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1. Efficient and Equitable Allocation of Renewable Portfolio Standards Targets Among China's Provinces, Energy Policy, 2019 125: 170-180

2. Promotion Policies for Third Party Financing in Photovoltaic Poverty Alleviation Projects Considering Social Reputation, Journal of Cleaner Production, 2019 211: 350-359

3. Investment strategy of hydrothermal geothermal heating in China under policy, technology and geology uncertainties, Journal of Cleaner Production, 2019 207: 17-29

4. Substitution effect of New-Energy Vehicle Credit Program and Corporate Average Fuel Consumption Regulation for Green-car Subsidy, Energy 2018 152: 223-236

5. Factors influencing the economics of public charging infrastructures for EV ¨CA review, Renewable and Sustainable Energy Reviews, 2018 94: 500-509

6. Policy simulation for promoting residential PV considering anecdotal information exchanges based on social network modelling, Applied Energy, 2018 223: 1¨C10

7. Study on the impacts of sharing business models on economic performance of distributed PV-Battery systems, Energy,2018 161:544-558

8. A review of photovoltaic poverty alleviation projects in China: Current status, challenge, and policy recommendations. Renewable and Sustainable Energy Reviews, 2018 94:214-223.

9. Recycling£¬Mechanisms and Policy Suggestions for Spent Electric Vehicles¡¯ Power Battery -A Case of Beijing, Journal of Cleaner Production, 2018 186: 388-406

10. Investment strategy for underground gas storage facilities based on real option model considering gas market reform in China, Energy Economics, 2018 70:132-142

11. Substitution effect of renewable portfolio standards and renewable energy certificate trading for feed-in tariff, Applied Energy, 2018 227: 426-435

12. Study on crowdfunding¡¯s promoting effect on the expansion of electric vehicle charging piles based on game theory analysis. Applied Energy, 2017 196: 238-248

13. The impacts of market reform on the market penetration of natural gas-fired electricity and renewable energy in China. Petroleum Science, 2017 14(4): 831-841

14. Study on the promotion impact of demand response on distributed PV penetration by using non-cooperative game theoretical analysis. Applied Energy, 2017 185(2): 1869-1878.

15. Study on the promotion of natural gas-fired electricity with energy market reform in China using a dynamic game-theoretic model. Applied Energy, 2017 185[2]: 1832-1839

16. Multi-region optimal deployment of renewable energy considering different interregional transmission scenarios, Energy, 2016 108: 108-118

17. Study on the Impacts of Natural Gas Supply Cost on Gas Flow and Infrastructure Deployment in China, Applied Energy, 2016 162: 1385-1398

18. A scenario analysis of oil and gas consumption in China to 2030 considering the peak CO2 emission constraint, Pet. Sci. 2016 13:370¨C383

19. An integrated scenario analysis for future zero-carbon energy system, International Journal of Energy Research, 2015 39[ 7]: 993¨C1010

20. Review of Japan's Power Generation Scenarios in light of the Fukushima Nuclear Accident, International Journal of Energy Research, 2014 38 [5]: 539¨C550

21. An Integrated Model for Long-Term Power Generation Planning Toward Future Smart Electricity Systems, Applied Energy, 2013 112: 1424-1437

22. A Methodology for Economic and Environmental Analysis of Electric Vehicles with Different Operational Conditions, Energy, 2013 61: 118-127

23. Integration of PV Power into Future Low-Carbon Smart Electricity Systems with EV and HP in Kansai Area, Japan, Renewable Energy, 2012 44: 99¨C108

24. Scenario Analysis on Future Electricity Supply And Demand In Japan, Energy, 2012 38: 376-385

25. An Analysis Methodology for Integrating Renewable and Nuclear Energy Into Future Smart Electricity Systems, International Journal of Energy Research, 2012 36: 1416-1431

26. Economic And Environmental Analysis Of Power Generation Expansion in Japan Considering Fukushima Nuclear Accident Using a Multi-Objective Optimization Model, Energy, 2012 44: 986-995

27. Long-term Planning for Nuclear Power¡¯s Development in Japan for a Zero-Carbon Electricity Generation System by 2100, Fusion Science and Technology, 2012 61: 423-427

28. Cost-benefit Analysis of A Green Electricity System In Japan Considering the Indirect Economic Impacts Of Tropical Cyclones, Energy Policy, 2012 43: 49¨C57

29. Estimation of the Energy Storage Requirement of a Future 100% Renewable Energy System in Japan, Energy Policy, 2012 47: 22-31

30. Methodology to Estimate the Output of a Dual Solar¨CWind Renewable Energy System in Japan, Energy Policy, 2010 38: 7793¨C7802

31. ¡°Ë«»ý·Ö¡±Õþ²ß¶Ô³ËÓóµÉú²úÉ̲ßÂÔÓëÉç»á¸£ÀûÓ°ÏìÑо¿.ϵͳ¹¤³ÌÀíÂÛÓëʵ¼ù£¬2018Äê10Ô¼ÓÃ. 

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36. »ùÓÚ²©ÞÄ·ÖÎöµÄÎÒ¹úÌìÈ»Æø´¢Æø¿â¿ª·¢²ßÂÔ¼°ÔËӪģʽÑо¿[J]. ʯÓÍ¿Æѧͨ±¨, 2016, 1(1): 175-182 £¨´´¿¯ºÅ£©

 

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1. Qi Zhang£¬ Integrated Analyses and Evaluation Support System of Global Energy Systems for Sustainable Development: System Development with a Case Study for Chinese Energy Policy Toward Sustainable Urban Infrastructure in East Asia, pp. 107-129, Kyoto University Press, 2014

2. Qi Zhang, et al. Multi-Objective Optimization Analysis of Post-Fukushima Power Generation Planning in Japan with Considering Nuclear Power¡¯s Risk Cost, Green Energy and Technology 2013, Springer, 2013 (ISBN: 978-4-431-54264-6)

3. Qi Zhang, et al. Long-Term Scenario Analysis of a Future Zero-Carbon Electricity Generation System in Japan, Green Energy and Technology 2011, pp.17-24, Springer, 2011 (ISBN 978-4-431-53910-4)

4. ÕÅÆæ¡¢ÀîÂÉËÉ¡¢ÎÀ½¨Î°£¬¡¶Visual C#Êý¾Ý¿âÏîÄ¿°¸Àýµ¼º½¡·£¬Ç廪´óѧ³ö°æ£¬2005

 

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