研究生: |
王雋杰 Wang, Chun-Chieh |
---|---|
論文名稱: |
以區塊鏈暨智能合約技術協助台灣內部企業進行碳權交易 Assisting Domestic Enterprises in Taiwan with Carbon Credit Trading Using Blockchain and Smart Contract Technologies |
指導教授: |
蔡芸琤
Tsai, Yun-Cheng |
口試委員: |
蔡芸琤
Tsai, Yun-Cheng 陸裕豪 Lu, Yu-Hao 曾思遠 Tseng, Ssu-Yuan 詹皓詠 Chan, Hao-Yung |
口試日期: | 2024/07/17 |
學位類別: |
碩士 Master |
系所名稱: |
科技應用與人力資源發展學系 Department of Technology Application and Human Resource Development |
論文出版年: | 2024 |
畢業學年度: | 112 |
語文別: | 英文 |
論文頁數: | 93 |
中文關鍵詞: | 碳權 、區塊鏈 、智能合約 、碳排放 、以太坊 |
英文關鍵詞: | Carbon Credit, Blockchain, Smart contract, Carbon emissions, Ethereum |
研究方法: | 實驗設計法 、 調查研究 |
DOI URL: | http://doi.org/10.6345/NTNU202401408 |
論文種類: | 學術論文 |
相關次數: | 點閱:119 下載:4 |
分享至: |
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報 |
19世紀工業革命的興起,人們對於化石燃料的需求大幅增長,導致溫室氣體排放量快速增長,其中二氧化碳為排放量最大之占比。近幾十年來溫室氣體排放所導致全球暖化問題日益明顯,造成生物環境之危脅及經濟層面之影響。因此於1997年12月,多達84個國家及歐盟成員國於日本京都進行《京都議定書》之簽署,並建立碳權交易等相關之機制,以促進碳權交易市場發展及助於各國或企業達成減排及永續發展之目標。因應歐盟所提出碳邊境調整機制(Carbon Border Adjustment Mechanism, CBAM)以及美國所提出的美國清潔競爭法案(Clean Competition Act, CCA)和台灣政府提出於2050達成淨零排放之政策,台灣企業勢必於政策期限內達到碳排放之標準,但在中小企業的部分可能面臨到技術門檻高、市場風險、參與門檻等困境。
綜合上述,本研究所開發之去中心化碳權交易平台專注於碳邊境調整機制(Carbon Border Adjustment Mechanism, CBAM)和美國清潔競爭法案(Clean Competition Act, CCA)關稅制度,以協助用戶將所產生之總碳排放量,依據這兩項關稅制度進行抵免。透過結合區塊鏈技術及智能合約導入至平台內,其旨為協助台灣中小企業以成本及時間最小化狀態下於碳權市場進行買賣,以解決其於短時間內無法更換綠能設備、碳排放超額之困境,同時也滿足其碳排放目標。
The rise of the 19th-century Industrial Revolution led to a significant increase in demand for fossil fuels, resulting in a rapid growth of greenhouse gas emissions, with carbon dioxide being the largest contributor. In recent decades, the problem of global warming caused by greenhouse gas emissions has become increasingly evident, resulting in threats to the biosphere and impacts on the economy. Therefore, in December 1997, as many as 84 coun-tries and EU member states signed the Kyoto Protocol in Japan, and estab-lished mechanisms such as carbon trading to promote the development of the carbon trading market and to help countries or enterprises achieve the goal of emission reduction and sustainable development. In response to the Carbon Border Adjustment Mechanism (CBAM) proposed by the European Union, the Clean Competition Act (CCA) by the United States, and the Taiwanese government's policy of achieving net-zero emissions by 2050, Taiwanese companies must meet carbon emissions standards within the policy deadline. However, small and medium-sized enterprises (SMEs) may face challenges such as high technical thresholds, market risks, and participation barriers.
Based on the above, this research develops a decentralized carbon trading platform focusing on the Carbon Border Adjustment Mechanism (CBAM) and the Clean Competition Act (CCA) tariff systems. It assists users in offsetting their total carbon emissions according to these two tariff systems. Integrating blockchain technology and smart contracts into the platform aims to help Taiwanese SMEs minimize costs and time when trading in the carbon market, addressing the dilemma of not being able to replace green energy equipment in a short time and exceeding carbon emissions while meeting their carbon re-duction targets.
吳栢妤(2023)。2022年對4大市場出口額「全創新高」 財政部:中國大陸獨憔悴。Yahoo奇摩股市。https://tw.stock.yahoo.com/news/2022-%E5%B9%B4%E5%B0%8D-4-%E5%A4%A7%E5%B8%82%E5%A0%B4%E5%87%BA%E5%8F%A3%E9%A1%8D%E3%80%8C%E5%85%A8%E5%89%B5%E6%96%B0%E9%AB%98%E3%80%8D-%E8%B2%A1%E6%94%BF%E9%83%A8%EF%BC%9A%E4%B8%AD%E5%9C%8B%E5%A4%A7%E9%99%B8%E7%8D%A8%E6%86%94%E6%82%B4-093719282.html
吳婉瑜(2022)。淨零排放進逼1/中小企業碳盤查完成比例低 減碳第一步就卡關。Yahoo奇摩新聞。https://tw.news.yahoo.com/%E6%B7%A8%E9%9B%B6%E6%8E%92%E6%94%BE%E9%80%B2%E9%80%BC1-%E4%B8%AD%E5%B0%8F%E4%BC%81%E6%A5%AD%E7%A2%B3%E7%9B%A4%E6%9F%A5%E5%AE%8C%E6%88%90%E6%AF%94%E4%BE%8B%E4%BD%8E-%E6%B8%9B%E7%A2%B3%E7%AC%AC-%E6%AD%A5%E5%B0%B1%E5%8D%A1%E9%97%9C-220000486.html
何晨瑋(2023)。一文搞懂什麼是CBAM碳邊境調整機制?10月上路!ESG遠見。https://esg.gvm.com.tw/article/5120
李蘇竣(2023)。調查顯示我國產業減碳仍緩步 台灣企業設淨零目標者不到一成。環境資訊中心。https://e-info.org.tw/node/236820
易淳敏(2023)。CBAM歐盟碳關稅10月上路!5件你必須知道的事。ESG遠見。https://esg.gvm.com.tw/article/28453
金融監督管理委員會(2022)。上市櫃公司永續發展路徑圖。金融監督管理委員會證卷期貨局。https://www.sfb.gov.tw/uploaddowndoc?file=news/202203031544210.pdf&filedisplay=%E6%96%B0%E8%81%9E%E7%A8%BF%E9%99%84%E4%BB%B6-%E8%B7%AF%E5%BE%91%E5%9C%96%E6%8E%A8%E5%8B%95%E8%A6%8F%E5%8A%83.pdf&flag=doc
曹妤如(2023)。美國CCA法案解析:碳關稅即將上路中小企業如何應對。中小企業綠色環保資訊網。https://green.sme.gov.tw/detail.php?type=1&id=2844&lang=tw
傅沁怡(2023)。台灣2022出、進口值均排名世界17。Yahoo奇摩股市。https://tw.stock.yahoo.com/news/%E5%8F%B0%E7%81%A32022%E5%87%BA-%E9%80%B2%E5%8F%A3%E5%80%BC%E5%9D%87%E6%8E%92%E5%90%8D%E4%B8%96%E7%95%8C17-093550127.html
經濟部中小及新創企業署(2022)。2022年中小企業白皮書。經濟部中小企業處。https://book.moeasmea.gov.tw/book/doc_detail.jsp?pub_SerialNo=2022A01686&click=2022A01686
管中維(2023)。自願減量可獲碳權 微型企業申請程序擬精簡。中央通訊社。https://www.cna.com.tw/news/ahel/202307240124.aspx
經濟部標準檢驗局(2022)。碳查證機構再添生力軍!工研院量測中心即日起受理服務。經濟部。https://www.moea.gov.tw/MNS/populace/News.aspx?kind=1&menu_i d=40&news_id=102707
環境部氣候變遷署(2016)。我國合格溫室氣體查驗機構之基本資訊。環境部氣候變遷署事業溫室氣體排放量資訊平台。https://ghgregistry.moenv.gov.tw/epa_ghg/VerificationMgt/InspectionAgency.aspx
環境部氣候變遷署(2023)。溫室氣體自願減量暨抵換資訊平臺。環境部氣候變遷署。https://carbonoffset.moenv.gov.tw/
顏和正(2023)。什麼是CBAM、EU ETS、CCA和Carbon Leakage?一次搞懂歐盟碳關稅的關鍵字【永續會研究室】。CSR@天下。https://csr.cw.com.tw/article/42992
Aggarwal, S. (2018). Modern web-development using reactjs. International Journal of Recent Research Aspects, 5(1), 133-137.
Ahl, A., Yarime, M., Goto, M., Chopra, S. S., Kumar, N. M., Tanaka, K., & Sagawa, D. (2020). Exploring blockchain for the energy transition: Opportunities and challenges based on a case study in Japan. Renewable and sustainable energy reviews, 117. https://doi.org/10.1016/j.rser.201-9.10-9488
Aki Kachi, I. C. A. P., & Frerk, M (2013). Carbon Market Oversight Primer. International Carbon Action Partnership Press.
Antonopoulos, A. M., & Wood, G. (2018). Mastering ethereum: building smart contracts and dapps (1nd ed.). O'reilly Media.
Balkrishna Industries Limited (2022). Balkrishna Industries Limited’s b-lockchain address. AlgoExplorer.
Berger, C., Blauth, R., & Boger, D. (1993). Kano’s methods for understanding customer-defined quality. Center for Quality Management Journal, 2, 3-36.
Brent, L., Jurisevic, A., Kong, M., Liu, E., Gauthier, F., Gramoli, V., ... & Scholz, B. (2018). Vandal: A scalable security analysis framework for smart contracts. arXiv preprint arXiv:1809.03981. https://doi.org/10.-48550/arXiv.1809.03981
Buck, H. J. (2021). Ending fossil fuels: Why net zero is not enough (1nd ed.). Verso Books.
CDM (2009a). AMS-I.D.: Grid connected renewable electricity gene-ration --- Version 13.0. CDM. https://cdm.unfccc.int/UserManagement/File-Storage/CDMWF_AM_PHPV5WESACMBTJ2YY54GAJYSIEI3HD
CDM (2009b). Tool to calculate the emission factor for an electricity system. CDM.
CDM (2020). Large-scale Consolidated Methodology: Grid-connected electricity generation from renewable sources. CDM.
Cokorilo, O. L. J. A., & Tomic, L. I. D. I. J. A. (2019). CORSIA-Carbon Offsetting and Reduction Scheme for International Aviation: Challenge and Practice. Topic: Next Generation Transport Industry Innovations, 1, 105-112.
Convery, F. J. (2009). Origins and development of the EU ETS. Environmental and Resource Economics, 43, 391-412. https://doi.org/10.1007/s10640-009-9275-7
Crosby, M., Pattanayak, P., Verma, S., & Kalyanaraman, V. (2016). Block-chain technology: Beyond bitcoin. Applied Innovation, 2(6-10), 6-19.
David, D., Yoshino, M., & Varun, J. P. (2022). Developing FinTech Ecosys-tems for Voluntary Carbon Markets Through Nature-Based Solutions: Opportunities and Barriers in ASEAN. Green Digital Finance and Sus-tainable Development Goals, 111-142. https://doi.org/10.1007-/978-981-19-2662-4_6
Fankhauser, S., & Hepburn, C. (2010, August). Designing carbon markets, Part II: Carbon markets in space. Energy policy, 38(8), 4381-4387. https://doi.org/10.1016/j.enpol.2010.03.066
Gencer, A. E., Basu, S., Eyal, I., Van Renesse, R., & Sirer, E. G. (2018). De-centralization in bitcoin and ethereum networks. Financial Cryptography and Data Security: 22nd International Conference, FC 2018, Nieu-wpoort, Curaçao, February 26–March 2, 2018, Revised Selected Papers 22, 439-457. https://doi.org/10.1007/978-3-662-58387-6_24
Global Wind Energy Council (2023). Global Wind Report 2023. Global Wind Energy Council. https://gwec.net/globalwindreport2023/
Golestani, N., Arzaghi, E., Abbassi, R., Garaniya, V., Abdussamie, N., & Yang, M. (2021). The Game of Guwarra: A game theory-based decision-making framework for site selection of offshore wind far-ms in Australia. Journal of Cleaner Production, 326, 1-22. https://-doi.org/10.1016/j.jclepro.2021.129358
Gosavi, O., Mahajan, R., Rathod, N., & Sharma, S (2023, May). DESIGNING A SOFTWARE TOOL SET FOR STORING DATA IN DECENTRALIZED STORAGE SYSTEM
Hegedűs, P. (2018, May). Towards analyzing the complexity landscape of solidity based ethereum smart contracts. Proceedings of the 1st Interna-tional Workshop on Emerging Trends in Software Engineering for Blockchain, 35-39. https://doi.org/10.1145/3194113.3194119
Hemami, A. (2012). Wind turbine technology (1nd ed.). Cengage Learning.
Hildenbrandt, E., Saxena, M., Rodrigues, N., Zhu, X., Daian, P., Guth, D., ... & Rosu, G. (2018, July). Kevm: A complete formal seman-tics of the ethereum virtual machine. 2018 IEEE 31st Computer -Security Foundations Symposium (CSF), 204-217. IEEE. https://doi.-org/10.1109/CSF.2018.00022
Johnson, M., Jones, M., Shervey, M., Dudley, J. T., & Zimmerman, N. (2019). Building a secure biomedical data sharing decentralized app (DApp): tutorial. Journal of medical Internet research, 21(10), 768-782. https://doi.org/10.2196/13601
Kennedy, K., & Gangotra, A. (2023). New US Trade Policies Can In-centivize Clean Industrial Manufacturing. World Resources Institute.
Khan, A. (2022, August). Graph analysis of the ethereum blockchain data: A survey of datasets, methods, and future work. 2022 IEEE International Conference on Blockchain (Blockchain), 250-257. IEEE. https://doi.or-g/10.1109/Blockchain55522.2022.00042
Kosba, A., Miller, A., Shi, E., Wen, Z., & Papamanthou, C. (2016, May). Hawk: The blockchain model of cryptography and privacy-preserving smart contracts. 2016 IEEE symposium on security and privacy (SP), 839-858. IEEE. https://doi.org/10.1109/SP.2016.55
Kuonen, D. (2023). The process of creating, testing, and deploying smart contracts on the Ethereum blockchain using Solidity. Haaga-Helia University of Applied Sciences, THESEUS.
Kuusi, T., Björklund, M., Kaitila, V., Kokko, K., Lehmus, M., Mechling, M., ... & Wang, M. (2020). Carbon border adjustment mechanisms and their economic impact on Finland and the EU. Prime Minister’s Office, 48.
Lausen, J., Glock, D., Geres, R., Lischker, S., Ferdinand, M., & Mihai, A. (2022). Trading activities and strategies in the European carbon market. Final report. Umweltbundesamt, 54(5).
Lee, X. T., Khan, A., Sen Gupta, S., Ong, Y. H., & Liu, X. (2020, April). Measurements, analyses, and insights on the entire ethereum blockchain network. WWW '20: Proceedings of The Web Conference 2020, 155-166. https://doi.org/10.1145/3366423.3380103
Letcher, T. (Ed.). (2023). Wind energy engineering: A handbook for on-shore and offshore wind turbines.
Luu, L., Chu, D. H., Olickel, H., Saxena, P., & Hobor, A. (2016, October). Making smart contracts smarter. CCS '16: Proceedings of the 2016 ACM SIGSAC Conference on Computer and Communications Securi-ty, 254-269. https://doi.org/10.1145/2976749.2978309
Macrinici, D., Cartofeanu, C., & Gao, S. (2018). Smart contract applications within blockchain technology: A systematic mapping stud-y. Telematics and Informatics, 35(8), 2337-2354. https://doi.org/10.1-016/j.tele.2018.10.004
Malhotra, D., Saini, P., & Singh, A. K. (2022). How blockchain can automate KYC: Systematic review. Wireless Personal Communications, 122(2), 1987-2021. https://doi.org/10.1007/s11277-021-08977-0
McKay, A., de Pennington, A., & Baxter, J. (2001). Requirements ma-nagement: a representation scheme for product specifications. Com-puter-Aided Design, 33(7), 511-520. https://doi.org/10.1016/S0010-4485(01)00050-1
Medeiros, H., Vilain, P., Mylopoulos, J., & Jacobsen, H. A. (2019, November). Solunit: A framework for reducing execution time of smart contract unit tests. CASCON '19: Proceedings of the 29th Annual International Con-ference on Computer Science and Software Engineering, 264-273.
Mhamdi, H., Zouinkhi, A., & Sakli, H. (2021, June). Smart contracts for de-centralized vehicle services. 2021 International Wireless Communica-tions and Mobile Computing (IWCMC), 1846-1851. https://doi.org/10.-1109/IWCMC51323.2021.9498954
Murray, M. (2019). Tutorial: A descriptive introduction to the blockch-ain. Communications of the Association for Information Systems, 45(1), 464-487. Https://doi.org/10.17705/1CAIS.04525
Naegele, H., & Zaklan, A. (2019). Does the EU ETS cause carbon leakage in European manufacturing?. Journal of Environmental Economics and Management, 93, 125-147. https://doi.org/10.1016/j.jeem.2018.11.004
Olano, M. V. (2022). Chart: The top 10 countries with the most wind power. Canary Media. https://www.canarymedia.com/articles/wind/chart-the-top-10-countries-with-the-most-wind-power
Palechor, L., & Bezemer, C. P. (2022, May). How are Solidity smart contracts tested in open source projects? An exploratory study. 2022 IEEE/ACM International Conference on Automation of Software Test (AST), 165-169. https://doi.org/10.1145/3524481.3527228
Pigeolet, L., & Van Waeyenberge, A. (2019). Assessment and challenges of carbon markets. Brazilian Journal of International Law, 16, 74-89. https://doi.org/10.5102/rdi.v16i2.6265
Poongodi, M., Sharma, A., Vijayakumar, V., Bhardwaj, V., Sharma, A. P., Iqbal, R., & Kumar, R. (2020). Prediction of the price of Ethereum blockchain cryptocurrency in an industrial finance system. Computers & Electrical Engineering, 81. https://doi.org/10.1016/j.compeleceng.2019.106527
Rahimian, R., & Clark, J. (2021). TokenHook: Secure ERC-20 smart con-tract. arXiv preprint arXiv:2107.02997. https://doi.org/10.48550/arX-iv.2107.02997
Ranjan, P., Srivastava, S., Gupta, V., Tapaswi, S., & Kumar, N. (2019, De-cember). Decentralized and distributed system for organ/tissue donation and transplantation. 2019 IEEE Conference on Information and Com-munication Technology, 1-6. https://doi.org/10.1109/ACCESS.2022.3180008
Raufer, R., Coussy, P., & Freeman, C. (2022). Emissions trading. Han-dbook of climate change mitigation and adaptation, 3237-3294. https://doi.org/10.1007/978-3-030-72579-2_8
Saraji, S., & Borowczak, M. (2021). A blockchain-based carbon credit eco-system. arXiv preprint arXiv:2107.00185. https://doi.org/10.48550/arXiv.-2107.00185
Semieniuk, G., Campiglio, E., Mercure, J. F., Volz, U., & Edwards, N. R. (2021). Low‐carbon transition risks for finance. Wiley Interdisciplinary Reviews: Climate Change, 12(1). https://doi.org/10.1002/wcc.678
Sireli, Y., Kauffmann, P., & Ozan, E. (2007). Integration of Kano's model into QFD for multiple product design. IEEE Transactions on Engineering Management, 54(2), 380-390. https://doi.org/10.1109/TEM.2007.8939-90
Solorio, K., Kanna, R., & Hoover, D. H. (2019). Hands-on smart contract development with Solidity and Ethereum: From fundamentals to de-ployment (1nd ed.). O'Reilly Media.
Stoll, C., Klaaßen, L., & Gallersdörfer, U. (2019). The carbon footpri-nt of bitcoin. Joule, 3(7), 1647-1661. https://doi.org/10.1016/j.joule.-2019.05.012
Suvitha, M., & Subha, R. (2021, March). A survey on smart contract plat-forms and features. 2021 7th International Conference on Advanced Computing and Communication Systems (ICACCS), 1, 1536-1539. https://doi.org-/10.1109/ICACCS51430.2021.9441970
Tang, Q., & Tang, L. M. (2019). Toward a distributed carbon ledger for car-bon emissions trading and accounting for corporate carbon manage-ment. Journal of Emerging Technologies in Accounting, 16(1), 37-46. https://doi.org/10.2308/jeta-52409
Taş, R., & Tanrıöver, Ö. Ö. (2019, October). Building a decentralized appli-cation on the ethereum blockchain. 2019 3rd IEEE International Sym-posium on Multidisciplinary Studies and Innovative Technologies (ISMSIT), 1-4. https://doi.org/10.1109/ISMSIT.2019.8932806
Viriyasitavat, W., & Hoonsopon, D. (2019). Blockchain characteristics and consensus in modern business processes. Journal of Industrial Infor-mation Integration, 13, 32-39. https://doi.org/10.1016/j.jii.2018.07.004
Vallejo Seade, P. (2022). Asset tokenization in real estate through the means of token standards available on the ethereum blockchain. Universidad de los Andes. http://hdl.handle.net/1992/63522
VTRM Renewable Energy 2 (2022). VTRM Renewable Energy 2’s blo-ckchain address. AlgoExplorer.
Wöhrer, M., & Zdun, U. (2021, December). Devops for ethereum blo-ckchain smart contracts. 2021 IEEE International Conference on -Blockchain (Blockchain), 244-251. https://doi.org/10.1109/Blockchai-n53845.2021.00040
Xing, Y., Huang, J., & Lai, Y. (2019, February). Research and analysis of the front-end frameworks and libraries in e-business development. ICCAE 2019: Proceedings of the 2019 11th International Conference on Com-puter and Automation Engineering, 68-72. https://doi.org/10.1145/33-13991.3314021