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Criteria of a good research field. Intellectually challenging Significant contributions to the society Provides jobs. Atmospheric Chemistry as a Good Research Field. Air Pollution Ozone Aerosols Climate Changes Greenhouse gases Aerosols -----------------
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Criteria of a good research field • Intellectually challenging • Significant contributions to the society • Provides jobs
Atmospheric Chemistry as a Good Research Field • Air Pollution • Ozone • Aerosols • Climate Changes • Greenhouse gases • Aerosols ----------------- Both subjects above provide good jobs, are tremendously important to the society, and have numerous challenging problems left.
Atmospheric Chemistry: The Driving Force of Life • Nearly all energy of the biota comes from the oxidation of carbohydrates CH2O + O2 -> CO2 + H2O • This energy cycle is closed by the photosynthesis CO2 + H2O + h -> CH2O + O2 (The ultimate energy source is the mighty sun!) • In turn, the biota control key processes of atmospheric chemistry, e.g. O2 abundance, C-cycle, N-cycle, etc.
行政院環境保護署九十一年度專案計畫 台灣地區臭氧與懸浮微粒預報模式建立及生成與傳輸機制分析 計畫主持人:劉紹臣 共同主持人:李崇德、鄭曼婷、吳義林、袁中新、陳瑞仁、林博雄協同主持人:周崇光、龍世俊、許世傑、林傳堯、張志忠
台灣地區臭氧與懸浮微粒預報模式建立及生成與傳輸機制分析台灣地區臭氧與懸浮微粒預報模式建立及生成與傳輸機制分析 計畫目標 1. 發展台灣地區區域性臭氧及懸浮微粒預報模式 2. 透過觀測實驗,瞭解台灣地區臭氧及懸浮微粒生成與 分佈的機制(包括區域性產生源及長程傳輸因素)
台灣地區臭氧與懸浮微粒預報模式建立及生成與傳輸機制分析台灣地區臭氧與懸浮微粒預報模式建立及生成與傳輸機制分析 工作方法及成果 • 現有資料之分析 • 模式模擬 • 觀測實驗
1998年各國環境負荷比較(超過一千萬人口國家)1998年各國環境負荷比較(超過一千萬人口國家) 各國 環境負荷 人口密度 (人/ km2) 工廠密度 (工廠數/ km2) 車輛密度 (車輛數/ km2) 能源消耗 (噸油當量/ km2) 台灣 607 2.74 442 2,047 日本 334 1.14 219 1,340 德國 230 0.12 126 953 英國 238 0.06 102 230 美國 27 0.04 21 219 台灣/各國 1.8~22倍 2.4~68.5倍 2~21倍 1.5~9.3倍 台灣 世界排名 2 1 1 1
台灣氣膠化學觀測網 (SINCE 2002) • 焦點議題 • 亞洲沙塵對台灣地區空氣品質之影響程度與範圍 • 污染物長程輸送對台灣地區空氣品質之影響 • 二次氣膠之生成與空間分佈 • 觀測項目 • 氣膠質量濃度 (PM2.5&PM10) • 氣膠質量粒徑分佈(PM10) • 氣膠化學組成(PM2.5 & PM10) • 有機碳及元素碳(OC/EC) • 地殼元素 • 重金屬元素 • 水溶性離子 • 太陽輻射量及氣膠光學厚度(台北&台南) • 揮發性有機物(VOCs)
2002 Autumn MeasurementPM10 Compositions [PM10=44.9mg/m3] [PM10=57.4mg/m3] [PM10=48.6mg/m3] [PM10=34.8mg/m3] [PM10=43.6mg/m3]
An analysis of the Distributions of Aerosols and Air Pollutants during Dust-Storm Period over Northern Taiwan Local pollution Front passed: • Dust storm • Long range transport • Clean Data: 1999/11~2000/05 2000/11~2001/05
Local pollution: Met. Data: wind , TM, pollutants: CO, SO2, O3, (NOx+O3), PM10
Front Passed: Dust-storm case Met. Data: wind, rain, Tm pollutants: PM10, (O3+NOx), O3, CO, SO2
Front Passed but Clean: Met. Data: wind, rain, Tm pollutants: PM10, (O3+NOx), O3, CO, SO2
LP DS FP FC M 1999/11 25 0 1 0 4 1999/12 21 0 2 5 3 2000/01 17 0 5 9 0 2000/02 13 3 0 13 0 2000/03 25 3 0 3 0 2000/04 22 3 0 5 0 2000/05 29 1 0 1 0 2000/11 18 0 0 11 1 2000/12 17 0 0 11 3 2001/01 25 2 0 4 0 2001/02 19 2 0 7 0 2001/03 26 2 0 3 0 2001/04 25 3 0 2 0 2001/05 23 1 0 5 2 Total(days) 305 20 8 79 13 % 71.7 4.7 1.9 18.6 3.1 Average (ug/m3) 47.4 127.6 85 32.8
PM10 (ug/m3) (30) CO (ppm) (0.25) SO2 (ppb) (0.5) NOX (ppb) (0.2) NO2+O3 (ppb) (40) ST03 (Wan-li) 49.4 (61%) 0.3 (77%) 1.2 (42%) 8.1 (2.47%) 48.5 (82.5%) ST10 (Tan-shui) 42.0 (71%) 0.6 (38%) 1.9 (26%) 21.1 (0.95%) 51.1 (78.3%) ST19 (Guan-in) 52.0 (58%) 0.3 (77%) 5.2 (10%) 17.8 (1.12%) 52.2 (76.6%) ST27 (San-i) 53.5 (56%) 0.4 (58%) 1.6 (31%) 21.0 (0.95%) 47.2 (84.7%) ST41 (Tai-se) 65.7 (53%) 0.4 (58%) 2.8 (18%) 14.4 (1.39%) 47.4 (84.4%) ST61 (Heng-chun) 31.9 (94%) 0.3 (77%) 0.3 (167%) 1.4 (14.29%) 38.2 (104.7%) ST62 (Tai-tung) 34.9 (86%) 0.5 (46%) 0.5 (100%) 11.8 (1.69%) 39.9 (100.3%)
ST63 (Hua-lien) 36.9 (81%) 0.7 (33%) 0.6 (83%) 21.4 (0.93%) 42.2 (94.8%) ST64 (Yang-ming) 20.7 (145%) 0.3 (77%) 1.2 (42%) 4.0 (5%) 47.2 (84.7%) ST65 (I-Lan) 35.6 (84%) 0.5 (46%) 1.1 (45%) 15.7 (1.27%) 44.3 (90.3%) ST14 (Ku-tin) Taipei 48.3 (62%) 0.9 (26%) 3.0 (17%) 47.4 (0.42%) 68.8 (58.1%) ST24 (Shin-chu) 51.3 (58%) 0.7 (33%) 4.3 (12%) 31.9 (0.63%) 55.4 (72.2%) ST31 (Tai-chung) 73.1 (41%) 1.0 (23%) 3.5 (14%) 48.9 (0.41%) 70.5 (56.7%) ST42 (Cha-i) 95.6 (31%) 0.8 (29%) 4.7 (11%) 42.4 (0.47%) 61.5 (65%) ST46 (Tai-nan) 93.6 (32%) 0.9 (26%) 5.0 (10%) 34.1 (0.59%) 55.7 (71.8%) ST53 (Nan-tze) Kaohsiung 91.9 (33%) 0.6 (38%) 4.7 (11%) 37.0 (0.54%) 64 (62.5%)
台灣日照時數之長期變化,1970年以後約減少15%,可能是由於氣膠汙染物對雲的影响。台灣日照時數之長期變化,1970年以後約減少15%,可能是由於氣膠汙染物對雲的影响。
Figure 8. Average daily minimum temperature in Taiwan (bottom panel), average daily maximum temperature in Taiwan (middle panel), average diurnal temperature range in Taiwan (top panel).
Figure 1. Landsat IR image of Taichung city and vicinity. (25 km X 25 km) (From CSRSR, NCU)
積雨雲 午後雷陣雨 海風 圖6. 海陸風環流示意圖
A Core Project of the International Geosphere-Biosphere Programme (IGBP) In Cooperation with the IAMAS Commission on Atmospheric Chemistry and Global Pollution (CACGP)
Defining IGAC's ScientificDirections for the Next Decade Initial Scientific Questions: • What is the role of atmospheric chemistry in amplifying or damping global change? • Within the Earth System, what effects do changing regional emissions and depositions, long-range transport, and transformations have on tropospheric chemical composition and air quality?
International Project Offices 1. US Core Project Office Co-Chair: Tim Bates, NOAA 2. Taipei Core Project Office Co-Chair: Shaw Liu, Academia Sinica 3. European Core Project Office Co-Chair: Sandro Fuzzi, Italy
Defining IGAC's ScientificDirections for the Next Decade What is the role of atmospheric chemistry in amplifying or damping global change? • What are the relative roles of stratosphere-troposphere exchange, anthropogenic and natural precursor emissions, and in situ photochemical processes in controlling O3 and its effect on global change? • What are the sources, sinks, distributions and properties of aerosols and their direct radiative effects on climate? • What are the effects of aerosols on clouds, precipitation, and regional hydrological cycles? • How will changing emissions and depositions of gases affect spatial patterns of climate forcing?
Defining IGAC's ScientificDirections for the Next Decade Scientific Objectives: • To accurately determine global distributions of both short and long lived chemical species in the atmosphere and to document their changing concentrations over time. • To provide a fundamental understanding of the processes that control the distributions of chemical species in the atmosphere and their impact on global change and air quality. • To improve our ability to predict the chemical composition of the atmosphere over the coming decades by integrating our understanding of atmospheric processes with the response and feedbacks of the Earth System.
Defining IGAC's ScientificDirections for the Next Decade • What is the role of atmospheric chemistry in amplifying or damping global change?
Transport of Asian Pollution across Pacific Clearly Observed Carbon monoxide is a medium-lived pollutant Asian plumes as concentrated as polluted rural U.S. ITCT measurements off the coast of California, David Parrish, NOAA/AL