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2. Exploring water-saving potentials of US electric power transition while thirsting for carbon neutrality. (2024). Xu, Zhongwen ; Tan, Shiqi ; Yao, Liming ; Lv, Chengwei.
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3. Carbon emission reduction potential and its influencing factors in China’s coal-fired power industry: a cost optimization and decomposition analysis. (2022). An, Yunfei ; Wang, Qunwei ; Zhou, Dequn.
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4. What drives the temporal and spatial differences of CO2 emissions in the transport sector? Empirical evidence from municipalities in China. (2021). Liu, Xianmei ; Peng, Rui ; Guo, Pibin ; Wang, Mingyue ; Zhong, Chao.
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5. Multitemporal LMDI Index Decomposition Analysis to Explain the Changes of ACI by the Power Sector in Latin America and the Caribbean between 1990–2017. (2020). de Oliveira-De, Paulo M ; Yusta, Jose M ; Galvis, John J ; Rojas-Lozano, Daniela.
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6. Effect of generation capacity factors on carbon emission intensity of electricity of Latin America & the Caribbean, a temporal IDA-LMDI analysis. (2019). de Oliveira-De, Paulo M.
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7. Reasons for recent stagnancy of carbon emissions in Chinas industrial sectors. (2019). Gao, Ziyan ; Liu, Zhiqing ; Geng, Yong ; Cui, Xiaowei ; Wu, Rui.
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8. Index decomposition analysis for comparing emission scenarios: Applications and challenges. (2019). Ang, B.W. ; Goh, Tian ; Wang, B.
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9. Driving factors of carbon emissions in China: A joint decomposition approach based on meta-frontier. (2019). Zhou, Peng ; Su, Xuelin ; Shi, Junxue ; Wang, Hui ; Liu, Bingquan.
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10. Changes in energy-related carbon dioxide emissions of the agricultural sector in China from 2005 to 2013. (2018). Cheng, Shulei ; Song, Malin.
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11. Impact of quota decline scheme of emission trading in China: A dynamic recursive CGE model. (2018). Lin, Boqiang ; Jia, Zhijie.
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12. Quantifying drivers of CO2 emissions from electricity generation – Current practices and future extensions. (2018). Ang, B.W. ; Xu, X Y ; Goh, Tian ; Wang, B.
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    RePEc:eee:appene:v:231:y:2018:i:c:p:1191-1204.

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13. Factors Affecting Transportation Sector CO 2 Emissions Growth in China: An LMDI Decomposition Analysis. (2017). Liang, YI ; Wang, Haichao ; Niu, Dongxiao.
    In: Sustainability.
    RePEc:gam:jsusta:v:9:y:2017:i:10:p:1730-:d:113553.

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2. Carbon mitigation potential and economic benefits of biomass co-firing in coal-fired power plants: A case study in Nanjing, China. (2025). Li, Zhen ; Yan, Yuting ; Wang, Hongkui ; Zhao, Dongliang ; Zhou, Zheng ; Fu, Yao ; Cao, Zhi.
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3. The future of coal-fired power plants in China to retrofit with biomass and CCS: A plant-centered assessment framework considering land competition. (2025). Lu, XI ; Zhou, Hewen ; Wang, Qingrui ; Yang, Qing ; Deng, AN ; Sun, Yunqi ; Chen, Hanping ; Meng, Wenchuan.
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27. Decomposition and scenario analysis of CO2 emissions in China’s power industry: based on LMDI method. (2017). Zhao, Yuhuan ; Zhang, Yongfeng ; Liu, YA ; Wang, Song.
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28. Vision 2023: Status quo and future of biomass and coal for sustainable energy generation in Turkey. (2017). Melikoglu, Mehmet.
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29. Physicochemical structure and gasification reactivity of co-pyrolysis char from two kinds of coal blended with lignocellulosic biomass: Effects of the carboxymethylcellulose sodium. (2017). Luo, Zhengyuan ; Yang, Wangcai ; Wang, Shuzhong ; Chen, Lin ; Zhao, Jun ; Meng, Haiyu ; Wu, Zhiqiang.
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