Linkage analysis for the water–energy nexus of city

Applied Energy

Volumn 189, Issue , 2017, Pages 770-779

  Fang, Delin ^a   Chen, Bin ^a  

^a BEIJING NORMAL UNIVERSITY   (China)

Author keywords

Beijing; Linkage analysis; Water energy nexus

Indexed keywords

ECONOMIC ANALYSIS; ENERGY RESOURCES; ENERGY TRANSFER; ENERGY UTILIZATION; FOOD PROCESSING; SUSTAINABLE DEVELOPMENT;

BEIJING; ELECTRICITY PRODUCTION; INTERMEDIATE PRODUCT; LINKAGE ANALYSIS; NATURAL GAS PROCESSING; REAL ESTATE INDUSTRIES; TRANSPORTATION SECTOR; WATER ENERGY;

WATER RESOURCES;

ELECTRICITY GENERATION; ENERGY RESOURCE; FOOD PROCESSING; METROPOLITAN AREA; NATURAL GAS; PETROLEUM; SUSTAINABILITY; URBAN ECONOMY; URBANIZATION; WIND POWER;

BEIJING [CHINA]; CHINA;

EID: 84962792118     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2016.04.020     Document Type: Article

References (43)

1. [1] Bartos, M.D., Chester, M.V., The conservation nexus: valuing interdependent water and energy savings in Arizona. Environ Sci Technol 48 (2014), 2139–2149.
2. [2] Ackerman, F., Fisher, J., Is there a water–energy nexus in electricity generation? Long-term scenarios for the western United States. Energy Policy 59 (2013), 235–241.
3. [3] Macknick, J., Newmark, R., Heath, G., Hallett, K.C., Operational water consumption and withdrawal factors for electricity generating technologies: a review of existing literature. Environ Res Lett, 7, 2012, 045802.
4. [4] Cai, B., Zhang, B., Bi, J., Zhang, W., Energy's thirst for water in China. Environ Sci Technol 48 (2014), 11760–11768.
5. [5] Feng, K., Hubacek, K., Siu, Y.L., Li, X., The energy and water nexus in Chinese electricity production: a hybrid life cycle analysis. Renew Sust Energy Rev 39 (2014), 342–355.
6. [6] Zhang, C., Anadon, L.D., Life cycle water use of energy production and its environmental impacts in China. Environ Sci Technol 47 (2013), 14459–14467.
7. [7] Murray, K.E., State-scale perspective on water use and production associated with oil and gas operations, Oklahoma, U.S. Environ Sci Technol 47 (2013), 4918–4925.
8. [8] Rio Carrillo, A.M., Frei, C., Water: a key resource in energy production. Energy Policy 37 (2009), 4303–4312.
9. [9] Cooper, D.C., Sehlke, G., Sustainability and energy development: influences of greenhouse gas emission reduction options on water use in energy production. Environ Sci Technol 46 (2012), 3509–3518.
10. [10] Scown, C.D., Horvath, A., McKone, T.E., Water footprint of U.S. transportation fuels. Environ Sci Technol 45 (2011), 2541–2553.
11. [11] Zhang, C., Anadon, L.D., Mo, H., Zhao, Z., Liu, Z., Water–carbon trade-off in China's coal power industry. Environ Sci Technol 48 (2014), 11082–11089.
12. [12] Dubreuil, A., Assoumou, E., Bouckaert, S., Selosse, S., Maı¨zi, N., Water modeling in an energy optimization framework – the water-scarce middle east context. Appl Energy 101 (2013), 268–279.
13. [13] Yang, J., Chen, B., Energy–water nexus of wind power generation systems. Appl Energy 169 (2016), 1–13.
14. [14] Zhu, X., Guo, R., Chen, B., Zhang, J., Hayat, T., Alsaedi, A., Embodiment of virtual water of power generation in the electric power system in China. Appl Energ 151 (2015), 345–354.
15. [15] Guo, R., Zhu, X., Chen, B., Yue, Y., Ecological network analysis of the virtual water network within China's electric power system during 2007–2012. Appl Energ 168 (2016), 110–121.
16. [16] Plappally, A.K., Lienhard, V.J.H., Energy requirements for water production, treatment, end use, reclamation, and disposal. Renew Sust Energ Rev 16 (2012), 4818–4848.
17. [17] Mo, W., Wang, R., Zimmerman, J.B., Energy–water nexus analysis of enhanced water supply scenarios: a regional comparison of Tampa Bay, Florida, and San Diego, California. Environ Sci Technol 48 (2014), 5883–5891.
18. [18] Zhou, Y., Zhang, B., Wang, H., Bi, J., Drops of energy: conserving urban water to reduce greenhouse gas emissions. Environ Sci Technol 47 (2013), 10753–10761.
19. [19] Santana, M.V., Zhang, Q., Mihelcic, J.R., Influence of water quality on the embodied energy of drinking water treatment. Environ Sci Technol 48 (2014), 3084–3091.
20. [20] Scott, C.A., Pierce, S.A., Pasqualetti, M.J., Jones, A.L., Montz, B.E., Hoover, J.H., Policy and institutional dimensions of the water–energy nexus. Energ Policy 39 (2011), 6622–6630.
21. [21] DeNooyer, T.A., Peschel, J.M., Zhang, Z., Stillwell, A.S., Integrating water resources and power generation: the energy–water nexus in Illinois. Appl Energ 162 (2016), 363–371.
22. [22] Nanduri, V., Saavedra-Antolínez, I., A competitive Markov decision process model for the energy–water–climate change nexus. Appl Energ 111 (2013), 186–198.
23. [23] Huang, W., Ma, D., Chen, W., Connecting water and energy: Assessing the impacts of carbon and water constraints on China's power sector. Appl Energ 185 (2017), 1497–1505.
24. [24] Scanlon, B.R., Duncan, I., Reedy, R.C., Drought and the water–energy nexus in Texas. Environ Res Lett, 8, 2013, 045033.
25. [25] Scott, C.A., The water–energy–climate nexus: resources and policy outlook for aquifers in Mexico. Water Resour Res, 47, 2011.
26. [26] Wang, J., Rothausen, S.G.S.A., Conway, D., Zhang, L., Xiong, W., Holman, I.P., et al. China's water–energy nexus: greenhouse-gas emissions from groundwater use for agriculture. Environ Res Lett, 7, 2012, 014035.
27. [27] Stokes, J.R., Hendrickson, T.P., Horvath, A., Save water to save carbon and money: developing abatement costs for expanded greenhouse gas reduction portfolios. Environ Sci Technol 48 (2014), 13583–13591.
28. [28] Allan, J.A., ’Virtual water’: a long term solution for water short Middle Eastern economies? School of Oriental and African Studies. 1997, University of London.
29. [29] Feng, K., Hubacek, K., Pfister, S., Yu, Y., Sun, L., Virtual scarce water in China. Environ Sci Technol 48 (2014), 7704–7713.
30. [30] Allan, J.A., Virtual water: a strategic resource global solutions to regional deficits. Ground Water, 2005, 545–546.
31. [31] Cazcarro, I., Duarte, R., Sanchez Choliz, J., Multiregional input-output model for the evaluation of Spanish water flows. Environ Sci Technol 47 (2013), 12275–12283.
32. [32] Hoekstra, A.Y., Mekonnen, M.M., The water footprint of humanity. Proc Natl Acad Sci USA 109 (2012), 3232–3237.
33. [33] Hubacek, K., Guan, D., Barrett, J., Wiedmann, T., Environmental implications of urbanization and lifestyle change in China: Ecological and Water Footprints. J Clean Prod 17 (2009), 1241–1248.
34. [34] Fang, D., Fath, B.D., Chen, B., Scharler, U.M., Network environ analysis for socio-economic water system. Ecol Indic 47 (2014), 80–88.
35. [35] Pfister, S., Bayer, P., Koehler, A., Hellweg, S., Environmental impacts of water use in global crop production: hotspots and trade-offs with land use. Environ Sci Technol 45 (2011), 5761–5768.
36. [36] Liu, Z., Geng, Y., Lindner, S., Zhao, H., Fujita, T., Guan, D., Embodied energy use in China's industrial sectors. Energ Policy 49 (2012), 751–758.
37. [37] Shao, L., Wu, Z., Zeng, L., Chen, Z.M., Zhou, Y., Chen, G.Q., Embodied energy assessment for ecological wastewater treatment by a constructed wetland. Ecol Model 252 (2013), 63–71.
38. [38] Feng, K., Chapagain, A., Suh, S., Pfister, S., Hubacek, K., Comparison of bottom-up and top-down approaches to calculating the water footprints of nations. Econ Syst Res 23 (2011), 371–385.
39. [39] Su, B., Ang, B.W., Low, M., Input–output analysis of CO2emissions embodied in trade and the driving forces: processing and normal exports. Ecol Econ 88 (2013), 119–125.
40. [40] Wang, Y., Zhao, H., Li, L., Liu, Z., Liang, S., Carbon dioxide emission drivers for a typical metropolis using input–output structural decomposition analysis. Energ Policy 58 (2013), 312–318.
41. [41] Duarte, R., Sanchez-Choliz, J., Bielsa, J., Water use in the Spanish economy: an input–output approach. Ecol Econ 43 (2002), 71–85.
42. [42] Sánchez-Chóliz, J., Duarte, R., Analysing pollution by way of vertically integrated coefficients, with an application to the water sector in Aragon. Camb J Econ 27 (2003), 433–448.
43. [43] Beijing Statistical Yearbook. Beijing: China Statistics Press; 2008.