臺灣局地大氣剖面特徵及其對空氣品質的影響

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梁婉琪(Un-Kei Leong) 查詢紙本館藏

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大氣科學學系

論文名稱

臺灣局地大氣剖面特徵及其對空氣品質的影響
(Characteristics of the Vertical Profiles of the Planetary Boundary Layer and its Influence on Air Quality in Taiwan)

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摘要(中)

臺灣在秋季至次年春季時，大氣環流主要受亞洲大陸的反氣旋天氣系統影響。當盛行風受中央山脈地形阻擋，臺灣西半部呈現弱風和沉降現象，常導致空氣污染事件的發生。為探討臺灣行星邊界層（PBL）垂直結構發展特性，及其對大氣污染物傳輸和擴散過程的影響，本研究分析了2015年至2021年冬季板橋、花蓮和馬公三個測站每天早上和晚上八點探空觀測資料，並根據冬季常見天氣型態(1)東北季風、(2)高壓迴流和(3)弱綜觀天氣，分述探空資料垂直結構特性。
根據探空剖面資料的分析結果，臺灣東北季風的平均厚度約為1600m，板橋站由於地形原因冬季主要吹拂東風。花蓮站冬季早上近地表常有輻射逆溫的現象，並且在受東北季風影響的天氣時，風速明顯較強。馬公站受強烈北風影響，低層的位溫和比濕混合良好。在弱綜觀天氣時，板橋站和花蓮站有較顯著的海陸風，臺灣地區冬季的海風大約從早上10時至11時開始，並持續約8至9個小時。
比較聖嬰年、正常年和反聖嬰年時臺灣冬季的垂直探空剖面，在聖嬰年期間臺灣周邊地區的對流層低層有較強的南風，而在反聖嬰年期間臺灣近地層風向偏北，增強東風和北風。當冬季的東風增強時，臺灣背風側的沉降作用增強，更不利於大氣污染物的擴散。另外，北風的增強為臺灣帶來更多的境外污染物，導致較差的空氣品質。

摘要(英)

From autumn to the following spring season, the atmospheric circulation of Taiwan is dominated by the Asian continental anticyclone system. Due to mountain blocking, western Taiwan, often experiences low wind speeds and strong subsidence, leading to serious PM2.5 problems. In addition, the planetary boundary layer (PBL) evolutions strongly affect air pollution dispersions. This study explored the characteristics of PBL through the analysis of daily observed sounding data located in northern Taiwan (Banqiao), eastern Taiwan (Hualien), and western Taiwan (Magong). The analysis was conducted according to different synoptic weather patterns including (1) prevailed by the northeasterly monsoonal flow; (2) under the influence of high-pressure peripheral circulation, and (3) weak synoptic weather conditions.
According to the analysis results of the sounding profiles, the average thickness of the northeast monsoon is about 1600m in Taiwan. Banqiao is obviously affected by easterly winds in the northeast monsoon weather in winter. Hualien has obvious radiation inversion near the surface at 00 UTC in winter and the wind speed is significantly higher in the northeast monsoon weather. Due to the strong northerly wind, the potential temperature and specific humidity of the lower layer in Magong are mixed well. In the weak synoptic weather, Banqiao and Hualien have more obvious sea-land breeze circulation. The winter sea breeze in Taiwan starts from 10:00 to 11:00 in the morning and lasts for 8 to 9 hours.
Comparing the sounding observation profiles of Taiwan during the winter of the El Niño year and the La Niña year. The results show that there is a strong southerly wind in the lower troposphere around Taiwan during the El Niño. During the La Niña, the wind direction of the near-surface layer is more northerly and the location of the continental cold high is more northerly, which makes the easterly and northerly winds stronger.
When the easterly wind is stronger in the winter, the sedimentation effect on the lee side area of Taiwan is enhanced, which is unfavorable for the diffusion of atmospheric pollutants. The strengthening of the northerly wind will bring more foreign pollutants to Taiwan, resulting in poor average air quality.

關鍵字(中)

★ 行星邊界層
★ 探空觀測
★ 空氣品質

關鍵字(英)

★ Planetary boundary layer
★ Sounding observation
★ Air quality

論文目次

目錄
中文摘要 ··············································· i
英文摘要 ··············································· iii
誌謝 ··············································· iv
目錄 ··············································· v
表目錄 ··············································· vi
圖目錄 ··············································· vii
一、緒論··········································· 1
1-1 前言··········································· 1
1-2 文獻回顧········································ 3
1-3 研究動機與目標·································· 5
二、研究方法········································ 7
2-1 資料來源········································ 7
2-2 研究時段········································ 8
2-3 主觀天氣型態分類································ 9
2-4 總體理查遜數···································· 10
三、臺灣冬季地面氣象要素特徵························· 11
3-1 三種天氣型態下地面觀測氣象要素特徵分析············ 11
3-2 小結··········································· 16
四、臺灣冬季大氣垂直剖面特徵························· 18
4-1 三種天氣型態下垂直剖面氣象要素特徵分析············ 19
4-2 東北季風天氣型態下臺灣風場剖面特徵················ 24
4-3 弱綜觀天氣型態下臺灣風場環流特徵·················· 25
4-4 小結··········································· 27
五、臺灣冬季大氣垂直剖面年際變化特徵·················· 29
5-1 臺灣近年冬季氣象特徵年際變化······················ 29
5-2 臺灣以及附近地區大氣環流場變化···················· 30
5-3 臺灣冬季大氣垂直剖面年際變化······················ 35
5-4 小結··········································· 43
六、臺灣冬季空氣品質年際變化特徵······················ 45
6-1 空氣品質指標年際變化····························· 45
6-2 懸浮微粒濃度年際變化···························· 47
6-3 境外移入污染事件年際變化························ 50
6-4 小結··········································· 51
七、結論與展望······································ 53
7-1 結論··········································· 53
7-2 未來展望········································ 54
八、參考文獻········································ 56
附表 ··············································· 62

參考文獻

〔1〕張強：〈大氣邊界層氣象學研究綜述〉，乾旱氣象，21，3，2003，74-78。
〔2〕胡非、洪鍾祥、雷考恩：〈大氣邊界層和大氣環境研究進展〉，大氣科學，27，4，2003，712-728。
〔3〕Roland B. Stull. “An introduction to boundary layer meteorology,” Kluwer Academic Publishers, 1988.
〔4〕Zhao Ming, Miao Man-Qian, Wang Yan-chang. “Boundary layer meteorology course,” Meteorological Press,1991, 257.
〔5〕黃隆明、張台聖：〈混合層高度簡易算法之探討〉，水土保持學報，44，3，231-250。
〔6〕范紹佳、林文實、蘇雄暉、陳小燕、馬淑琴：〈理查遜數Ri在沿海近地層大氣穩定度分類中的應用〉，熱帶氣象學報，15，4，1999，370-375。
〔7〕畢雪岩、劉烽、吳兌：〈幾種大氣穩定度分類標準計算方法的比較分析〉，熱帶氣象學報，4，2005，402-409。
〔8〕李祥余：〈大氣穩定度分類方法及判據比較研究〉，環境與可持續發展，40，6，2015，93-95。
〔9〕Zhang Hongsheng, Zhang Xiaoye, Li Qianhui, Cai Xuhui, Fan Shaojia, Song Yu, Hu Fei, Che Huizheng, Quan Jiannong, Kang Ling, Zhu Tong. “Research progress on estimation of atmospheric boundary layer height,” Acta Meteorologica Sinica, 78, 3, 2020, 522-536.
〔10〕Fang-Yi Cheng, Chia-Hua Hsu. “Long-term variation in PM2.5 concentrations under changing meteorological conditions in Taiwan,” Scientific Report, 9, 2019, 6635.
〔11〕QX/T 123-2011：〈無線電探空資料質量控制〉，氣象出版社，中國氣象局，2011。
〔12〕Jeffrey E. Passner. The atmospheric sounding program: an analysis and forecasting tool for weather hazards on the battlefield, Army Research Laboratory, 1999.
〔13〕Dian J. Seidel, Franz H. Berger, Franz Immler, Michael Sommer. “Reference upper-air observations for climate: rationale, progress, and plans,” Bulletin of the American Meteorological Society, 90, 3, 2009, 361-369.
〔14〕Yanjun Guo, Fuzhong Weng, Guofu Wang, Wenhui Xu. “The long-term trend of upper-air temperature in China derived from microwave sounding data and its comparison with radiosonde observations,” Journal of Climate, 33, 18, 2020, 7875-7895.
〔15〕Petra Seibert, Frank Bryrich, Sven-Erik Gryning, Sylvain Joggre, Alix Rasmussen, Philippe Tercier. “Review and intercomparison of operational methods for the determination of the mixing height,” Atmospheric Environment, 34, 7, 2000, 1001-1027.
〔16〕劉廣英、張儀峰、葉文欽、呂國財：〈臺灣地區垂直向氣象因子量之合成分析與探討〉，大氣科學，13，1986，47-61。
〔17〕洪逸文：〈臺北混合層高度之氣候研究〉，碩士論文，國立臺灣師範大學，1994。
〔18〕彭啟明、林松錦,：〈臺灣北部地區混合層高度的觀測與模擬〉，大氣科學，23，3，1995，311-336。
〔19〕劉說安、顏翔崑、楊之遠：〈臺灣地區逆溫現象型態之研究〉第八屆全國大氣科學學術研討會，2004，485-489。
〔20〕官岱煒：〈臺灣地區大氣探空剖面特徵分析〉，碩士論文，國立臺灣大學， 2005。
〔21〕呂佳穎：〈臺灣環島之大氣邊界層特性〉，碩士論文，國立臺灣大學，2015。
〔22〕Robert H. Stewart. “Introduction to physical oceanography,” Texas A&M University, 2008, 129.
〔23〕Y. Zhang, Z. Gao, D. L, Y. Li, N. Zhang, X. Zhao, J. Chen. “On the computation of planetary boundary-layer height using the bulk Richardson number method,” Geosci. Model Dev., 7, 2014, 2599–2611.
〔24〕Richard Davy. “The climatology of the atmospheric boundary layer in contemporary global climate models,” Journal of Climate, 31, 22, 2018, 9151-9173.
〔25〕Jens Havskov Sørensen, Alix Resmussen. “Method for calculation of atmospheric boundary-layer height used in ETEX dispersion modeling,” Phys. Chem. Earth, 21, 1997, 435-439.
〔26〕Sven-Erik Gryning, Ekaterina Batchvarova. “Marine boundary layer and turbulent fluxes over the Baltic Sea: measurements and modeling,” Boundary-Layer Meteorology, 103, 2002, 29-47.
〔27〕Seirgej Zlitinkevich, Alexander Baklanov. “Calculation of the stable boundary layer in practical applications,” Boundary-Layer Meteorology, 105, 2002, 389-409.
〔28〕Radan Huth, Christoph Beck, Andreas Philipp, Matthias Demuzere, Zbigniew Ustrnul, Monika Cahynová, Jan Kyselý, Ole Einar Tveito. “Classification of atmospheric circulation patterns: recent advances and applications,” Annals of the New York Academy of Sciences, 1146, 1, 2008, 105-152.
〔29〕Gorica Stanojrvic. “The classifications of atmospheric circulation,” Journal of the Geographical Institute Joran Cvijic SASA, 60, 2, 2010, 27-37.
〔30〕Chia-Hua Hsu, Fang-Yi Cheng. “Synoptic weather patterns and associated air pollution in Taiwan,” Aerosol and Air Quality Research, 19, 2019, 1139-1151.
〔31〕中央氣象局：《中華民國109年氣候資料年報第二部分—高空資料》，臺北市：交通部中央氣象局，2021。
〔32〕Vaisala. “Vaisala radiosonde RS41-SG technical data,” 2017, www.vaisala.com.
〔33〕National Oceanic and Atmospheric Administration National Weather Service Climate Prediction Center, El Nino / La Nina episodes, www.nws.noaa.gov.
〔34〕許竣傑：〈1999年與2000年二月臺灣地區異常降水之分析探討〉，碩士論文，國立中央大學，2001。
〔35〕吳定澄、李忠潘：〈聖嬰-南方振盪現象對臺灣氣溫及雨量之影響〉，第36屆海洋工程研討會，國立交通大學，2014，471-476。
〔36〕D. Vickers, L. Mahrt. “Evaluating formulations of stable boundary layer height,” Journal of Applied Meteorology and Climatology, 43, 11, 2004, 1736-1749.
〔37〕Richard Davy. “The climatology of the atmospheric boundary layer in contemporary global climate models,” Journal of Climate, 31, 22, 2018, 9151-9173.
〔38〕肖之盛、孟凡、徐峻、何友江、趙妤希、于揚、張博雄：〈低空急流理論及其對空氣污染物傳輸影響研究進展〉，環境工程技術學報，9，2，2019，111-119。
〔39〕Shiu-Yu Chang, Guor-Cheng Fang, Charles C. K. Chou, Wei-Nai Chen. “Chemical compositions and radiative properties of dust and anthropogenic air masses study in Taipei Basin,” Atmospheric Environment, 40, 40, 2006, 7796-7809.
〔40〕Li-Wei Lai. “Fine particulate matter events associated with synoptic weather patterns, long-range transport path and mixing height in the Taipei Basin, Taiwan,” Atmospheric Environment, 113, 2015, 50-62.
〔41〕吳政忠、呂芳川、陳文定、鄭竹齋、莊漢明：〈東北季風時期臺灣海峽強風成因之研究〉，天氣分析與預報研討會，交通部中央氣象局，臺北市，2004，178-182。
〔42〕吳政忠、呂芳川、陳文定、趙尊憲、莊漢明：〈冬季臺灣附近海域強風預報研究〉，氣象學報，46，2，2005，29-43。
〔43〕簡芳菁、林勝峰：〈冬季冷鋒個案之數值研究〉，大氣科學，32，2，2004，141-160。
〔44〕吳政忠、毛正氣：〈臺灣海峽冬季強風特性與預報〉，海軍學術雙月刊，44，3，2010，107-118。
〔45〕廖杞昌、呂芳川、陳文定、朱昌敏：〈寒潮爆發期間局部環流受地形影響之研究〉，天氣分析與預報研討會，交通部中央氣象局，臺北市，2005，184-189。
〔46〕陶家瑞、蘇義雄：〈冬季臺灣及其附近大氣邊界層之研究〉，氣象預報與分析，116，1988，21-31。
〔47〕蔡清彥：〈臺灣北部地區局部環流之研究〉，大氣科學，15，2，1987，179-198。
〔48〕廖慶堂、徐如娟、林受勳、陳志弘、黃茂信、衛紀淮、何良勝：《103年臺灣國內商港海域海氣象觀測分析研究》，臺北市：交通部運輸研究所，2015。
〔49〕湯舜然：〈臺灣地區海陸風之基本特性〉，碩士論文，國立臺灣大學，1999。
〔50〕王世宇：〈臺灣地區海陸風與大尺度環流關係之研究〉，碩士論文，國立中央大學，2000。
〔51〕張憲國、何良勝、張高瑋、衛紀淮：〈臺北港海陸風的轉向特性及風速與波浪的關係探討〉，第36屆海洋工程研討會，國立交通大學，2014，673-678。
〔52〕交通部中央氣象局：《中央氣象局108年氣候年報》，臺北，交通部中央氣象局，2020。
〔53〕交通部中央氣象局：《中央氣象局109年氣候年報》，臺北，交通部中央氣象局，2021。
〔54〕交通部中央氣象局：《氣候監測報告》，臺北，交通部中央氣象局，2021。
〔55〕韓榮青、石柳、袁媛：〈2020/2021年冬季中國氣候冷暖轉折成因分析〉，氣象，47，7，2021，880-892。
〔56〕Chuan-Yao Lin, Shaw Chen Liu, Charles C.-K. Chou, Tsun Hsien Liu, Chung-Te Lee, Chung-Shin Yuan, Chen-Jung Shiu, Chea-Yuan Young. “Long-range transport of Asian dust and air pollutants to Taiwan,” TAO, 15, 5, 2004, 759-784.
〔57〕行政院環境保護署，空氣品質監測網-空氣品質指標，https://airtw.epa.gov.tw/CHT/Information/Standard/AirQualityIndicator.aspx.
〔58〕Carsten Junker, Jia-Lin Wang, Chung-Te Lee. “Evaluation of the effect of long-range transport of air pollutants on coastal atmospheric monitoring sites in and around Taiwan,” Atmospheric Environment, 43, 21, 2009, 3374-3384.
〔59〕I-Chien Lai, Peter Briblecombe. “Long-range transport of air pollutants to Taiwan during the COVID-19 lockdown in Hubei province,” Aerosol Air Qual. Res, 21, 2021, 200392.
〔60〕Stephen Miles Griffith, Wei-Syun Huang, Chia-Ching Lin, Ying-Chieh Chen, Kou-En Chang, Tang-Huang Lin, Sheng-Hsiang Wang, Neng-Huei Lin. “Long-range air pollution transport in East Asia during the first week of the COVID-19 lockdown in China,” Sci Total Environ, 741, 2020, 140214.

指導教授

鄭芳怡(Fang-Yi Cheng)

審核日期

2022-6-21

推文