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LEAP-WEAP analysis of urban energy-water dynamic nexus in Beijing (China)

Author

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  • Liu, Gengyuan
  • Hu, Junmei
  • Chen, Caocao
  • Xu, Linyu
  • Wang, Ning
  • Meng, Fanxin
  • Giannetti, Biagio F.
  • Agostinho, Feni
  • Almeida, Cecília M.V. B.
  • Casazza, Marco

Abstract

Based on LEAP and WEAP, this paper establishes the coupled model of energy and water in cities. With Beijing as a case, 26 scenarios are designed to explore the energy saving/water saving of different policies in Beijing in the future and its nexus effect, including the sensitivity analysis of the results. The results show that the total energy consumption in Beijing will grow slowly by year. Carbon emissions will peak in 2020, and fluctuate after 2035 it will slowly increase until 2050. Total water demand is stable between 3.6 and 4.1 billion cubic meters. According to the forecasted water supply capacity, there is no shortage of water supply and demand. The proportion of groundwater from the source of water supply fell to 27%, and the proportion of water in the South-to-North Water Transfer increased to 40%. The total energy saving of the “13th Five-Year Plan” water saving policy is 1.003 million tons of standard coal, which is equivalent to 8.165 billion kWh of electricity. The energy saving policy has reached 276 million cubic meters of water, equivalent to 140 Kunming Lakes. The energy demand of residents' lives, service industry, construction industry and traditional manufacturing industry has a good correlation with water demand value, which proved they are important water-coupled sectors. In terms of energy-saving/water-saving effects in different scenarios and recent/long range periods, the industrial structure optimization policy showed good energy-saving potential in the short-term, but the long-term energy-saving effect was not obvious, while it was accompanied by an increase in water consumption. The irrigation technology innovation and planting structure optimization scenarios in the agricultural sector have better energy saving and water saving effects in the short term. However, with the occurrence and further expansion of water shortage, the medium and long term the water saving effect is sill, while the energy saving effect is not significant. The sensitivity analysis shows that the parameters of the scenario such as economic slowdown, industrial structure optimization, development of public transportation, and planting structure optimization are more sensitive. For the synergistic effect of water and energy conservation, the synergy effect is more obvious in the energy saving scenarios of the service industry and the industrial sector. For the policies of the same department, the synergistic saving effect of the situation of improving energy intensity is obvious. From the perspective of the difficulty in policy implementation process and overview effects, the water saving and energy saving policies of the industrial sector face more difficulties while implementation. The external power regulation policy and the capital rising residents’ wareness of water saving policy has good performance both in the difficulty of implementation and overview effects.

Suggested Citation

  • Liu, Gengyuan & Hu, Junmei & Chen, Caocao & Xu, Linyu & Wang, Ning & Meng, Fanxin & Giannetti, Biagio F. & Agostinho, Feni & Almeida, Cecília M.V. B. & Casazza, Marco, 2021. "LEAP-WEAP analysis of urban energy-water dynamic nexus in Beijing (China)," Renewable and Sustainable Energy Reviews, Elsevier, vol. 136(C).
    • Handle: RePEc:eee:rensus:v:136:y:2021:i:c:s1364032120306572
    DOI: 10.1016/j.rser.2020.110369
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    Cited by:

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    2. El-Sayed, Ahmed Hassan A. & Khalil, Adel & Yehia, Mohamed, 2023. "Modeling alternative scenarios for Egypt 2050 energy mix based on LEAP analysis," Energy, Elsevier, vol. 266(C).
    3. Kılkış, Şiir, 2022. "Urban emissions and land use efficiency scenarios towards effective climate mitigation in urban systems," Renewable and Sustainable Energy Reviews, Elsevier, vol. 167(C).
    4. Lingchun Hou & Yuanping Wang & Yingheng Zheng & Aomei Zhang, 2022. "The Impact of Vehicle Ownership on Carbon Emissions in the Transportation Sector," Sustainability, MDPI, vol. 14(19), pages 1-23, October.
    5. Ana Luiza Fontenelle & Erik Nilsson & Ieda Geriberto Hidalgo & Cintia B. Uvo & Drielli Peyerl, 2022. "Temporal Understanding of the Water–Energy Nexus: A Literature Review," Energies, MDPI, vol. 15(8), pages 1-21, April.
    6. Yuan Liu & Qinliang Tan & Jian Han & Mingxin Guo, 2021. "Energy-Water-Carbon Nexus Optimization for the Path of Achieving Carbon Emission Peak in China Considering Multiple Uncertainties: A Case Study in Inner Mongolia," Energies, MDPI, vol. 14(4), pages 1-21, February.

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