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研究生: 黃冠中
Huang, Guan-Zhong
論文名稱: 鹿角坑溪與馬槽溪匯流後的離子濃度調節作用
Regulation of ion concentrations in the confluence of Lujiaokeng and Macao Stream
指導教授: 林登秋
Lin, Teng-Chiu
學位類別: 碩士
Master
系所名稱: 生命科學系
Department of Life Science
論文出版年: 2018
畢業學年度: 106
語文別: 英文
論文頁數: 52
中文關鍵詞: 陽明山溫泉溪流酸化離子濃度調節
英文關鍵詞: stream, acidification, ion concentration
DOI URL: http://doi.org/10.6345/THE.NTNU.SLS.007.2018.D01
論文種類: 學術論文
相關次數: 點閱:121下載:5
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酸化對生態系及人類社會帶來許多負面影響,是環境變遷的研究的重要議題之一。人為活動引起的酸化受到廣泛的研究與探討,並逐漸受到控制,然而對生態系統同樣有重要影響的天然的酸化卻較少受到關注。陽明山國家公園的馬槽溪深受火山地質影響而含有高濃度的各種離子,水質高度酸化,但與鹿角坑溪匯流後有明顯改善的現象。前人研究指出,稀釋與沉澱作用是降低離子濃度的主要調節機制,這兩種調節機制在水資源管理上的意涵有很大差異,但少有研究觸及。本研究藉由溪、雨水的成份分析與流量模擬來估算兩溪與匯流後的離子輸出量,利用流量差異推估稀釋作用的效果、輸出量的差異推算各種離子的沉澱量,推導沉澱作用的效果,並探討雨量對兩作用的影響。結果顯示稀釋作用對降低離子濃度的效果為63.7 ± 1.1%,沉澱作用的效果則隨離子種類而不同。雨量是影響兩種作用效果的主要因子,能有效增進兩作用的效果並降低離子濃度、改善水質。大豪雨雖會降低離子濃度但亦會大幅增加離子輸出量及混濁程度,對水質改善並無持續性的作用。乾旱不僅減弱稀釋的效果,也使溪流水更酸而增加鋁的溶解度。氣候變遷的影響使降雨的集中度有增加的趨勢,可能會增加豪雨及乾旱事件的發生而使兩溪匯流後的調節功能降低。

Environmental acidification is a critical issue in global change due to its negative effects on social-ecologiacal systems. Anthropogenic acidification has been extensively studied and gradually under control in many parts of the world. However, natural acidification has received much less attention although it also has major effects on ecosystems. The Macao Stream in the volcanic Yangmingshan National Park has high concentration of many metal ions due to volcanic influences. After merging with the Lujiaokeng Stream, the metal ion concentrations are likely regulated through precipitation and dilution. We investigated the relatively contributions of the two processes on reducing ion concentrations by estimating ion flux and streamflow in the two streams and their confluence. The results indicate that dilution accounts for 63.7 ± 1.1% of the reduction of ion concentrations while the effect of precipitation varies among ions. Although rainfall can improve the effects of dilution and precipitation, extreme rainfall events do not contribute to improve water because the flood can lead to high turbidity in the stream. Droughts not only reduced the dilution effect but also limited precipitation because stream water during low flow periods were more acidic, which increases solubility of metal ions. The projected increases in the frequency of torrential rain and drought events will have negative effects on the regulation of ion concentrations in the acidic stream water.

圖次.....................3 表次.....................4 摘要.....................5 Abstract.....................6 Introduction.....................7 Materials and methods.....................10 Results.....................17 Discussions.....................20 Appendix.....................43 References.....................47

Ardia, D., K. Boudt, P. Carl, K. M. Mullen, and B. G. Peterson. 2011. Differential evolution with DEoptim. R Journal 3:27-34.
Asta, M. P., C. Ayora, G. Román-Ross, J. Cama, P. Acero, A. G. Gault, J. M. Charnock, and F. Bardelli. 2010. Natural attenuation of arsenic in the Tinto Santa Rosa acid stream (Iberian Pyritic Belt, SW Spain): the role of iron precipitates. Chemical Geology 271:1-12.
Baker, J., J. Van Sickle, C. Gagen, D. DeWalle, W. Sharpe, R. Carline, B. Baldigo, P. Murdoch, D. Bath, and W. Krester. 1996. Episodic acidification of small streams in the northeastern United States: Effects on fish populations. Ecological Applications 6:422-437.
Battaglia, M., G. Hose, E. Turak, and B. Warden. 2005. Depauperate macroinvertebrates in a mine affected stream: clean water may be the key to recovery. Environmental Pollution 138:132-141.
Bergström, S. 1992. The HBV model: Its structure and applications. Swedish Meteorological and Hydrological Institute, Norrköping, Sweden.
Bergström, S., and A. Forsman. 1973. Development of a conceptual deterministic rainfall-runoff model. Hydrology Research 4:147-170.
Bergstrom, S. 1976. Development and application of a conceptual runoff model for Scandinavian catchments. Series A, No. 52, Lund Institute of Technology, University of Lund, Lund, Sweden.
Bigham, J., U. Schwertmann, S. Traina, R. Winland, and M. Wolf. 1996. Schwertmannite and the chemical modeling of iron in acid sulfate waters. Geochimica et Cosmochimica Acta 60:2111-2121.
Bouchard, A. 1997. Recent lake acidification and recovery trends in southern Quebec, Canada. Water, Air, and Soil Pollution 94:225-245.
Brady, K., J. Bigham, W. Jaynes, and T. Logan. 1986. Influence of sulfate on Fe-oxide formation: Comparisons with a stream receiving acid mine drainage. Clays and Clay minerals 34:266-274.
Chang, K.-H., F.-T. Jeng, Y.-L. Tsai, and P.-L. Lin. 2000. Modeling of long-range transport on Taiwan's acid deposition under different weather conditions. Atmospheric Environment 34:3281-3295.
Chen, C. J., and W. T. Jiang. 2012. Influence of waterfall aeration and seasonal temperature variation on the iron and arsenic attenuation rates in an acid mine drainage system. Applied geochemistry 27:1966-1978.
Cheng, K., H. Hsu, M. Tsai, K. Chang, and R. Lee. 2004. Test and analysis of trend existence in rainfall data. Proceedings of Asia pacific association of hydrology and water resources:5-8.
Cronan, C. S., R. April, R. J. Bartlett, P. R. Bloom, C. T. Driscoll, S. A. Gherini, G. S. Henderson, J. Joslin, J. Kelly, and R. A. Parnell. 1989. Aluminum toxicity in forests exposed to acidic deposition: the ALBIOS results. Water, Air, and Soil Pollution 48:181-192.
Da Silva, E. F., C. Patinha, P. Reis, E. C. Fonseca, J. Matos, J. Barrosinho, and J. S. Oliveira. 2006. Interaction of acid mine drainage with waters and sediments at the Corona stream, Lousal mine (Iberian Pyrite Belt, Southern Portugal). Environmental Geology 50:1001-1013.
DeNicola, D. M., and M. G. Stapleton. 2002. Impact of acid mine drainage on benthic communities in streams: the relative roles of substratum vs. aqueous effects. Environmental Pollution 119:303-315.
Dey, S., S. Kharbuli, R. Chakraborty, S. Bhattacharyya, and U. Goswami. 2009. Toxic effect of environmental acid‐stress on the sperm of a hill‐stream fish Devario aequipinnatus: A scanning electron microscopic evaluation. Microscopy Research and Technique 72:76-78.
Driscoll, C. T., K. M. Driscoll, M. J. Mitchell, and D. J. Raynal. 2003. Effects of acidic deposition on forest and aquatic ecosystems in New York State. Environmental Pollution 123:327-336.
Driscoll, C. T., G. B. Lawrence, A. J. Bulger, T. J. Butler, C. S. Cronan, C. Eagar, K. F. Lambert, G. E. Likens, J. L. Stoddard, and K. C. Weathers. 2001. Acidic Deposition in the Northeastern United States: Sources and Inputs, Ecosystem Effects, and Management Strategies: The effects of acidic deposition in the northeastern United States include the acidification of soil and water, which stresses terrestrial and aquatic biota. BioScience 51:180-198.
Ezoe, Y., C. H. Lin, M. Noto, Y. Watanabe, and K. Yoshimura. 2002. Evolution of water chemistry in natural acidic environments in Yangmingshan, Taiwan. Journal of Environmental Monitoring 4:533-540.
Haynes, R., and R. Swift. 1986. Effects of soil acidification and subsequent leaching on levels of extractable nutrients in a soil. Plant and Soil 95:327-336.
He, Z., A. Alva, D. Calvert, Y. Li, and D. Banks. 1999. Effects of nitrogen fertilization of grapefruit trees on soil acidification and nutrient availability in a Riviera fine sand. Plant and Soil 206:11-19.
Herrmann, J., and K. Frick. 1995. Do stream invertebrates accumulate aluminium at low pH conditions? Water, Air, and Soil Pollution 85:407-412.
Hogsden, K. L., and J. S. Harding. 2011. Consequences of acid mine drainage for the structure and function of benthic stream communities: a review. Freshwater Science 31:108-120.
Hsu, P. c., T. Li, J. J. Luo, H. Murakami, A. Kitoh, and M. Zhao. 2012. Increase of global monsoon area and precipitation under global warming: A robust signal? Geophysical Research Letters 39:L06701.
Hsu, S. C., S. C. Liu, Y. T. Huang, C. C. Chou, S. Lung, T. H. Liu, J. Y. Tu, and F. Tsai. 2009. Long‐range southeastward transport of Asian biosmoke pollution: Signature detected by aerosol potassium in northern Taiwan. Journal of Geophysical Research: Atmospheres 114:D14301.
Jeffries, D. S., T. A. Clair, S. Couture, P. J. Dillon, J. Dupont, W. Keller, D. K. McNicol, M. A. Turner, R. Vet, and R. Weeber. 2003. Assessing the recovery of lakes in southeastern Canada from the effects of acidic deposition. AMBIO 32:176-182.
Keller, W., J. H. Heneberry, and S. S. Dixit. 2003. Decreased acid deposition and the chemical recovery of Killarney, Ontario, lakes. AMBIO 32:183-189.
Kim, J., S.-Y. Koo, J.-Y. Kim, E.-H. Lee, S.-D. Lee, K.-S. Ko, D.-C. Ko, and K.-S. Cho. 2009. Influence of acid mine drainage on microbial communities in stream and groundwater samples at Guryong Mine, South Korea. Environmental Geology 58:1567-1574.
Kopáček, J., J. Hejzlar, P. Krám, F. Oulehle, and M. Posch. 2016. Effect of industrial dust on precipitation chemistry in the Czech Republic (Central Europe) from 1850 to 2013. Water Research 103:30-37.
Kuklinska, K., L. Wolska, and J. Namiesnik. 2015. Air quality policy in the US and the EU–a review. Atmospheric Pollution Research 6:129-137.
Löhr, A., T. Bogaard, A. Heikens, M. Hendriks, S. Sumarti, M. Van Bergen, K. C. Van Gestel, N. Van Straalen, P. Vroon, and B. Widianarko. 2005. Natural Pollution Caused by the Extremely Acid Crater Lake Kawah Ijen, East Java, Indonesia. Environmental Science and Pollution Research 12:89-95.
Lee, G., J. M. Bigham, and G. Faure. 2002. Removal of trace metals by coprecipitation with Fe, Al and Mn from natural waters contaminated with acid mine drainage in the Ducktown Mining District, Tennessee. Applied geochemistry 17:569-581.
Lee, H.-F. 2004. Compositions of fumarolic gases and the H-O isotopic ratios of the condensed water in Tatun Volcanic area, North Taiwan. Unpublished master’s thesis, Department of Geosciences, National Taiwan university, Taiwan (ROC):1-83.
Likens, G. E., C. T. Driscoll, and D. C. Buso. 1996. Long-term effects of acid rain: response and recovery of a forest ecosystem. Science 272:244-246.
Lin, C.-Y., S. C. Liu, C. C.-K. Chou, S.-J. Huang, C.-M. Liu, C.-H. Kuo, and C.-Y. Young. 2005. Long-range transport of aerosols and their impact on the air quality of Taiwan. Atmospheric Environment 39:6066-6076.
Lin, C.-Y., Z. Wang, W.-N. Chen, S.-Y. Chang, C. C. Chou, N. Sugimoto, and X. Zhao. 2007. Long-range transport of Asian dust and air pollutants to Taiwan: observed evidence and model simulation. Atmospheric Chemistry and Physics 7:423-434.
Makungo, R., J. Odiyo, J. Ndiritu, and B. Mwaka. 2010. Rainfall–runoff modelling approach for ungauged catchments: A case study of Nzhelele River sub-quaternary catchment. Physics and Chemistry of the Earth, Parts A/B/C 35:596-607.
McKnight, D. M., and G. L. Feder. 1984. The ecological effect of acid conditions and precipitation of hydrous metal oxides in a Rocky Mountain stream. Hydrobiologia 119:129-138.
Moatar, F., and M. Meybeck. 2005. Compared performances of different algorithms for estimating annual nutrient loads discharged by the eutrophic River Loire. Hydrological processes 19:429-444.
Munk, L., and G. Faure. 2004. Effects of pH fluctuations on potentially toxic metals in the water and sediment of the Dillon Reservoir, Summit County, Colorado. Applied geochemistry 19:1065-1074.
Munk, L., G. Faure, D. E. Pride, and J. M. Bigham. 2002. Sorption of trace metals to an aluminum precipitate in a stream receiving acid rock-drainage; Snake River, Summit County, Colorado. Applied geochemistry 17:421-430.
Neal, C. 1988. Aluminium solubility relationships in acid waters—A practical example of the need for a radical reappraisal. Journal of Hydrology 104:141-159.
Nordstrom, D. K., and J. W. Ball. 1986. The geochemical behavior of aluminum in acidified surface waters. Science 232:54-56.
Novotny, E. V., and H. G. Stefan. 2007. Stream flow in Minnesota: indicator of climate change. Journal of Hydrology 334:319-333.
Parajka, J., R. Merz, and G. Blöschl. 2007. Uncertainty and multiple objective calibration in regional water balance modelling: case study in 320 Austrian catchments. Hydrological processes 21:435-446.
Parnell, R. A., and K. J. Burke. 1990. Impacts of acid emissions from Nevado del Ruiz volcano, Colombia, on selected terrestrial and aquatic ecosystems. Journal of Volcanology and Geothermal Research 42:69-88.
Ravengai, S., D. Love, I. Love, B. Gratwicke, O. Mandingaisa, and R. Owen. 2005. Impact of Iron Duke Pyrite Mine on water chemistry and aquatic life–Mazowe valley, Zimbabwe. Water SA 31:219-228.
Razavi, T., and P. Coulibaly. 2012. Streamflow prediction in ungauged basins: review of regionalization methods. Journal of hydrologic engineering 18:958-975.
Sarmiento, A. M., M. A. Caraballo, D. Sanchez-Rodas, J. M. Nieto, and A. Parviainen. 2012. Dissolved and particulate metals and arsenic species mobility along a stream affected by Acid Mine Drainage in the Iberian Pyrite Belt (SW Spain). Applied geochemistry 27:1944-1952.
Seibert, J. 2000. Multi-criteria calibration of a conceptual runoff model using a genetic algorithm. Hydrology and Earth System Sciences 4:215-224.
Sheoran, A., and V. Sheoran. 2006. Heavy metal removal mechanism of acid mine drainage in wetlands: a critical review. Minerals Engineering 19:105-116.
Song, S. R., and S. M. Chiu. 2005. Reports of spring resources survey in Yangmingshan National Park. Department of Yangmingshan National Park:1-130.
Sriwana, T., M. Van Bergen, S. Sumarti, J. De Hoog, B. Van Os, R. Wahyuningsih, and M. Dam. 1998. Volcanogenic pollution by acid water discharges along Ciwidey River, West Java (Indonesia). Journal of Geochemical Exploration 62:161-182.
Stoddard, J. L., D. Jeffries, A. Lükewille, T. Clair, P. Dillon, C. Driscoll, M. Forsius, M. Johannessen, J. Kahl, and J. Kellogg. 1999. Regional trends in aquatic recovery from acidification in North America and Europe. Nature 401:575.
Storn, R., and K. Price. 1997. Differential evolution–a simple and efficient heuristic for global optimization over continuous spaces. Journal of global optimization 11:341-359.
Sun, W., H. Ishidaira, S. Bastola, and J. Yu. 2015. Estimating daily time series of streamflow using hydrological model calibrated based on satellite observations of river water surface width: Toward real world applications. Environmental research 139:36-45.
Tipping, E., C. Rey-Castro, S. E. Bryan, and J. Hamilton-Taylor. 2002. Al (III) and Fe (III) binding by humic substances in freshwaters, and implications for trace metal speciation. Geochimica et Cosmochimica Acta 66:3211-3224.
Tomlinson, G. H. 2003. Acidic deposition, nutrient leaching and forest growth. Biogeochemistry 65:51-81.
Trenberth, K. E. 2011. Changes in precipitation with climate change. Climate Research 47:123-138.
Yu, P.-S., T.-C. Yang, and C.-C. Kuo. 2006. Evaluating long-term trends in annual and seasonal precipitation in Taiwan. Water Resources Management 20:1007-1023.
Yu, P. S., and Y. C. Wang. 2009. Impact of climate change on hydrological processes over a basin scale in northern Taiwan. Hydrological processes 23:3556-3568.
Zhang, Q., V. P. Singh, P. Sun, X. Chen, Z. Zhang, and J. Li. 2011. Precipitation and streamflow changes in China: changing patterns, causes and implications. Journal of Hydrology 410:204-216.

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