English  |  正體中文  |  简体中文  |  Post-Print筆數 : 27 |  Items with full text/Total items : 113656/144643 (79%)
Visitors : 51719529      Online Users : 621
RC Version 6.0 © Powered By DSPACE, MIT. Enhanced by NTU Library IR team.
Scope Tips:
  • please add "double quotation mark" for query phrases to get precise results
  • please goto advance search for comprehansive author search
  • Adv. Search
    HomeLoginUploadHelpAboutAdminister Goto mobile version
    Please use this identifier to cite or link to this item: https://nccur.lib.nccu.edu.tw/handle/140.119/134134


    Title: 養殖漁業與太陽光電設置之綜效、權衡及共效益
    Synergies, trade-offs and co-benefits of aquaculture fishery and solar photovoltaic installation
    Authors: 陳家琳
    Chen, Chia-Lin
    Contributors: 蔡育新
    Tsai, Yu-Shin
    陳家琳
    Chen, Chia-Lin
    Keywords: 太陽光電
    綜效、權衡、共效益
    利害關係人
    Solar photovoltaics
    Synergies, trade-offs, and co-benefits
    Stakeholders
    Date: 2021
    Issue Date: 2021-03-02 14:44:09 (UTC+8)
    Abstract: 太陽能的設置改變原土地使用型態,進而直接或間接的影響當地的經濟、社會、環境等層面。漁電共生是一種新興異業結合的經營模式,是臺灣推行太陽能的新契機,政策屬於初期尚未發展成熟階段,但各地區擁有背景條件不同,加上太陽能板平均使用年限長達二十年,時間與空間兩因子加劇問題的複雜度,牽涉許多不確定性影響因子。由於政策背景的特殊性及推動時程壓力,相關研究、法令修訂仍然趕不上推動的速度,造成執行困難。
    本研究以台灣目前漁電共生推行政策及現況執行情形為研究範圍,透過深度訪談搜集彙整利害關係人對於漁電共生觀點,以土地使用面向切入,據以建立相互作用關係,以綜效、權衡及共效益的概念分析彼此的交互影響關係,釐清相關議題、影響因子、與成效評估面向。政策的推行是一個動態的過程,且涉及利害關係人多元,過利害關係人反饋的影響因子,可以分析預測政策推行可能產生的綜效、權衡與共效益,確保其可行性及永續性是成功的關鍵,並據以作為未來政策推行方向、修訂法令、規劃選址之參考。
    研究結果顯示太陽光電與漁業土地使用之交互影響關係,包括設置過程考量的因子,及產生議題的影響因子,又依不同利害關係人角度及互動而有不一樣的影響結果。以土地使用面向切入,透過彙整分析各受訪者之看法,釐清太陽光電在執行上與漁業土地使用相關聯的面向,將現況發展及相關議題分為土地使用、土地管理、社會經濟等面向。
    Solar photovoltaics installation changes the original land use pattern and directly or indirectly affects the local economy, society, environment, and other aspects. Aquaculture fishery and electricity symbiosis is a new business model of combining different industries, which serves as a new opportunity for Taiwan to promote solar energy. Its policies are in the early stage of development and have not yet matured. While different regions have different background conditions and that the average service life of solar panels is as long as 20 years, time and space factors aggravate the complexity of relevant problems, which involves many uncertain impact factors. Due to the particularity of the policy background and promotion pressure, relevant studies and legislative amendments are still unable to catch up with the promotion speed, resulting in difficulties in implementation.
    Based on the current policies and implementation of aquaculture fishery and electricity symbiosis in Taiwan, this study collects stakeholders` views on the symbiosis through in-depth interviews, establishes interaction relationships with land use, analyzes the interaction relationship with concepts of synergy, trade-off, and co-benefits, and clarifies relevant issues, influencing factors, and effectiveness evaluation aspects. Policy implementation is a dynamic process involving multiple stakeholders. Through the impact factors of the stakeholder feedback, possible synergies, trade-offs, and co-benefits of policy implementation are analyzable and predictable, with ensuring feasibility and sustainability being the key to success, which can be used as a reference for future policy implementation directions, revision of laws, and planning of site selection.
    The results show that the relationship between solar photovoltaics and aquaculture fishery land use, including process setting and issue generating factors, has different impact results according to different stakeholders` perspectives and interactions. From the land-use perspective, this study analyzes the interviewees` perceptions to clarify relevant aspects of solar photovoltaic implementation and aquaculture fishery land use and divides the current development and related issues into land use, land management, and socio-economic aspects.
    Reference: 中文參考文獻
    黃孔良,2018,「再生能源需要大量土地面積,臺灣是否不適合發展再生能源」.
    蔡耀賢、洪百陞、向為民,2019,「不利農業經營之農地發展,太陽能光電廠對環境影響初探」,『農業試驗所技術服務季刊』,120期:16-19。
    經濟部,2016,「太陽光電2年推動計畫」。
    經濟部,2019,「109年太陽光電6.5GW達標計畫」。
    國家發展委員會(國發會),2020,「2019臺灣永續發展目標年度檢討報告」。
    徐嘉信,2020。綠色基礎設施於都市「街區開放空間」對氣候變遷減緩與調適之綜效、權衡與共效益。碩士論文,國立政治大學地政研究所。

    外文參考文獻
    Allen, C., 2011, “German village achieves energy independence... and then some”, Biocycle, 52(4): 37-42.
    Bagdanavičiūtė, I., Umgiesser, G., Vaičiūtė, D., Bresciani, M., Kozlov, I. and Zaiko, A., 2018, “GIS-based multi-criteria site selection for zebra mussel cultivation: Addressing end-of-pipe remediation of a eutrophic coastal lagoon ecosystem”, Science of the Total Environment, 634: 990-1003.
    Bisaga, I., Parikh, P., Tomei, J., & To, L. S., 2020, “Mapping synergies and trade-offs between energy and the sustainable development goals: A case study of off-grid solar energy in Rwanda”, Energy Policy, 112028.
    Brown, G., de Bie, K. and Weber, D., 2015, “Identifying public land stakeholder perspectives for implementing place-based land management”, Landscape and Urban Planning, 139: 1-15.
    Buchholtz, A. K. and A. B. Carroll, 2012, “Business & society: Ethics & stakeholder management”, South-Western Cengage Learning.
    Calvert, K. E., 2018, “Measuring and modelling the land‐use intensity and land requirements of utility‐scale photovoltaic systems in the Canadian province of Ontario”, The Canadian Geographer/Le Géographe canadien, 62(2): 188-199.
    Carroll, A. B., & Buchholtz, A. K., 2014, “Business and society: Ethics, sustainability, and stakeholder management”, Nelson Education.
    Castillo, C. P., e Silva, F. B., & Lavalle, C., 2016, “An assessment of the regional potential for solar power generation in EU-28”, Energy Policy, 88: 86-99.
    Clarkson, M. E., 1995, “A stakeholder framework for analyzing and evaluating corporate social performance”, Academy of management review , 20(1): 92-117.
    Corning, P. A., 1998, “The synergism hypothesis”: On the concept of synergy and its role in the evolution of complex systems”, Journal of social and evolutionary systems, 21(2): 133-172.
    Dapueto, G., Massa, F., Costa, S., Cimoli, L., Olivari, E., Chiantore, M., ... and Povero, P., 2015, “A spatial multi-criteria evaluation for site selection of offshore marine fish farm in the Ligurian Sea, Italy”, Ocean & Coastal Management, 116: 64-77.
    Delfanti, L., Colantoni, A., Recanatesi, F., Bencardino, M., Sateriano, A., Zambon, I. and Salvati, L., 2016, “Solar plants, environmental degradation and local socioeconomic contexts: A case study in a Mediterranean country”, Environmental Impact Assessment Review, 61: 88-93.
    Denholm, P., Kuss, M. and Margolis, R. M., 2013, “Co-benefits of large scale plug-in hybrid electric vehicle and solar PV deployment”, Journal of Power Sources, 236: 350-356.
    Duguma, L.A., Wambugu, S.W., Minang, P.A., van Noordwijk, M, 2014, “Climate change mitigation and adaptation in the land use sector: from complementarity to synergy”, Environmental management, 54 (3), 420-432.
    Emirbayer, M. and J. Goodwin, 1994, “Network analysis, culture, and the problem of agency”, American journal of sociology, 99(6): 1411-1454.
    Fang, H., Li, J. and Song, W., 2018, “Sustainable site selection for photovoltaic power plant: An integrated approach based on prospect theory”, Energy conversion and management, 174: 755-768.
    Fassin, Y., 2009, “The stakeholder model refined”, Journal of business ethics, 84(1): 113-135.
    Frantál, B., Van der Horst, D., Martinát, S., Schmitz, S., Silva, L., Golobic, M. and Roth, M., 2018, “Spatial targeting, synergies and scale: Exploring the criteria of smart practices for siting renewable energy projects”, Energy Policy, 120: 85-93.
    Frate, C. A. and C. Brannstrom, 2017, “Stakeholder subjectivities regarding barriers and drivers to the introduction of utility-scale solar photovoltaic power in Brazil”, Energy Policy, 111: 346-352.
    Freeman, R. E., 1984, “Strategic management: A stakeholder approach”, Pitman, Boston.
    Geng, S., Lin, L., Zhang, L., Liu, X. and Huang, Z., 2020, “Site selection framework of fishing photovoltaic hybrid project under interval-valued intuitionistic fuzzy environment”, Journal of Cleaner Production, 252: 119774.
    Griggs, D., Smith, M. S., Rockström, J., Öhman, M. C., Gaffney, O., Glaser, G., ... and Shyamsundar, P.,2014, “An integrated framework for sustainable development goals”, Ecology and society, 19(4).
    Grippo, M., Hayse, J. W and O’Connor, B. L., 2015, “Solar energy development and aquatic ecosystems in the southwestern United States: potential impacts, mitigation, and research needs”, Environmental Management, 55(1): 244-256.
    Haase, D., Schwarz, N., Strohbach, M., Kroll, F. and Seppelt, R., 2012, “Synergies, trade-offs, and losses of ecosystem services in urban regions: an integrated multiscale framework applied to the Leipzig-Halle Region, Germany”, Ecology and society, 17(3).
    Hernandez, R. R., Hoffacker, M. K., Murphy-Mariscal, M. L., Wu, G. C. and Allen, M. F., 2015, “Solar energy development impacts on land cover change and protected areas”, Proceedings of the National Academy of Sciences, 112(44): 13579-13584.
    Hoogwijk, M. and Graus, W., 2008, “Global potential of renewable energy sources: a literature assessment”, Background report prepared by order of REN21. Ecofys, PECSNL072975.
    Kapetanakis, I. A., Kolokotsa, D. and Maria, E. A., 2014, “Parametric analysis and assessment of the photovoltaics` landscape integration: Technical and legal aspects”, Renewable energy, 67: 207-214.
    Lo, C. C., Wang, C. H. and Huang, C. C., 2013, “The national innovation system in the Taiwanese photovoltaic industry: A multiple stakeholder perspective”, Technological Forecasting and Social Change, 80(5): 893-906.
    Luyet, V., Schlaepfer, R., Parlange, M. B. and Buttler, A., 2012, “A framework to implement stakeholder participation in environmental projects”, Journal of environmental management, 111: 213-219.
    Nerini, F. F., Tomei, J., To, L. S., Bisaga, I., Parikh, P., Black, M., ... and Mulugetta, Y., 2018, “Mapping synergies and trade-offs between energy and the Sustainable Development Goals”, Nature Energy, 3(1): 10-15.
    Nilsson, M., Chisholm, E., Griggs, D., Howden-Chapman, P., McCollum, D., Messerli, P., Neumann, B., Stevance, A., Visbeck, M., and Stafford-Smith, M., 2018, “Mapping interactions between the sustainable development goals: lessons learned and ways forward”, Sustainability Science, 13(6): 1489-1503.
    Mitchell, R. K., Agle, B. R. and Wood, D. J., 1997, “Toward a theory of stakeholder identification and salience: Defining the principle of who and what really counts”, Academy of management review, 22(4): 853-886.
    Mittal, D., Saxena, B. K. and Rao, K. V. S., 2017, “Floating solar photovoltaic systems: An overview and their feasibility at Kota in Rajasthan”, In 2017 International Conference on Circuit, Power and Computing Technologies (ICCPCT) (pp. 1-7). IEEE.
    Ong, S., Campbell, C., Denholm, P., Margolis, R. and Heath, G., 2013, “Land-use requirements for solar power plants in the United States”, National Renewable Energy Lab.(NREL), Golden, CO (United States).
    Pasqualetti, M. J., 2011, “The geography of energy and the wealth of the world”, Taylor & Francis, 971-980.
    Pfitzer, M., Bockstette, V., & Stamp, M., 2013, “Innovating for shared value”, Harvard Business Review, 91(9): 100-107.
    Pimentel Da Silva, G. D., Magrini, A. and Branco, D. A. C., 2020, “A multicriteria proposal for large-scale solar photovoltaic impact assessment”, Impact Assessment and Project Appraisal, 38(1): 3-15.
    Pimentel Da Silva, G. D. and Branco, D. A. C., 2018, “Is floating photovoltaic better than conventional photovoltaic? Assessing environmental impacts”, Impact Assessment and Project Appraisal, 36(5): 390-400.
    Prell, C., Hubacek, K. and Reed, M., 2009, “Stakeholder analysis and social network analysis in natural resource management”, Society and natural resources, 22(6): 501-518.
    Pringle, A. M., Handler, R. M. and Pearce, J. M., 2017, “Aquavoltaics: Synergies for dual use of water area for solar photovoltaic electricity generation and aquaculture”, Renewable and Sustainable Energy Reviews, 80: 572-584.
    Raudsepp-Hearne, C., Peterson, G. D. and Bennett, E. M.,2010, “Ecosystem service bundles for analyzing tradeoffs in diverse landscapes”, Proceedings of the National Academy of Sciences, 107(11): 5242-5247.
    REN21, 2019, “Asia and the Pacific Renewable Energy Status Report (Paris: REN21 Secretariat) ”.
    Rose, T. and Wollert, A, 2015, “The dark side of photovoltaic—3D simulation of glare assessing risk and discomfort”, Environmental Impact Assessment Review, 52, 24-30.
    Sahu, A., Yadav, N. and Sudhakar, K., 2016, “Floating photovoltaic power plant: A review”, Renewable and Sustainable Energy Reviews, 66: 815-824.
    Skevas, T., Hayden, N. J., Swinton, S. M. and Lupi, F., 2016, “Landowner willingness to supply marginal land for bioenergy production”, Land Use Policy, 50: 507-517.
    Stafford-Smith, M., Griggs, D., Gaffney, O., Ullah, F., Reyers, B., Kanie, N., ... and O’Connell, D., 2017, “Integration: the key to implementing the Sustainable Development Goals”, Sustainability Science, 12(6): 911-919.
    Suuronen, A., 2017, “Ecological and social impacts of photovoltaic solar power plants and optimization of their locations in northern Chile”, Jyväskylä studies in biological and environmental science, (338): 17-20.
    Tomscha, S. A. and S. E. Gergel, 2016, “Ecosystem service trade-offs and synergies misunderstood without landscape history”, Ecology and society, 21(1).
    Tsoutsos, T., Frantzeskaki, N. and Gekas, V., 2005, “Environmental impacts from the solar energy technologies”, Energy Policy, 33(3): 289-296.
    Weitz, N., Carlsen, H., Nilsson, M. and Skånberg, K., 2018, “Towards systemic and contextual priority setting for implementing the 2030 Agenda”, Sustainability Science, 13(2): 531-548.
    Yeh, N., Ding, T. J. and Yeh, P., 2015, “Light-emitting diodes׳ light qualities and their corresponding scientific applications”, Renewable and Sustainable Energy Reviews, 51: 55-61.
    Yongphet, P. and D. W. C. Maouche “Guidelines for the Sustainability of Community Energy Management under the Sufficiency Economy Philosophy”, RMUTL , 2(1): 33-48.
    Yue, C.-D. and Huang, G. R., 2011, “An evaluation of domestic solar energy potential in Taiwan incorporating land use analysis”, Energy Policy, 39(12): 7988-8002.
    Yue, C.-D. and Wang, S. S., 2006, “GIS-based evaluation of multifarious local renewable energy sources: a case study of the Chigu area of southwestern Taiwan”, Energy Policy, 34(6): 730-742.
    Zoellner, J., Schweizer-Ries, P. and Wemheuer, C., 2008, “Public acceptance of renewable energies: Results from case studies in Germany”, Energy policy, 36(11): 4136-4141.
    Description: 碩士
    國立政治大學
    地政學系
    107257012
    Source URI: http://thesis.lib.nccu.edu.tw/record/#G0107257012
    Data Type: thesis
    DOI: 10.6814/NCCU202100334
    Appears in Collections:[地政學系] 學位論文

    Files in This Item:

    File Description SizeFormat
    701201.pdf1284KbAdobe PDF20View/Open


    All items in 政大典藏 are protected by copyright, with all rights reserved.


    社群 sharing

    著作權政策宣告 Copyright Announcement
    1.本網站之數位內容為國立政治大學所收錄之機構典藏,無償提供學術研究與公眾教育等公益性使用,惟仍請適度,合理使用本網站之內容,以尊重著作權人之權益。商業上之利用,則請先取得著作權人之授權。
    The digital content of this website is part of National Chengchi University Institutional Repository. It provides free access to academic research and public education for non-commercial use. Please utilize it in a proper and reasonable manner and respect the rights of copyright owners. For commercial use, please obtain authorization from the copyright owner in advance.

    2.本網站之製作,已盡力防止侵害著作權人之權益,如仍發現本網站之數位內容有侵害著作權人權益情事者,請權利人通知本網站維護人員(nccur@nccu.edu.tw),維護人員將立即採取移除該數位著作等補救措施。
    NCCU Institutional Repository is made to protect the interests of copyright owners. If you believe that any material on the website infringes copyright, please contact our staff(nccur@nccu.edu.tw). We will remove the work from the repository and investigate your claim.
    DSpace Software Copyright © 2002-2004  MIT &  Hewlett-Packard  /   Enhanced by   NTU Library IR team Copyright ©   - Feedback