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題名	台灣微藻固碳科技創新發展研究-以科技創新系統與創新生態系統觀點 Exploring the Technological Innovation of Microalgae-based Carbon Capture in Taiwan: Perspectives from Technological Innovation System and Innovation Ecosystem
作者	曾鈺婷 Tseng, Yu-Ting
貢獻者	柯玉佳 Ko, Yu-Chia 曾鈺婷 Tseng, Yu-Ting
關鍵詞	科技創新系統創新生態系統微藻固碳與固碳後再利用 Technological innovation system Innovation ecosystem Microalgae carbon capture, storage and utilization
日期	2023
上傳時間	1-Jul-2024 13:31:36 (UTC+8)
摘要	本研究著眼於台灣微藻固碳技術的創新發展，從科技創新系統（Technological Innovation System, TIS）和創新生態系統（Innovation Ecosystem）的視角進行探討，分析了技術發展、知識轉化以及商業化過程中的關鍵互動和合作模式，探討科技創新系統如何更好地協助創新生態系統的發展，並從每一個功能性活動分別創造了什麼價值，連結到企業如何把產業生態系建立起來，以創造對自身有利的發展環境。透過文獻回顧及質性研究法針對我國工研院微藻研發團隊和成功大學微藻研發團隊的深度訪談，嘗試描繪產學研三方的當前發展，從而評估和辨識創新系統中的互動、合作模式及其對技術推進的影響。研究發現，科技創新系統與創新生態系統的整合，形成了一個動態互補的創新網絡，使技術創新更有效地轉化為市場產品。結論指出，台灣應持續加強其科技創新系統，特別是在研發到商業化的轉化過程中，增強創新生態系統中各方的協作與互動，以促進微藻固碳技術的產業化和市場化。 This study focuses on the innovative development of microalgae carbon capture technology in Taiwan, explored from the perspectives of the Technological Innovation System (TIS) and the Innovation Ecosystem. It analyzes the key interactions and cooperation models in the processes of technology development, knowledge transformation, and commercialization, exploring how the technological innovation system can better assist the development of the innovation ecosystem. It also examines the value created by each system building activity, linking this to how companies build ecosystems to create favorable development environments for themselves. Through literature review and qualitative research methods, including in-depth interviews with the microalgae research teams of the Industrial Technology Research Institute and National Cheng Kung University, the study attempts to depict the current development among academia, industry, and research institutions, thereby assessing and identifying the interactions and cooperation models within the innovation system and their impact on technological advancement. The findings reveal that the integration of the technological innovation system and the innovation ecosystem forms a dynamic and complementary innovation network, making technological innovation more effectively transform into commercial products. The conclusion points out that Taiwan should continue to strengthen its technological innovation system, particularly in the transition from research and development to commercialization, enhancing the collaboration and interaction among various parties within the innovation ecosystem to promote the industrialization and marketization of microalgae carbon capture and utilization technology.
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Analyzing the functional dynamics of technological innovation systems: A scheme of analysis. Research policy, 37(3), 407-429. Bergek, A., Hekkert, M., Jacobsson, S., Markard, J., Sandén, B., & Truffer, B. (2015). Technological innovation systems in contexts: Conceptualizing contextual structures and interaction dynamics. Environmental innovation and societal transitions, 16, 51- 64. Bogdan, R. C., & Biklen, S. K. (1982). Qualitative research for education: An introduction to theory and methods. Breslin, D., Kask, J., Schlaile, M., & Abatecola, G. (2021). Developing a coevolutionary account of innovation ecosystems. Industrial Marketing Management, 98, 59-68. Carlsson, B., & Stankiewicz, R. (1991). On the nature, function and composition of technological systems. Journal of evolutionary economics, 1, 93-118. Carlsson, B., Jacobsson, S., Holmén, M., & Rickne, A. (2002). Innovation systems: analytical and methodological issues. Research policy, 31(2), 233-245. Denzin, N. K., & Lincoln, Y. S. (2011). The SAGE Handbook of Qualitative Research Granstrand, O., & Holgersson, M. (2020). Innovation ecosystems: A conceptual review and a new definition. Technovation, 90, 102098. Hellsmark, H., & Jacobsson, S. (2009). Opportunities for and limits to academics as system builders—the case of realizing the potential of gasified biomass in Austria. Energy Policy, 37(12), 5597-5611. Ho, S. H., Chen, C. Y., Lee, D. J., & Chang, J. S. (2011). Perspectives on microalgal CO2- emission mitigation systems—a review. Biotechnology advances, 29(2), 189-198. Iansiti, M., & Levien, R. (2004). Strategy as ecology. Harvard business review, 82(3), 68-78. Iansiti, M, & Levien, R. (2004b), “The Keystone advantage: What the new dynamics of business ecosystems mean or strategy, innovation, and sustainability”, Boston MA: Harvard Business School Press. Jacobsson, S., & Johnson, A. (2000). The diffusion of renewable energy technology: an analytical framework and key issues for research. Energy policy, 28(9), 625-640. Jacobides, M. G., Knudsen, T., & Augier, M. (2006). Benefiting from innovation: Value creation, value appropriation and the role of industry architectures. Research policy, 35(8), 1200-1221. James F. Moore.(1993) Predators and prey: a new ecology of competition. Harv Bus Rev. 1993 May-Jun;71(3):75-86 James F. Moore.(2006). Business ecosystems and the view from the firm, The Antitrust Bulletin:Vol.51, No.1/Spring 2006 31-75 Kebede, K. Y., & Mitsufuji, T. (2017). Technological innovation system building for diffusion of renewable energy technology: A case of solar PV systems in Ethiopia. Technological Forecasting and Social Change, 114, 242-253. Musiolik, J., & Markard, J. (2011). Creating and shaping innovation systems: Formal networks in the innovation system for stationary fuel cells in Germany. Energy Policy, 39(4), 1909-1922. Neuman, W.L. (1997) Social Research Methods: Qualitative and Quantitative Approaches. Scaringella, L., & Radziwon, A. (2018). Innovation, entrepreneurial, knowledge, and business ecosystems: Old wine in new bottles?. Technological Forecasting and Social Change, 136, 59-87. Shaw, D. R., & Allen, T. (2018). Studying innovation ecosystems using ecology theory. Technological Forecasting and Social Change, 136, 88-102. Silverman, L. (1985). The Ideological Mediation of Party‐political Responses to Social Change. European Journal of Political Research, 13(1), 69-93. Singh, J., & Dhar, D. W. (2019). Overview of carbon capture technology: microalgal biorefinery concept and state-of-the-art. Frontiers in Marine Science, 6, 29. Teece, D. J. (2007). Explicating dynamic capabilities: the nature and microfoundations of (sustainable) enterprise performance. Strategic management journal, 28(13), 1319- 1350. de Vasconcelos Gomes, L. A., Salerno, M. S., Phaal, R., & Probert, D. R. (2018). How entrepreneurs manage collective uncertainties in innovation ecosystems. Technological Forecasting and Social Change, 128, 164-185. Weil, H. B., Sabhlok, V. P., & Cooney, C. L. (2014). The dynamics of innovation ecosystems: A case study of the US biofuel market. Energy strategy reviews, 3, 88- 99. 三、網路資料李幸宜。以減碳創造新收益、新經濟微藻變身生質金礦。工業技術與資訊月刊。最後檢索日期：2023年2月20日，檢自： https://www.itri.org.tw/ListStyle.aspxDisplayStyle=18_content&SiteID=1& MmmID=1036452026061075714&MGID=711302240625714532 李洵穎。從排碳大戶到養生專家微藻固碳助水泥業走永續之路。工業技術與資訊月刊332期2019年08月號。最後檢索日期：2023年8月20日。檢自： https://www.itri.org.tw/ListStyle.aspx?DisplayStyle=18_content&SiteID=1&MmmID=1036452026061075714&MGID=1036250477610254775 許旭昇。科研成果產業化，他們怎麼做? 最後檢索日期：2023年3月1號。檢自： https://tpl.ncl.edu.tw/NclService/pdfdownloadfilePath=lV8OirTfsslWcCxIpLbUfpBFnr50DaCpDeDnz5UaYHEkegzhDkBAsvsxgJXR66er&imgType=Bn5sH4BGpJw=&key=ymcTTlMn-wwaY8ZRIYlwe1Uj6FvspNS8PB2d7g6_hfMeVVU9OyINO4qBZJhLTxWd&xmlId=0006960531 張嘉修、陳俊延、林志生、楊勝仲、周德珍、郭子禎、顏宏偉、李澤民。2015。二氧化碳再利用 ─ 微藻養殖。科學發展 2015 年 6 月│ 510 期賴允政。2020。微藻的減碳循環經濟，檢自：https://www.grb.gov.tw/search/report/13381777 闕壯群。2009。微藻類固碳工程。科學發展 2009年1月，433期工研院技術研究院官網。【碳捕捉、利用與封存減碳解決方案】綠色捕手－微藻固碳及利用技術。檢自：https://www.itri.org.tw/ListStyle.aspx?DisplayStyle=01_content&SiteID=1&MmmID=1162127241711441152&MGID=1162130537112316003 最後檢索日期：2024/05/25 行政院國家科學委員會專題研究計畫成果報告，微藻生質能源整合型技術開發研究成果報告。2009。計畫主持人:張嘉修《臺灣2050淨零排放路徑及策略總說明》。2022。國家發展委員會、行政院環境保護署、經濟部、科技部、交通部、內政部、行政院農業委員會、金融監督管理委員會研究機構能源科技專案 103 年度執行報告，微藻綠能科技發展計畫。2014。經濟部財團法人食品工業發展研究所研究機構能源科技專案 105 年度執行報告，永續生質能源關鍵技術研發計畫。2017。經濟部財團法人工業技術研究院國立成功大學新聞中心，成大「新型態藻菌廢水處理技術」傳統與高科技產業均青睞。2019。網址：https://news-secr.ncku.edu.tw/p/404-1037-197992.php 國立成功大學能源科技與策略研究中心。最後檢索日期：2023/08/28 網址：https://cets.ncku.edu.tw/index.php?inter=technology&id=105&tabid=175 國立成功大學能源科技與策略研究中心，微藻固碳及水淨化。網址： https://cets.ncku.edu.tw/index.php?inter=technology&id=105&tabid=167。最後檢索日期：2023/08/28 節約能源專區官網。2008。取自台灣電力公司，最後檢索日期：2023/08/28 網址：https://www.energypark.org.tw/news/news/15-promotion-activities/282-2018-08-24%2010-29-16-282.html 台泥公司永續報告書。2021。台泥公司官網台泥公司永續報告書。2022。台泥公司官網中鋼公司永續報告書。2022。中鋼公司官網 World Energy Outlook 2022, WEO2022，International Energy Agency, IEA
描述	碩士國立政治大學科技管理與智慧財產研究所 110364119
資料來源	http://thesis.lib.nccu.edu.tw/record/#G0110364119
資料類型	thesis

dc.contributor.advisor	柯玉佳	zh_TW
dc.contributor.advisor	Ko, Yu-Chia	en_US
dc.contributor.author (Authors)	曾鈺婷	zh_TW
dc.contributor.author (Authors)	Tseng, Yu-Ting	en_US
dc.creator (作者)	曾鈺婷	zh_TW
dc.creator (作者)	Tseng, Yu-Ting	en_US
dc.date (日期)	2023	en_US
dc.date.accessioned	1-Jul-2024 13:31:36 (UTC+8)	-
dc.date.available	1-Jul-2024 13:31:36 (UTC+8)	-
dc.date.issued (上傳時間)	1-Jul-2024 13:31:36 (UTC+8)	-
dc.identifier (Other Identifiers)	G0110364119	en_US
dc.identifier.uri (URI)	https://nccur.lib.nccu.edu.tw/handle/140.119/152137	-
dc.description (描述)	碩士	zh_TW
dc.description (描述)	國立政治大學	zh_TW
dc.description (描述)	科技管理與智慧財產研究所	zh_TW
dc.description (描述)	110364119	zh_TW
dc.description.abstract (摘要)	本研究著眼於台灣微藻固碳技術的創新發展，從科技創新系統（Technological Innovation System, TIS）和創新生態系統（Innovation Ecosystem）的視角進行探討，分析了技術發展、知識轉化以及商業化過程中的關鍵互動和合作模式，探討科技創新系統如何更好地協助創新生態系統的發展，並從每一個功能性活動分別創造了什麼價值，連結到企業如何把產業生態系建立起來，以創造對自身有利的發展環境。透過文獻回顧及質性研究法針對我國工研院微藻研發團隊和成功大學微藻研發團隊的深度訪談，嘗試描繪產學研三方的當前發展，從而評估和辨識創新系統中的互動、合作模式及其對技術推進的影響。研究發現，科技創新系統與創新生態系統的整合，形成了一個動態互補的創新網絡，使技術創新更有效地轉化為市場產品。結論指出，台灣應持續加強其科技創新系統，特別是在研發到商業化的轉化過程中，增強創新生態系統中各方的協作與互動，以促進微藻固碳技術的產業化和市場化。	zh_TW
dc.description.abstract (摘要)	This study focuses on the innovative development of microalgae carbon capture technology in Taiwan, explored from the perspectives of the Technological Innovation System (TIS) and the Innovation Ecosystem. It analyzes the key interactions and cooperation models in the processes of technology development, knowledge transformation, and commercialization, exploring how the technological innovation system can better assist the development of the innovation ecosystem. It also examines the value created by each system building activity, linking this to how companies build ecosystems to create favorable development environments for themselves. Through literature review and qualitative research methods, including in-depth interviews with the microalgae research teams of the Industrial Technology Research Institute and National Cheng Kung University, the study attempts to depict the current development among academia, industry, and research institutions, thereby assessing and identifying the interactions and cooperation models within the innovation system and their impact on technological advancement. The findings reveal that the integration of the technological innovation system and the innovation ecosystem forms a dynamic and complementary innovation network, making technological innovation more effectively transform into commercial products. The conclusion points out that Taiwan should continue to strengthen its technological innovation system, particularly in the transition from research and development to commercialization, enhancing the collaboration and interaction among various parties within the innovation ecosystem to promote the industrialization and marketization of microalgae carbon capture and utilization technology.	en_US
dc.description.tableofcontents	第一章緒論 9 第一節研究背景與動機 9 第二節研究目的與問題 11 第三節論文結構 11 第二章文獻探討 12 第一節微藻固碳與加值化開發 12 一、微藻固碳技術發展簡介 12 二、聚焦我國微藻固碳發展 15 三、微藻固碳後再利用之市場佈局 19 第二節科技創新系統（TIS）理論發展 22 一、科技創新系統簡介 22 二、科技創新系統構成要件 24 三、科技創新系統對於功能性活動的討論 26 第三節創新生態系統 30 一、創新生態系統簡介 30 二、創新生態系統構成要件 32 第四節綜合兩理論進行討論 34 一、整合性討論 34 二、形成本研究架構 38 第三章研究方法 39 第一節質性研究法 39 一、理論思維 39 二、資料蒐集方法 40 三、研究的應用 41 第二節研究流程與研究架構 42 一、研究流程 42 二、研究架構 43 第三節研究對象 44 第四節研究限制 45 第四章個案研究 46 第一節台灣微藻固碳與固碳後再利用之創新技術發展 48 第二節綜合理論框架探討創新技術發展概況 49 一、知識發展與擴散 51 二、探索發展方向 53 三、創新創業活動 54 四、市場形塑 59 五、建立正當性 62 六、資源移轉運用 64 七、創造正向外部性 65 第三節綜觀台灣微藻產業生態系之價值創造 67 ㄧ、關鍵參與者的價值創造 67 二、共生互賴的關係 69 第五章結論與建議 72 第一節研究發現與結論 72 一、研究發現 72 二、研究結論 74 第二節學術貢獻 76 第三節實務建議 77 第四節後續研究建議 79 參考文獻 80 ㄧ、中文部分 80 二、英文部分 80 三、網路資料 82 附錄：訪綱設計 84 一、訪綱ㄧ 84 二、訪綱二 86	zh_TW
dc.format.extent	2727956 bytes	-
dc.format.mimetype	application/pdf	-
dc.source.uri (資料來源)	http://thesis.lib.nccu.edu.tw/record/#G0110364119	en_US
dc.subject (關鍵詞)	科技創新系統	zh_TW
dc.subject (關鍵詞)	創新生態系統	zh_TW
dc.subject (關鍵詞)	微藻固碳與固碳後再利用	zh_TW
dc.subject (關鍵詞)	Technological innovation system	en_US
dc.subject (關鍵詞)	Innovation ecosystem	en_US
dc.subject (關鍵詞)	Microalgae carbon capture, storage and utilization	en_US
dc.title (題名)	台灣微藻固碳科技創新發展研究-以科技創新系統與創新生態系統觀點	zh_TW
dc.title (題名)	Exploring the Technological Innovation of Microalgae-based Carbon Capture in Taiwan: Perspectives from Technological Innovation System and Innovation Ecosystem	en_US
dc.type (資料類型)	thesis	en_US
dc.relation.reference (參考文獻)	一、中文部分周興平。2020。Environmental Innovation and Societal Transitions 16 (2015) 51–64 。國立清華大學科技管理研究所博士論文。張書豪。2014。創新生態系統下研發成果產業化模型與實踐機制。科技管理學刊第十九卷第三期 103年9月 1-32 楊佩芬。2019。微藻生質能源基因工程技術發展盧文章、王振諧。2009。藻類培養之光合生物反應器發展現況。化工資訊與商情 77 期20-25 潘淑滿。2022。質性研究：理論與應用（第二版）二、英文部分 Adner, R., & Kapoor, R. (2010). Value creation in innovation ecosystems: How the structure of technological interdependence affects firm performance in new technology generations. Strategic management journal, 31(3), 306-333. Adner, R. (2012). The wide lens: A new strategy for innovation(Vol. 34, No. 9). Penguin Uk. Adner, R. (2017). Ecosystem as structure: An actionable construct for strategy. Journal of management, 43(1), 39-58. Bergek, A., Jacobsson, S., Carlsson, B., Lindmark, S., & Rickne, A. (2005, June). Analyzing the dynamics and functionality of sectoral innovation systems–a manual. In DRUID tenth anniversary summer conference (pp. 27-29). 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