Energy system transformation for attainability of net zero emissions in Thailand

Q1 Social Sciences

International Journal of Sustainable Energy Planning and Management Pub Date : 2022-09-13 DOI:10.54337/ijsepm.7116

B. Limmeechokchai, Bijay Bahadur Pradhan, P. Chunark, Achiraya Chaichaloempreecha, Salony Rajbhandari, Piti Pita

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引用次数: 7

Abstract

This study analyzed energy and technological implications in the energy sector to attain net zero emissions in Thailand by 2050. The study used AIM/Enduse, a bottom-up type energy system model, as an analytical tool. A business-as-usual and a net zero emission scenario are analyzed. Net zero emission scenarios are assessed in terms of net zero greenhouse gas emissions (NZE-GHG). Results show that the GHG emissions from the energy sector in the BAU would reach 635 MtCO2e in 2050. Decarbonization of the energy sector and transition towards net zero emission by 2050 in Thailand would require rapid deployment of renewable energy sources like solar, wind and biomass. In net zero scenario, installed capacity of solar PV and wind for power generation in 2050 would reach 64 GW and 40 GW, respectively. In addition, this study assesses the role of green hydrogen in achieving net zero target. The 200 GW solar capacity would be required to produce green hydrogen for decarbonizing the transport, industrial as well as power sector. The high carbon sequestration from LULUCF sector in Thailand will make it possible to reach net zero emission with carbon dioxide capture and storage (CCS) technology in the energy sector. Additional bioenergy or CCS technologies will need to be deployed in the power sector if the renewables cannot be deployed to the desirable extent.

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泰国实现净零排放的能源系统转型

本研究分析了能源和技术对泰国到2050年实现净零排放的影响。本研究采用自下而上的能源系统模型AIM/Enduse作为分析工具。对一切照常和净零排放情景进行了分析。净零排放情景根据净零温室气体排放(NZE-GHG)进行评估。结果表明，到2050年，BAU能源部门的温室气体排放量将达到6.35亿吨二氧化碳当量。到2050年，泰国能源部门的脱碳和向净零排放过渡需要快速部署太阳能、风能和生物质能等可再生能源。在净零情景下，2050年太阳能光伏和风能发电装机容量将分别达到64吉瓦和40吉瓦。此外，本研究还评估了绿色氢在实现净零目标中的作用。该项目将需要200吉瓦的太阳能发电能力来生产绿色氢，用于运输、工业和电力部门的脱碳。泰国LULUCF部门的高碳固存将使能源部门的二氧化碳捕获和储存(CCS)技术实现净零排放成为可能。如果可再生能源不能达到理想的程度，则需要在电力部门部署额外的生物能源或CCS技术。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Sustainable Energy Planning and Management Social Sciences-Geography, Planning and Development

CiteScore

7.60

自引率

0.00%

发文量

审稿时长

30 weeks

期刊介绍： The journal is an international interdisciplinary journal in Sustainable Energy Planning and Management combining engineering and social science within Energy System Analysis, Feasibility Studies and Public Regulation. The journal especially welcomes papers within the following three focus areas: Energy System analysis including theories, methodologies, data handling and software tools as well as specific models and analyses at local, regional, country and/or global level. Economics, Socio economics and Feasibility studies including theories and methodologies of institutional economics as well as specific feasibility studies and analyses. Public Regulation and management including theories and methodologies as well as specific analyses and proposals in the light of the implementation and transition into sustainable energy systems.