), 858-875. Maji, S., Ahmed, S., Ghosh, S., & Garg, S. K. (2020). Evaluation of air quality index for air quality data interpretation in Delhi, India. Curr Sci, 119(6), 1019-1026. Mar, T. F., Koenig, J. Q., & Primomo, J. (2010). Associations between asthma emergency visits and particulate matter sources, including diesel emissions from stationary generators in Tacoma, Washington. Inhalation toxicology, 22(6), 445-448. Marseille, E., Larson, B., Kazi, D. S., Kahn, J. G., & Rosen, S. (2014). Thresholds for the cost–effectiveness of interventions: alternative approaches. Bulletin of the World Health Organization, 93, 118-124. McDonnell, W. F., Abbey, D. E., Nishino, N., & Lebowitz, M. D. (1999). Long-term ambient ozone concentration and the incidence of asthma in nonsmoking adults: the AHSMOG Study. Environmental Research, 80(2), 110-121. McGuinn, L. A., Ward-Caviness, C. K., Neas, L. M., Schneider, A., Diaz-Sanchez, D., Cascio, W. E., ... & Devlin, R. B. (2016). Association between satellite-based estimates of long-term PM2.5 exposure and coronary artery disease. Environmental research, 145, 9-17. Mirabelli, M. C., Ebelt, S., & Damon, S. A. (2020). Air Quality Index and air quality awareness among adults in the United States. Environmental research, 183, 109185. Næss, Ø., Nafstad, P., Aamodt, G., Claussen, B., & Rosland, P. (2007). Relation between concentration of air pollution and cause-specific mortality: four-year exposures to nitrogen dioxide and particulate matter pollutants in 470 neighborhoods in Oslo, Norway. American journal of epidemiology, 165(4), 435-443. Nikoonahad, A., Naserifar, R., Alipour, V., Poursafar, A., Miri, M., Ghafari, H. R., ... & Mohammadi, A. (2017). Assessment of hospitalization and mortality from exposure to PM10 using AirQ modeling in Ilam, Iran. Environmental Science and Pollution Research, 24(27), 21791-21796. Niu, Y., Chen, R., & Kan, H. (2017). Air pollution, disease burden, and health economic loss in China. Ambient Air Pollution and Health Impact in China, 233-242. Nuvolone, D., Balzi, D., Pepe, P., Chini, M., Scala, D., Giovannini, F., ... & Barchielli, A. (2013). Ozone short-term exposure and acute coronary events: a multicities study in Tuscany (Italy). Environmental research, 126, 17-23. Orellano, P., Reynoso, J., Quaranta, N., Bardach, A., & Ciapponi, A. (2020). Short-term exposure to particulate matter (PM10 and PM2. 5), nitrogen dioxide (NO2), and ozone (O3) and all-cause and cause-specific mortality: Systematic review and meta-analysis. Environment international, 142, 105876. Ostro, B. D., Lipsett, M. J., Mann, J. K., Krupnick, A., & Harrington, W. (1993). Air pollution and respiratory morbidity among adults in Southern California. American Journal of Epidemiology, 137(7), 691-700. Perlmutt, L. D., & Cromar, K. R. (2019a). Evaluation of the Air Quality Index as a Risk Communication Tool. Journal of Environmental Health, 81(6). Perlmutt, L. D., & Cromar, K. R. (2019b). Comparing associations of respiratory risk for the EPA Air Quality Index and health-based air quality indices. Atmospheric Environment, 202, 1-7. Pope, C. A, D. W. Dockery, J. D. Spengler, and M. E. Raizenne (1991), “Respiratory health and PM10 pollution: a daily time series analysis,” American Review of Respiratory Disease, 144111(3_pt_1): 668-674. Puett, R. C., Hart, J. E., Yanosky, J. D., Paciorek, C., Schwartz, J., Suh, H., ... & Laden, F. (2009). Chronic fine and coarse particulate exposure, mortality, and coronary heart disease in the Nurses’ Health Study. Environmental health perspectives, 117(11), 1697-1701. Puett, R. C., Schwartz, J., Hart, J. E., Yanosky, J. D., Speizer, F. E., Suh, H., ... & Laden, F. (2008). Chronic particulate exposure, mortality, and coronary heart disease in the nurses’ health study. American journal of epidemiology, 168(10), 1161-1168. Raaschou-Nielsen, O., Andersen, Z. J., Jensen, S. S., Ketzel, M., Sørensen, M., Hansen, J., ... & Overvad, K. (2012). Traffic air pollution and mortality from cardiovascular disease and all causes: a Danish cohort study. Environmental Health, 11(1), 1-12. Revich, B., & Shaposhnikov, D. (2010). The effects of particulate and ozone pollution on mortality in Moscow, Russia. Air Quality, Atmosphere & Health, 3(2), 117-123. Ruidavets, J. B., Cournot, M., Cassadou, S., Giroux, M., Meybeck, M., & Ferrières, J. (2005). Ozone air pollution is associated with acute myocardial infarction. Circulation, 111(5), 563-569. Santus, P., Russo, A., Madonini, E., Allegra, L., Blasi, F., Centanni, S., ... & Amaducci, S. (2012). How air pollution influences clinical management of respiratory diseases. A case-crossover study in Milan. Respiratory research, 13(1), 1-12. Schuchter, J., Bhatia, R., Corburn, J., & Seto, E. (2014). Health impact assessment in the United States: Has practice followed standards?. Environmental Impact Assessment Review, 47, 47-53. She, Q., Peng, X., Xu, Q., Long, L., Wei, N., Liu, M., ... & Xiang, W. (2017). Air quality and its response to satellite-derived urban form in the Yangtze River Delta, China. Ecological Indicators, 75, 297-306. Shen, F., Ge, X., Hu, J., Nie, D., Tian, L., & Chen, M. (2017). Air pollution characteristics and health risks in Henan Province, China. Environmental research, 156, 625-634. Song, J., Gao, Y., Hu, S., Medda, E., Tang, G., Zhang, D., ... & Zheng, X. (2021). Association of long-term exposure to PM2. 5 with hypertension prevalence and blood pressure in China: a cross-sectional study. BMJ open, 11(12), e050159. Tagaris, E., Liao, K. J., DeLucia, A. J., Deck, L., Amar, P., & Russell, A. G. (2009). Potential impact of climate change on air pollution-related human health effects. Environmental science & technology, 43(13), 4979-4988. ter Burg, W., Bokkers, B. G. H., Kroese, E. D., & Schuur, A. G. (2015). A First Exploration of Health Impact Assessment of Chemical Exposure: Assigning Weights to Subclinical Effects Based on Animal Studies. Human and Ecological Risk Assessment: An International Journal, 21(3), 763-780. U.S. Environmental Protection Agency. (2014). Air Quality Index: A guide to air quality and your health (Publication No. EPA- 456/F-14-002). Research Triangle Park, NC: Office of Air Quality and Planning Standards. Retrieved from https://www3.epa.gov/airnow/aqi_brochure_02_14.pdf USEPA(2014). USEPA(2016). Ozone and your patients’ health [training course]. Retrieved from https://www.epa.gov/ozone-pollution-and-your-patients-health. USEPA(2021). Conducting a Human Health Risk Assessment. Retrieved from https://www.epa.gov/risk/conducting-human-health-risk-assessment. World Bank, & Institute for Health Metrics and Evaluation. (2016). The cost of air pollution: strengthening the economic case for action. World Health Organization. (2009, July 16). Health impact assessment: Reasons for using HIA. Retrieved from https://www.who.int/news-room/questions-and-answers/item/reasons-for-using-health-impact-assessment-hia. World Health Organization. (2021, September 21). Ambient (outdoor) air pollution. Retrieved from https://www.who.int/news-room/fact-sheets/detail/ambient-(outdoor)-air-quality-and-health. Yin, P., Chen, R., Wang, L., Meng, X., Liu, C., Niu, Y., ... & Kan, H. (2017). Ambient ozone pollution and daily mortality: a nationwide study in 272 Chinese cities. Environmental health perspectives, 125(11), 117006. Yu, Y., Yao, S., Dong, H., Wang, L., Wang, C., Ji, X., ... & Zhang, Z. (2019). Association between short-term exposure to particulate matter air pollution and cause-specific mortality in Changzhou, China. Environmental research, 170, 7-15. Zafirah, Y., Lin, Y. K., Andhikaputra, G., Deng, L. W., Sung, F. C., & Wang, Y. C. (2021). Mortality and morbidity of asthma and chronic obstructive pulmonary disease associated with ambient environment in metropolitans in Taiwan. PloS one, 16(7), e0253814. Zanobetti, A., & Schwartz, J. (2007). Particulate air pollution, progression, and survival after myocardial infarction. Environmental health perspectives, 115(5), 769-775. Zanobetti, A., Franklin, M., Koutrakis, P., & Schwartz, J. (2009). Fine particulate air pollution and its components in association with cause-specific emergency admissions. Environmental Health, 8(1), 1-12. Zhang, C., Quan, Z., Wu, Q., Jin, Z., Lee, J. H., Li, C., ... & Cui, L. (2018). Association between atmospheric particulate pollutants and mortality for cardio-cerebrovascular diseases in Chinese Korean population: a case-crossover study. International Journal of Environmental Research and Public Health, 15(12), 2835. Zhang, P., Dong, G., Sun, B., Zhang, L., Chen, X., Ma, N., ... & Chen, J. (2011). Long-term exposure to ambient air pollution and mortality due to cardiovascular disease and cerebrovascular disease in Shenyang, China. PloS one, 6(6), e20827. Zhang, S., Li, G., Tian, L., Guo, Q., & Pan, X. (2016). Short-term exposure to air pollution and morbidity of COPD and asthma in East Asian area: A systematic review and meta-analysis. Environmental research, 148, 15-23. Zhao, M., Xu, Z., Guo, Q., Gan, Y., Wang, Q., & Liu, J. A. (2022). Association between long-term exposure to PM2.5 and hypertension: A systematic review and meta-analysis of observational studies. Environmental Research, 204, 112352. Zheng, P. W., Wang, J. B., Zhang, Z. Y., Shen, P., Chai, P. F., Li, D., ... & Chen, K. (2017). Air pollution and hospital visits for acute upper and lower respiratory infections among children in Ningbo, China: a time-series analysis. Environmental Science and Pollution Research, 24(23), 18860-18869. Zou, L., Zong, Q., Fu, W., Zhang, Z., Xu, H., Yan, S., ... & Lv, C. (2021). Long-term exposure to ambient air pollution and myocardial infarction: a systematic review and meta-analysis. Frontiers in medicine, 8, 616355. 中華民國內政部戶政司(無日期)。人口統計資料 – 年度縣市及全國統計資料 – 107年全國人口統計資料,內政部戶政司全球資訊網。2021,取自https://www.ris.gov.tw/app/portal/346。 中華民國內政部戶政司(無日期)。人口統計資料 – 年度縣市及全國統計資料 – 108年全國人口統計資料,內政部戶政司全球資訊網。2022,取自https://www.ris.gov.tw/app/portal/346。 交通部中央氣象局(2018)。2018年臺灣季節氣候分析。 交通部運輸研究所(2019)。108年交通建設計畫經濟效益評估手冊。 行政院主計總處(2019a)。107年薪資與生產力統計。 行政院主計總處(2019b)。各縣市工業及服務業企業僱用員工薪資統計說明。 行政院主計總處(2019c)。107年工業及服務業受僱員工全年總薪資中位數及分布統計結果。 行政院主計總處(2020)。108年工業及服務業受僱員工全年總薪資中位數及分布統計結果。 行政院主計總處(2021)。物價指數 – 統計表,中華民國統計資訊網,取自https://www.stat.gov.tw/ct.asp?xItem=35375&CtNode=487&mp=4。 行政院主計總處(2022)。最新統計指標 – 消費者物價基本分類指數,取自https://nstatdb.dgbas.gov.tw/dgbasall/webMain.aspx?sys=210&funid=A030101010 行政院環境保護署(2013)。《我國細懸浮微粒空品標準效益評估工具及實證研究》,環保署 / 國科會空污防制科研合作計畫,計畫編號:NSC102- EPA-F-002-001,執行單位:國立臺灣大學、財團法人中華經濟研究院。 行政院環境保護署(2017a)。空氣污染防制新作為,國土及公共治理季刊,第五卷,第三期。 行政院環境保護署(2017b)。空氣污染防制策略。 行政院環境保護署(2018a)。空氣污染防制法。 行政院環境保護署(2018b)。中華民國空氣品質監測報告105年年報。 行政院環境保護署(2018c)。空氣品質指標(AQI)(歷史資料),環保署環境資料開放平臺,取自https://data.epa.gov.tw/dataset/detail/AQX_P_488。 行政院環境保護署(2018d)。日空氣品質指標(AQI),環保署環境資料開放平臺,取自https://data.epa.gov.tw/dataset/detail/AQX_P_434。 行政院環境保護署(2019)。中華民國空氣品質監測報告107年年報。 行政院環境保護署(2020a)。空氣污染防制方案(109年至112年)。 行政院環境保護署(2020b)。中華民國109年度空氣污染防制總檢討。 行政院環境保護署(無日期)。各級環保單位附屬單位決算 – 空氣污染防制基金,環保統計查詢網,2022,取自https://statis91.epa.gov.tw/epanet/。 行政院環境保護署(無日期)。空氣品質指標,空氣品質監測網,2021a,取自https://airtw.epa.gov.tw/CHT/Information/Standard/AirQualityIndicator.aspx。 宋雅珍(2019)。公共建設計畫效益評估之研究,經濟研究,第19期。 李汶洙(2010)。生命價值與年齡關係之實證分析─以台灣為例,碩士論文,國立中央大學,產業經濟研究所,桃園市。 屏東縣政府環保局(2021)。屏東縣空氣污染防制計畫(109年至112年)。 孫克難(2015)。法規或政策影響評估(RIA)之成本效益分析,財稅研究,第44卷,第3期。 高雄市政府環保局(2021)。高雄市空氣污染防制計畫(109年至112年)。 國家發展委員會(2020)。人口推估 - 5.高齡化時程,取自https://www.ndc.gov.tw/Content_List.aspx?n=695E69E28C6AC7F3 張書豪(2015)。以非線性分布遞延模型評估 AQI 指標對心血管疾病的影響 – 以台北盆地為例,碩士論文,國立陽明大學,生物醫學資訊學研究所,臺北市。 陳文姿(2017)。2150億救空污 林全拍版2019年PM2.5降18%。環境資訊中心。取自:https://e-info.org.tw/node/204215。 衛生福利部中央健康保健署(2020)。107年癌症登記報告。 衛生福利部中央健康保健署(2020)。107年癌症登記報告。 衛生福利部中央健康保健署(2020)。2014年版_ICD-9-CM2001年版與ICD-10-CM/PCS對應檔。 衛生福利部國民健康署(2016)。2013年「國民健康訪問調查」結果報告。 衛生福利部統計處(2019b)。107年死因統計結果分析,取自https://www.mohw.gov.tw/cp-16-48057-1.html。 衛生福利部統計處(2021a)。全民健康保險醫療統計 – 106年全民健康保險醫療統計年報。 衛生福利部統計處(2021b)。全民健康保險醫療統計 – 107年全民健康保險醫療統計年報。 衛生福利部統計處(2021c)。全民健康保險醫療統計 – 108年全民健康保險醫療統計年報。 衛生福利部統計處(2021d)。106年死因統計年報。 衛生福利部統計處(2021e)。107年死因統計年報。 衛生福利部統計處(2021f)。108年死因統計年報。 駱尚廉與蕭代基 (2007)。「環境經濟分析」。臺北:曉園出版社。 | - |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/87918 | - |
dc.description.abstract | 空氣品質對人體健康影響的議題不分國內外都越來越受到關注。為提升國民健康保障和改善空氣污染,我國政府於2016年12月起實施空氣品質指標(Air Quality Index, AQI),並制定空氣品質保護相關政策和規劃;然而多數研究以特定空氣污染物的濃度減量來評估空氣品質改善成效,不易民眾理解。本研究係考量民眾在日常生活中多以易於理解的AQI判定空氣污染情形,且我國空污防制方案和計畫皆將AQI不良率作為空氣品質目標,故針對AQI等級之間的改善和AQI不良率每下降1%對應之健康風險進行分析。首先以我國近年與空氣污染有關之重點死因和疾病作為健康效應指標,利用基於健康影響評估架構建立的空氣品質改善效益評估流程,探討AQI改善對於全國、七大空品區和以性別與年齡別分的族群帶來多少健康效益,並將其量化成貨幣價值,藉以進一步探尋易受空氣污染影響的高風險族群,並檢視空污防制相關政策下,空氣品質改善之淨效益。
研究結果顯示全國總健康效益隨著AQI改善程度越多而增加,自情境1(AQI由普通改善至良好等級)的79.6萬件到情境5(AQI由危害改善至良好等級)的506.7萬件;而將健康效益貨幣化後,具最多全因死亡變化量的情境3(AQI由對所有人不健康改善至良好等級)有最高總貨幣效益約達923,308億元。心腦血管疾病患者、>65歲年長者皆為敏感性族群,需多加注意空氣品質狀態。此外,對於AQI重點改善區域,即高屏空品區的《空氣污染防制計畫》進行成本效益分析後發現,若高雄市與屏東縣每年皆達到AQI不良率改善目標,前者年均淨效益現值為172,400億元,後者則為37,296億元,兩者淨效益現值皆大於零,《空氣污染防制計畫》具經濟可行性。 本研究使用AQI衡量我國空氣品質改善之健康與經濟效益,以期提升大眾對空氣品質的理解和意識,並以更貼近國人健康狀況和更全面的角度提供政府單位空品管理決策參考。 | zh_TW |
dc.description.abstract | Issues related to human health impacts of air quality has been aroused more and more attention throughout the world. In order to improve health protection and tackle air pollution, our government has implemented Air Quality Index (AQI) since December 2016, and formulated policies and plans involved with air quality protection. However, most studies evaluate effectiveness of air quality improvement by decreasing concentration of specific air pollutants, which is difficult for the public to understand. This study considers that people often use AQI to determine air pollution levels in their daily lives. Moreover, air pollution control programs and plans in Taiwan take AQI nonconformance proportion as air quality targets. Accordingly, it aims at using health risks corresponding to each level of AQI and the 1% drop in the AQI nonconformance proportion to analyzes. First of all, we start with regarding the significant causes of death and diseases concerning air pollution in Taiwan in recent years as health indicators. Then, using evaluation process of benefits of air quality improvement based on the framework of health impact assessment, we examine the impact of AQI improvement on all Taiwanese, seven air quality zones, populations by gender and age. Meanwhile, those health benefits are converted into monetary values. Finally, this study explores high-risk groups who is vulnerable to air pollution, and furthermore, investigates the net present value of air quality improvements under air pollution control policies.
The results of the research show that total domestic health benefits increase 1with the degree of AQI improvement, from 0.796 million cases in scenario 1 (AQI improves from moderate category to good category) to 5.067 million cases in scenario 5 (AQI improves from hazardous category to good category). Moreover, after monetizing the health benefits, scenario 3 with greatest change in all-cause mortality (AQI improves from unhealthy category to good category) has the highest total monetary benefit: NT$ 92,330.8 billion. In addition, patients suffering from cardiovascular and cerebrovascular diseases and the elderly over 65 years old are all belong to sensitive groups, who needs to pay more attention to air quality levels. In addition, the results of cost-benefit analysis of Air Pollution Control Plan for the crucial area of AQI improvement: Kao-ping air quality zone indicates that if Kaohsiung City and Pingtung County both reach air quality targets of AQI nonconformance proportion every year, the former’s average annual present value of net benefit is NT$ 17,240 billion, and the latter’s is NT$ 3,729.6 billion. Both present value of net benefits are greater than zero; therefore, Air Pollution Control Plans are economically feasible. To summarize, this study utilizes AQI to measure health and economic benefits of air quality improvements in Taiwan. It anticipates to enhance public understanding and awareness of air quality; besides, to provide government agencies with a more localized, diverse and comprehensive perspective on air quality management in decision-making. | en |
dc.description.provenance | Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-07-31T16:18:26Z No. of bitstreams: 0 | en |
dc.description.provenance | Made available in DSpace on 2023-07-31T16:18:26Z (GMT). No. of bitstreams: 0 | en |
dc.description.tableofcontents | 誌謝 II
摘要 III ABSTRACT IV 圖目錄 IX 表目錄 XI 第ㄧ章 前言 1 1.1 研究背景與動機 1 1.2 研究目的 2 1.3 研究架構 2 第二章 文獻回顧 5 2.1 空氣污染對健康的危害 5 2.2 我國AQI 6 2.3 AQI與人體健康、經濟效益的關係 9 2.3.1 AQI與人體健康的關係 9 2.3.2 AQI與經濟效益的關係 10 2.4 衝擊路徑評估與健康影響評估 10 2.4.1 污染物排放改變導致的污染物濃度變化 12 2.4.2 計算健康事件變化量 13 2.4.3 貨幣化空污減量的健康效益 14 2.5 成本效益分析 16 2.6 空氣品質保護政策 18 2.6.1 空氣污染防制策略 18 2.6.2 空氣污染防制方案 19 2.6.3 空氣污染防制基金 20 第三章 研究方法 21 3.1 研究區域 21 3.2 研究資料 22 3.2.1 AQI 22 3.2.2 空氣污染物 23 3.3 研究方法 24 3.3.1 計算AQI改善之空氣品質變化 27 3.3.2蒐集各健康事件對應的劑量效應函數和其參數 27 3.3.3 計算健康事件變化量 39 3.3.4 貨幣化AQI改善導致的健康效益 42 3.3.5 空氣品質保護策略效益評估 48 第四章 結果與討論 52 4.1 AQI等級之間的改善效益 52 4.1.1 全臺灣的健康事件變化量與貨幣效益 52 4.1.2 各空品區的健康事件變化量與貨幣效益 56 4.1.3 以性別和年齡別分的健康事件變化量與貨幣效益 61 4.2 空氣品質保護策略效益評估 63 4.2.1 重點空品區空品不良率降低1%之效益計算 63 4.2.2 《空氣污染防制策略》與《空氣污染防制計畫》之淨效益現值 66 4.2.3 淨效益現值之敏感度分析 68 第五章 結論與建議 69 5.1 結論 69 5.2 建議 73 第六章 參考資料 75 附錄 89 附錄ㄧ 劑量效應係數(𝛽) 89 附錄二 全臺灣的健康事件變化量與貨幣效益 105 附錄三 空品區的健康事件變化量與貨幣效益 107 附錄四 高雄市與屏東縣空氣品質保護策略效益評估 109 | - |
dc.language.iso | zh_TW | - |
dc.title | 以AQI衡量空氣品質改善的健康與經濟效益 | zh_TW |
dc.title | Using Air Quality Index to Evaluate Health Benefits and Economic Benefits of Air Quality Improvements. | en |
dc.type | Thesis | - |
dc.date.schoolyear | 111-2 | - |
dc.description.degree | 碩士 | - |
dc.contributor.oralexamcommittee | 馬鴻文;丁育頡 | zh_TW |
dc.contributor.oralexamcommittee | Hwong-wen Ma;Yu-Chieh Ting | en |
dc.subject.keyword | 空氣品質指標,健康影響評估,健康效益,貨幣化,成本效益分析, | zh_TW |
dc.subject.keyword | air quality index,health impact assessment,health benefits,monetization,cost-benefit analysis, | en |
dc.relation.page | 109 | - |
dc.identifier.doi | 10.6342/NTU202300715 | - |
dc.rights.note | 同意授權(全球公開) | - |
dc.date.accepted | 2023-04-11 | - |
dc.contributor.author-college | 工學院 | - |
dc.contributor.author-dept | 環境工程學研究所 | - |
顯示於系所單位: | 環境工程學研究所 |
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