«Previous Article|Table of Contents|Next Article»

¡¶µØÇò¿ÆѧÓë»·¾³Ñ§±¨¡·[ISSN:1672-6561/CN:61-1423/P]

Issue:

2025ÄêµÚ03ÆÚ

Page:

397-413

Research Field:

»ÆºÓÁ÷ÓòÉú̬±£»¤ºÍ¸ßÖÊÁ¿·¢Õ¹×¨¿¯(ÉÏ)

Publishing date:

Info

Title:

Review on the Water-energy-food Nexus

Author(s):

SHANG Hai-yang^1*;  HU Yue¹;  SU Fang^2¢k

(1.School of Management,Northwest University of Political Science and Law,Xi'an 710122,Shaanxi,China; 2.School of Economics & Management,Northwest University,Xi'an 710127,Shaanxi,China)

Keywords:

resource management;  water-energy-food;  nexus;  collaboration;  research framework;  sustainable development

PACS:

X24

DOI:

10.19814/j.jese.2024.10039

Abstract:

The complex coupling relationship between the subsystems of water, energy and food were explored, and the origin, connotation, input and output, and influencing factors of water-energy-food nexus were systematically sort out from the perspective of complex synergy, so as to provide theoretical support and practical guidance for the collaborative development of environment, society and economy. The literatures show that the current research involves multiple levels such as coupling association, simulation prediction and safety measurement, and coupling relationship and simulation prediction are still the focus of empirical research. The water-energy-food nexus has undergone a dynamic evolution from single factor to double factor, and even multi-factor factors, and external factors such as society, environment, and culture have been gradually incorporated into the systematic research, and the internal mechanism and external correlation of bond relationship still need to be explored. In the future, it is necessary to further expand the research on the framework of the coupling system of the nexus, accelerate the research on cross-regional and multi-sectoral collaboration, strengthen the research on risk early warning and system resilience, and promote the research on the integration of big data and nexus information, so as to improve the sustainable development of the nexus.

References:

[1] RASUL G,SHARMA B.The Nexus Approach to Water-energy-food Security:An Option for Adaptation to Climate Change[J].Climate Policy,2016,16(6):682-702.
[2] SCOTT C A,KURIAN M,WESCOAT J L.The Water-energy-food Nexus:Enhancing Adaptive Capacity to Complex Global Challenges[M]¡ÎKURIAN M,ARDAKANIAN R.Governing the Nexus.Cham:Spr-inger,2015:15-38.
[3] ADNAN H.The Status of the Water,Food and Energy Nexus in Asia and the Pacific[R].Bangkok:UNE-SCAP,2013.
[4] DOMINGUEZ P.Thinking About Water Differently:Managing the Water-food-energy Nexus[R].Manila:Asian Development Bank,2013.
[5] FAO.The Water-energy-food Nexus:A New Approa-ch in Support of Food Security and Sustainable Agriculture[R].Rome:FAO,2014.
[6] MPANDELI S.Exploring the Relationship Between Water,Energy and Food:Water-energy-food Nexus[J].Water Wheel,2024,13(3):38-39.
[7] ALBRECHT T R,CROOTOF A,SCOTT C A.The Water-energy-food Nexus:A Systematic Review of Methods for Nexus Assessment[J].Environmental Research Letters,2018,13(4):043002.
[8] ALLAN T,KEULERT Z M,WOERTZ E.The Water-food-energy Nexus:An Introduction to Nexus Concepts and Some Conceptual and Operational Problems[J].International Journal of Water Resources Deve-lopment,2015,31(3):301-311.
[9] ELMINSHAWY N A S,OSAMA A,GAGLIANO A,et al.A Technical and Economic Evaluation of Floating Photovoltaic Systems in the Context of the Water-energy Nexus[J].Energy,2024,303:131904.
[10] HOSSEINITABAR S A,SABOUHI F,BOZORGI-AMIRI A.A Resilient Biofuel Supply Chain Design Based on Paulownia and Jatropha Under Uncertainty Considering the Water-energy Nexus[J].Industrial Cro-ps and Products,2024,222(2):119607.
[11] Åí¿¡½Ü.»ÆºÓÁ÷Óò¡°Ë®-ÄÜÔ´-Á¸Ê³¡±Å¦´øϵͳµÄÉú³É»úÖÆ¡¢¼ÛÖµÌåÏÖÓë·¾¶ÖØËÜ[J].µ±´ú¾­¼Ã¹ÜÀí,2021,43(8):76-81.
PENG Jun-jie.The Generating Mechanism,Value Embodiment and Path Reconstruction of the Water-energy-food Nexus in the Yellow River Basin[J].Contemporary Economic Management,2021,43(8):76-81.
[12] WANG Y,XIE Y J,QI L,et al.Synergies Evaluation and Influencing Factors Analysis of the Water-energy-food Nexus from Symbiosis Perspective:A Case Study in the Beijing-Tianjin-Hebei Region[J].Science of the Total Environment,2022,818:151731.
[13] ºÂÁÖ¸Ö,ÓÚ¾²½à,Íõ ƽ,µÈ.ÃæÏò¿É³ÖÐø·¢Õ¹µÄË®-ÄÜÔ´-Á¸Ê³Å¦´ø¹Øϵϵͳ½âÎö¼°ÆäÑо¿¿ò¼Ü[J].µØÀí¿Æѧ½øÕ¹,2023,42(1):173-184.
HAO Lin-gang,YU Jing-jie,WANG Ping,et al.Analysis of the Water-energy-food Nexus System for Sustainable Development and Its Research Framework[J].Progress in Geography,2023,42(1):173-184.
[14] Íõ½¨»ª,ÖìÓÀéª,ÀîÁá»Û,µÈ.Éç»áˮѭ»·ÏµÍ³Ë®-ÄÜ-̼Ŧ´ø¹Øϵ¼°µÍ̼µ÷¿Ø²ßÂÔÑо¿[J].Öйú¹¤³Ì¿Æѧ,2023,25(4):191-201.
WANG Jian-hua,ZHU Yong-nan,LI Ling-hui,et al.Water-energy-carbon Nexus of Social Water Cycle System and Low-carbon Regulation Strategy[J].Strategic Study of CAE,2023,25(4):191-201.
[15] ÍõºìÈð,ÕÔΰ¾²,µË²ÊÔÆ,µÈ.Ë®-ÄÜÔ´-Á¸Ê³Å¦´ø¹ØϵÈô¸ÉÎÊÌâ½âÎö[J].×ÔÈ»×ÊԴѧ±¨,2022,37(2):307-319.
WANG Hong-rui,ZHAO Wei-jing,DENG Cai-yun,et al.Analysis on Issues of Water-energy-food Nexus[J].Journal of Natural Resources,2022,37(2):307-319.
[16] µËÃú½­,Áú°®»ª,Àî ½­,µÈ.Î÷±±ÄÚ½ºÓÁ÷Óò¡°×ÔÈ»-Éç»á-óÒס±ÈýԪˮѭ»·Ä£Ê½½âÎö[J].µØÀíѧ±¨,2020,75(7):1333-1345.
DENG Ming-jiang,LONG Ai-hua,LI Jiang,et al.Theoretical Analysis of ¡°Natural-social-trading¡± Ternary Water Cycle Mode in the Inland River Basin of Northwest China[J].Acta Geographica Sinica,2020,75(7):1333-1345.
[17] BIGGS E M,BRUCE E,BORUFF B,et al.Sustainable Development and the Water-energy-food Nexus:A Perspective on Livelihoods[J].Environmental Scien-ce & Policy,2015,54:389-397.
[18] ±Ï ²©,³Â µ¤,µË Åô,µÈ.ÇøÓòË®×ÊÔ´-ÄÜÔ´-Á¸Ê³ÏµÍ³ñîºÏЭµ÷ÑÝ»¯ÌØÕ÷Ñо¿[J].ÖйúÅ©´åË®ÀûË®µç,2018(2):72-77.
BI Bo,CHEN Dan,DENG Peng,et al.The Evolutio-nary Characteristics Analysis of Coupling and Coordination of Regional Water-energy-food[J].China Rural Water and Hydropower,2018(2):72-77.
[19] ÈÎÐ÷Ñà,ÈÎÓÀÌ©,Îä·½å·,µÈ.ÇøÓòË®-ÄÜÔ´-Á¸Ê³¹ØÁªÏµÍ³Ð­Í¬·¢Õ¹Ä£ÐÍ[J].Ë®ÍÁ±£³Öͨ±¨,2021,41(5):218-225.
REN Xu-yan,REN Yong-tai,WU Fang-chen,et al.Collaborative Development Model of Regional Water-energy-food Nexus[J].Bulletin of Soil and Water Conservation,2021,41(5):218-225.
[20] MONDAL K,CHATTERJEE C,SINGH R.Examining the Coupling and Coordination of Water-energy-food Nexus at a Sub-national Scale in India:Insights from the Perspective of Sustainable Development Goals[J].Sustainable Production and Consumption,2023,43:140-154.
[21] FENG M Q,CHEN Y N,LI Z,et al.Optimisation Model for Sustainable Agricultural Development Based on Water-energy-food Nexus and CO₂ Emissions:A Case Study in Tarim River Basin[J].Energy Conversion and Management,2024,303:118174.
[22] Àî³ÉÓî,ÕÅÊ¿Ç¿.ÖйúÊ¡¼ÊË®-ÄÜÔ´-Á¸Ê³ñîºÏЭµ÷¶È¼°Ó°ÏìÒòËØÑо¿[J].ÖйúÈË¿Ú¡¤×ÊÔ´Óë»·¾³,2020,30(1):120-128.
LI Cheng-yu,ZHANG Shi-qiang.Chinese Provincial Water-energy-food Coupling Coordination Degree and Influencing Factors Research[J].China Population,Resources and Environment,2020,30(1):120-128.
[23] ÍôÖлª,³Â±£»ª.¾­¼ÃÔö³¤-Éú̬»·¾³-ÈË¿Ú¼¯¾Ûʱ¿ÕñîºÏ¼°¿Õ¼äЧӦÑо¿:ÒÔËÉ»¨½­Á÷ÓòΪÀý[J].Éú̬¾­¼Ã,2023,39(7):171-177,186.
WANG Zhong-hua,CHEN Bao-hua.Spatio-temporal Coupling and Spatial Effect of Economic Growth-ecological Environment-population Agglomeration:A Ca-se Study of Songhua River Basin[J].Ecological Eco-nomy,2023,39(7):171-177,186.
[24] Ëï²ÅÖ¾,ºÂ ˧.ÖйúË®-ÄÜ-Á¸Ð­µ÷¶È²â¶È¼°²îÒìÐÔÓÅ»¯µ÷¿Ø[J].ÈËÃñ³¤½­,2023,54(5):12-20.
SUN Cai-zhi,HAO Shuai.Coordination Degree and Di-fferential Optimizing of Water-energy-food System in China[J].Yangtze River,2023,54(5):12-20.
[25] ´Þ²Ý²Ý,Íõ ÔÏ,ÍõÎıò.ÖйúË®-ÄÜÔ´-Á¸Ê³-Éú̬ϵͳЭµ÷·¢Õ¹Ê±¿Õ¸ñ¾Ö¼°Çý¶¯ÒòËØÑо¿[J].»ª±±Ë®ÀûË®µç´óѧѧ±¨(Éç»á¿Æѧ°æ),2024,40(4):12-26.
CUI Cao-cao,WANG Yun,WANG Wen-bin.Resear-ch on the Spatio-temporal Pattern and Driving Factors of Coordinated Development of China's Water-energy-food-ecosystem[J].Journal of North China University of Water Resources and Electric Power(Social Science Edition),2024,40(4):12-26.
[26] EGIEYA J M,PARKER Y,HOFMANN V S,et al.Predictive Simulation of the Water-energy-food Nexus for the City of Cape Town[J].Science of the Total Environment,2024,934:173289.
[27] FU Y B,REN Y T,PEI W.Evaluation of the Symbiosis Level of the Water-energy-food Complex System Based on the Improved Cloud Model:A Case Study in Heilongjiang Province[J].Environmental Science and Pollution Research International,2023,30(9):22963-22984.
[28] DIAS I Y P,LAZARO L L B,BARROS V G.Water-energy-food Security Nexus:Estimating Future Water Demand Scenarios Based on Nexus Thinking:The Watershed as a Territory[J].Sustainability,2023,15(9):7050.
[29] Íõ»ÛÃô,ºé ¿¡,Áõ ¸Ö.¡°Ë®-ÄÜÔ´-Á¸Ê³¡±Å¦´ø¹ØϵÏÂÇøÓòÂÌÉ«·¢Õ¹Õþ²ß·ÂÕæÑо¿[J].ÖйúÈË¿Ú¡¤×ÊÔ´Óë»·¾³,2019,29(6):74-84.
WANG Hui-min,HONG Jun,LIU Gang.Simulation Research on Different Policies of Regional Green Development Under the Nexus of Water-energy-food[J].China Population,Resources and Environment,2019,29(6):74-84.
[30] VALENCIA A,ZHANG W,CHANG N B.Sustainability Transitions of Urban Food-energy-water-waste Infrastructure:A Living Laboratory Approach for Circular Economy[J].Resources,Conservation and Recycling,2022,177:105991.
[31] MARTINEZ-HERNANDEZ E,LEACH M,YANG A D.Understanding Water-energy-food and Ecosystem Interactions Using the Nexus Simulation Tool NexSym[J].Applied Energy,2017,206:1009-1021.
[32] ÁõÁèÑà,Íõ»ÛÃô,Áõ ¸Ö,µÈ.¹©ÐèÊÓ½ÇÏÂË®-ÄÜÔ´-Á¸Ê³ÏµÍ³·çÏÕµÄÇý¶¯»úÀíÓëÕþ²ß·ÂÕæ:ÃæÏò¶«±±ÈýÊ¡µÄϵͳ¶¯Á¦Ñ§·ÖÎö[J].Èí¿Æѧ,2020,34(12):52-60.
LIU Ling-yan,WANG Hui-min,LIU Gang,et al.Driving Mechanism and Policy Simulation of Water-energy-food Risks from the Perspective of Supply and Demand:A Case Study of Northeast China for System Dynamics Analysis[J].Soft Science,2020,34(12):52-60.
[33] OUYANG Y R,CAI Y P,XIE Y L,et al.Multi-scale Simulation and Dynamic Coordination Evaluation of Water-energy-food and Economy for the Pearl River Delta City Cluster in China[J].Ecological Indicators,2021,130:108155.
[34] Ëï²ÅÖ¾,ÖÜ ÖÛ,ÕÔÁ¼ÊË.»ùÓÚSDÄ£Ð͵ÄÖйúÎ÷ÄÏË®-ÄÜÔ´-Á¸Ê³Å¦´øϵͳ·ÂÕæÄ£Äâ[J].¾­¼ÃµØÀí,2021,41(6):20-29.
SUN Cai-zhi,ZHOU Zhou,ZHAO Liang-shi.System Simulation of Water-energy-food in Southwest China Based on SD Model[J].Economic Geography,2021,41(6):20-29.
[35] ïú ¾ê,³Â¾ü·É,µËÃλª,µÈ.ÂÌÉ«·¢Õ¹Ï³¤Èý½ÇµØÇøË®-ÄÜÔ´-Á¸Ê³-Éú̬ϵͳ·ÂÕæºÍÓÅ»¯Ñо¿[J].Èí¿Æѧ,2023,37(5):105-114.
JI Juan,CHEN Jun-fei,DENG Meng-hua,et al.Simulation and Optimization of Water-energy-food-ecology System for Green Development in the Yangtze River Delta[J].Soft Science,2023,37(5):105-114.
[36] LIU H Y,ZHANG X,DENG L K,et al.A Simulation and Risk Assessment Framework for Water-energy-environment Nexus:A Case Study in the City Cluster Along the Middle Reach of the Yangtze River,China[J].Science of the Total Environment,2024,912:169212.
[37] PURWANTO A,SUSNIK J,SURYADI F X,et al.Quantitative Simulation of the Water-energy-food(WEF)Security Nexus in a Local Planning Context in Indonesia[J].Sustainable Production and Consum-ption,2021,25:198-216.
[38] MUHIRWA F,SHEN L,ELSHKAKI A,et al.Ecological Balance Emerges in Implementing the Water-energy-food Security Nexus in Well-developed Countries in Africa[J].Science of the Total Environment,2022,833:154999.
[39] MPEREJEKUMANA P,SHEN L,ZHONG S,et al.Assessing the Capacity of the Water-energy-food Nexus in Enhancing Sustainable Agriculture and Food Secu-rity in Burundi[J].Sustainability,2023,15(19):14117.
[40] LU S B,LU W J,XU M,et al.Water-energy-food Security Under Green Finance Constraints in Southwest China[J].Energy Economics,2023,118:106478.
[41] ÍõÓñ±¦,ÆÑ°ÁæÃ,ãÆ ÐÇ,µÈ.н®Ë®-ÄÜÔ´-Á¸Ê³ÏµÍ³°²È«×ÛºÏÆÀ¼Û[J].Å©Òµ»úеѧ±¨,2020,51(6):264-272.
WANG Yu-bao,PU Ao-ting,YAN Xing,et al.Comprehensive Evaluation of Water-energy-food Nexus Safety in Xinjiang[J].Transactions of the Chinese Society for Agricultural Machinery,2020,51(6):264-272.
[42] ¸Ç ÃÀ,µÔÓðÜç.ÖйúË®×ÊÔ´-ÄÜÔ´-Á¸Ê³-Ö§³Åϵͳ°²È«²â¶È¼°Ð­µ÷·¢Õ¹[J].Éú̬ѧ±¨,2021,41(12):4746-4756.
GAI Mei,ZHAI Yu-qian.Measurement and Coordinated Development of Water Resources,Energy,Food and Support Security in China[J].Acta Ecologica Si-nica,2021,41(12):4746-4756.
[43] ³Ê˱¦,ÉÐÒãè÷,Íõ ºÆ.»ùÓÚÐÞÕýË®×ÊԴѹÁ¦Ö¸ÊýµÄ»ª¶«µØÇøË®-ÄÜ-Á¸Ð­Í¬°²È«ÆÀ¹À[J].¸ÉºµÇø×ÊÔ´Óë»·¾³,2022,36(2):68-77.
LU Shi-bao,SHANG Yi-zi,WANG Hao.Assessment on Water-energy-grain Collaborative Security in East China Based on Modified Water Resource Pressure Index[J].Journal of Arid Land Resources and Environment,2022,36(2):68-77.
[44] Íõ ºã,·½ À¼.ÖйúË®-ÄÜÔ´-Á¸Ê³Å¦´øϵͳ°²È«Ë®Æ½ÓëÈ«ÒªËØÉú²úÂÊʱ¿ÕñîºÏЭµ÷¹Øϵ·ÖÎö[J].Ë®×ÊÔ´±£»¤,2023,39(1):150-157.
WANG Heng,FANG Lan.Spatial-temporal Coupling Coordination Relationship Between the Security Level of Water-energy-food Nexus System and Total Factor Productivity in China[J].Water Resources Protection,2023,39(1):150-157.
[45] Àî œÕ,½ª ɺ,ÕÔ ÓÂ,µÈ.¾©½ò¼½Ë®-ÄÜÔ´-Á¸Ê³ñîºÏϵͳ°²È«ÆÀ¼Û[J].Ë®×ÊÔ´±£»¤,2023,39(5):39-48.
LI Wei,JIANG Shan,ZHAO Yong,et al.Safety Eva-luation of Water-energy-food Coupling System in Beijing-Tianjin-Hebei Region[J].Water Resources Protection,2023,39(5):39-48.
[46] NAIDOO D,NHAMO L,MPANDELI S,et al.Ope-rationalising the Water-energy-food Nexus Through the Theory of Change[J].Renewable and Sustainable Energy Reviews,2021,149:111416.
[47] ÁõöÎîÚ,Íõ ß®,ºØ ±ó,µÈ.»ùÓÚË®¡¢Ì¼×ã¼£µÄÂÌÖÞСÂóÉú²ú»·¾³Ó°ÏìÌØÕ÷¼°ÆäÍѹ³¹Øϵ:ÒÔн®Ò¶¶ûǼºÓÁ÷Óòɯ³µ¹àÇøΪÀý[J].µØÇò¿ÆѧÓë»·¾³Ñ§±¨,2023,45(4):869-880.
LIU Xin-yu,WANG Yi,HE Bin,et al.Characteristics of Environmental Impact for Wheat Production and Their Decoupling Relationship in Oasis Irrigation Area Based on Water and Carbon Footprints:Taking Shache Irrigation District in Yarkant River Basin of Xinjiang,China as an Example[J].Journal of Earth Sciences and Environment,2023,45(4):869-880.
[48] Éк£Ñó,ËÎÄÝÄÝ.̼×ã¼£ÓëË®×ã¼£µÄ¸ÅÄî¡¢Ñо¿·½·¨ºÍÓ¦¶ÔÕþ²ß±È½Ï[J].Ë®×ÊÔ´±£»¤,2018,34(2):15-21.
SHANG Hai-yang,SONG Ni-ni.Carbon Footprint and Water Footprint:Comparison of Concepts,Methods,and Policy Responses[J].Water Resources Protection,2018,34(2):15-21.
[49] µË Åô,³Â ݼ,³Â µ¤,µÈ.ÇøÓòË®-ÄÜÔ´-Á¸Ê³ñîºÏЭµ÷ÑÝ»¯ÌØÕ÷Ñо¿:ÒÔ½­ËÕʡΪÀý[J].Ë®×ÊÔ´ÓëË®¹¤³Ìѧ±¨,2017,28(6):232-238.
DENG Peng,CHEN Jing,CHEN Dan,et al.The Evolutionary Characteristics Analysis of the Coupling and Coordination Among Water,Energy and Food:Take Jiangsu Province as an Example[J].Journal of Water Resources and Water Engineering,2017,28(6):232-238.
[50] EVANS B,KHOURY M,VAMVAKERIDOU-LYROUDIA L,et al.A Modelling Testbed to Demonstrate the Circular Economy of Water[J].Journal of Cleaner Production,2023,405:137018.
[51] WANG Q,LI S Q,HE G,et al.Evaluating Sustainability of Water-energy-food(WEF)Nexus Using an Improved Matter-element Extension Model:A Case Study of China[J].Journal of Cleaner Production,2018,202:1097-1106.
[52] HE L Y,XU Z C,WANG S F,et al.Optimal Crop Planting Pattern Can Be Harmful to Reach Carbon Neutrality:Evidence from Food-energy-water-carbon Nexus Perspective[J].Applied Energy,2022,308:118364.
[53] MILLER L,CARRIVEAU R.Balancing the Carbon and Water Footprints of the Ontario Energy Mix[J].Energy,2017,125:562-568.
[54] ÐìÅÎÅÎ,³Â ˶,ÂíºÆÔ·,µÈ.»ùÓÚDPSIRÄ£Ð͵ÄÇØÁ뱱´ÉÂÎ÷³ÇÊÐȺˮ°²È«ÆÀ¹À¼°Çý¶¯Òò×Óʶ±ð[J].µØÇò¿ÆѧÓë»·¾³Ñ§±¨,2024,46(2):143-153.
XU Pan-pan,CHEN Shuo,MA Hao-yuan,et al.Assessment of Water Security and Identification of Driving Factors for Shaanxi Urban Agglomeration in the Northern Foothills of Qinling Mountains,China Based on DPSIR Model[J].Journal of Earth Sciences and Environment,2024,46(2):143-153.
[55] ÕÅ×ÚÓÂ,Áõ¿¡¹ú,Íõ ¿­,µÈ.Ë®-Á¸Ê³-ÄÜÔ´¹ØÁªÏµÍ³ÊöÆÀ:ÎÄÏ×¼ÆÁ¿¼°½âÎö[J].¿Æѧͨ±¨,2020,65(16):1569-1581.
ZHANG Zong-yong,LIU Jun-guo,WANG Kai,et al.A Review and Discussion on the Water-food-energy Nexus:Bibliometric Analysis[J].Chinese Science Bulletin,2020,65(16):1569-1581.
[56] Ëï²ÅÖ¾,½ù´ºÓñ,ºÂ ˧.»ÆºÓÁ÷ÓòË®×ÊÔ´-ÄÜÔ´-Á¸Ê³Å¦´ø¹ØϵÑо¿[J].ÈËÃñ»ÆºÓ,2020,42(9):101-106.
SUN Cai-zhi,JIN Chun-yu,HAO Shuai.Study on Water-energy-food Nexus Relationship of the Yellow River Basin[J].Yellow River,2020,42(9):101-106.
[57] ZHANG T,TAN Q,YU X N,et al.Synergy Assessment and Optimization for Water-energy-food Nexus:Modeling and Application[J].Renewable and Sustainable Energy Reviews,2020,134:110059.
[58] YANG X C,WANG Y T,SUN M X,et al.Exploring the Environmental Pressures in Urban Sectors:An Energy-water-carbon Nexus Perspective[J].Applied Energy,2018,228:2298-2307.
[59] ÖÜ º½,ÕÔÏȳ¬.ÏØÓò³ß¶ÈϺþÄÏʡ̼ÅÅ·Å¿Õ¼ä·ÖÒìÌØÕ÷ÓëÓ°ÏìÒòËØ[J].µØÇò¿ÆѧÓë»·¾³Ñ§±¨,2024,46(2):196-210.
ZHOU Hang,ZHAO Xian-chao.Spatial Differentiation Characteristics of Carbon Emission and Its Influencing Factors in Hunan Province,China at the County Scale[J].Journal of Earth Sciences and Environment,2024,46(2):196-210.
[60] κ ŽU,Ò¶³¤Ê¢,²Ì öÎ,µÈ.»ùÓÚÉú̬ÍøÂç·ÖÎöÄ£Ð͵ÄÎ人ÊС°ÈýÉú¿Õ¼ä¡±Ì¼´úлÌØÕ÷[J].µØÇò¿ÆѧÓë»·¾³Ñ§±¨,2024,46(4):528-543.
WEI Wei,YE Chang-sheng,CAI Xin,et al.Characte-ristics of Carbon Metabolism of Production-living-eco-logical Space in Wuhan City of Hubei Province,China Based on Ecological Network Analysis Model[J].Journal of Earth Sciences and Environment,2024,46(4):528-543.
[61] ñû Ïæ,ÖÜ ºÆ,Ñî Ñï.ºâÉ۸ɺµ×ßÀÈ¡°Ë®-ÄÜ-Á¸-Éú¡±ÏµÍ³·ÂÕæ¼°ÓÅ»¯Ñо¿[J].Ë®ÍÁ±£³ÖÑо¿,2025,32(4):405-417.
TAN Xiang,ZHOU Hao,YANG Yang.Study on the Simulation and Optimization of Water-energy-food-ecology System in the Heng Shao Arid Corridor[J].Research of Soil and Water Conservation,2025,32(4):405-417.
[62] Íõ ·Æ,²ÜÓÀÇ¿,·¶Ë§°î.¡°Ë«Ì¼¡±Ä¿±ê϶«±±ÈýÊ¡Ë®-ÄÜԴŦ´ø¹Øϵ¼°ÍøÂçÌØÕ÷·ÖÎö[J].Éú̬ѧ±¨,2022,42(14):5692-5707.
WANG Fei,CAO Yong-qiang,FAN Shuai-bang.Analysis of Water-energy Ties and Network Characteristics in the Three Provinces of Northeast China Under the ¡°Double Carbon¡± Target[J].Acta Ecologica Sinica,2022,42(14):5692-5707.
[63] Àî¿ÉÐÀ,²ÜÓÀÇ¿,·¶Ë§°î,µÈ.¶«±±ÈýÊ¡¡°Ë®-ÄÜÔ´-̼¡±ÏµÍ³·ÂÕæÄ£Äâ:»ùÓÚϵͳ¶¯Á¦Ñ§Ä£ÐÍ[J].Éú̬ѧ±¨,2023,43(17):6999-7011.
LI Ke-xin,CAO Yong-qiang,FAN Shuai-bang,et al.Simulation of Water-energy-carbon in Northeast China Based on System Dynamics Model[J].Acta Ecologica Sinica,2023,43(17):6999-7011.
[64] YOON P R,LEE S H,CHOJ J Y,et al.Analysis of Climate Change Impact on Resource Intensity and Carbon Emissions in Protected Farming Systems Us-ing Water-energy-food-carbon Nexus[J].Resources,Conservation and Recycling,2022,184:106394.
[65] FETANAT A,TAYEBI M,MOFID H.Water-energy-carbon Nexus and Sustainability-oriented Priori-tization of Negative Emissions Technologies for the Oil & Gas Industry:A Decision Support System Under Fermatean Fuzzy Environment[J].Process Safety and Environmental Protection,2023,179:462-483.
[66] GARCIA D J,LOVETT B M,YOU F Q.Considering Agricultural Wastes and Ecosystem Services in Food-energy-water-waste Nexus System Design[J].Journal of Cleaner Production,2019,228:941-955.
[67] LUCCA E,EL JEITANY J,CASTELLI G,et al.A Review of Water-energy-food-ecosystems Nexus Research in the Mediterranean:Evolution,Gaps and Applications[J].Environmental Research Letters,2023,18(8):083001.
[68] Áõ éª,Ãű¦»Ô,ÀöÄÈ¡¤Íпâ,µÈ.¾©½ò¼½µØÇøË®-ÄÜ-Á¸-̼Ŧ´ø¹Øϵ¼°°²È«Ì½¾¿[J].Ë®Á¦·¢µçѧ±¨,2025,44(3):62-75.
LIU Nan,MEN Bao-hui,TUOKU Lina,et al.Exploring Water-energy-food-carbon Nexus and Security in Beijing-Tianjin-Hebei Region[J].Journal of Hydroelectric Engineering,2025,44(3):62-75.
[69] ËÎ ½à,»Æ¾²Ë¼,ºÎ¹Úéª,µÈ.Ë®-ÄÜÔ´-Á¸Ê³Å¦´øϵͳµÄ·çÏÕ²â¶ÈÓëÈÍÐÔÌáÉýÑо¿[J].Öйú¹ÜÀí¿Æѧ,2025,33(1):323-334.
SONG Jie,HUANG Jing-si,HE Guan-nan,et al.Risk Measurement and Resilience Improvement of Water-energy-food Coupling Systems[J].Chinese Journal of Management Science,2025,33(1):323-334.
[70] Àî œÕ,ÕÔ ÓÂ,½ª ɺ,µÈ.»ùÓÚÎÄÏ×¼ÆÁ¿·ÖÎöµÄË®¡¢ÄÜÔ´ºÍÁ¸Ê³Å¦´ø¹ØϵÑо¿½øÕ¹[J].Éú̬ѧ±¨,2024,44(17):7909-7922.
LI Wei,ZHAO Yong,JIANG Shan,et al.Research Progress on the Water,Energy,and Food Nexus Ba-sed on Bibliometric Analysis[J].Acta Ecologica Sinica,2024,44(17):7909-7922.
[71] ÍõÓ¢½Ü,Íõ»ª´º.»ÆºÓÁ÷ÓòË®¡¢ÄÜÔ´¡¢Ê³ÎïÕþ²ßÕûºÏ³Ì¶È¡¢Ä£Ê½Óë½á¹¹[J].ÖйúÈË¿Ú¡¤×ÊÔ´Óë»·¾³,2024,34(6):173-186.
WANG Ying-jie,WANG Hua-chun.Degree,Patterns,and Structure of Water,Energy and Food Policy Integration in the Yellow River Basin[J].China Population Resources and Environment,2024,34(6):173-186.
[72] AJJUR S B,AL-GHAMDI S G.Towards Sustainable Energy,Water and Food Security in Qatar Under Climate Change and Anthropogenic Stresses[J].Energy Reports,2022,8(S3):514-518.
[73] Éк£Ñó,ºú «h,Íõ Ò¢,µÈ.ÍÁµØÕþ²ßÑо¿µÄ¹úÄÚ½øÕ¹¼°Ç÷ÊÆ:»ùÓÚ1992¡«2024Äê·¢±íµÄ8 537ƪÎÄÏ׵ķÖÎö[J].µØÇò¿ÆѧÓë»·¾³Ñ§±¨,2024,46(4):454-469.
SHANG Hai-yang,HU Yue,WANG Yao,et al.Domestic Research Progress and Trend of Land Policy:Based on 8 537 Literatures Published from 1992 to 2024[J].Journal of Earth Sciences and Environment,2024,46(4):454-469.
[74] KONDASH A J,HERRERA I,CASTELLANOS E,et al.Food,Energy,and Water Nexus Research in Guatemala:A Systematic Literature Review[J].Environmental Science & Policy,2021,124:175-185.
[75] ¹Ø öÎ,κçûÏè,ÁºÔóºã,µÈ.Ë®-ÄÜÔ´-Á¸Ê³¹ØÁªµÄÖйúÁ¸Ê³°²È«ÀíÂÛ¹¹½¨[J].ÖйúÅ©Òµ×ÊÔ´ÓëÇø»®,2025,46(2):1-13.
GUAN Xin,WEI Kun-xiang,LIANG Ze-heng,et al.Construction of China's Food Security Theory of Water-energy-food Correlation[J].Chinese Journal of Agricultural Resources and Regional Planning,2025,46(2):1-13.
[76] ¶¡Í¯»Û,³Â¾ü·É,ïú ¾ê,µÈ.Ë®-ÄÜÔ´-Á¸Ê³Å¦´ø¹ØϵÓëÉú̬ϵͳ·þÎññîºÏÑо¿½øÕ¹[J].Éú̬ѧ±¨,2025,45(6):3032-3045.
DING Tong-hui,CHEN Jun-fei,JI Juan,et al.Resear-ch Progress and Prospect of the Coupling Between Water-energy-food Nexus and Ecosystem Services[J].Acta Ecologica Sinica,2025,45(6):3032-3045.
[77] ÍõÞȼÑ,ÁõìÍÐò,ËΠˬ,µÈ.Ë®-Á¸Ê³-ÄÜÔ´-Éú̬ϵͳ¹ØÁªÑо¿½øÕ¹[J].µØÇò¿Æѧ½øÕ¹,2021,36(7):684-693.
WANG Yi-jia,LIU Yan-xu,SONG Shuang,et al.Research Progress of the Water-food-energy-ecosystem Nexus[J].Advances in Earth Science,2021,36(7):684-693.
[78] ÁõÀèÃ÷,³Â¾ü·É,Íõ´º±¦.³¤½­¾­¼Ã´øË®-ÄÜÔ´-Á¸Ê³-Éú̬´àÈõÐÔʱ¿ÕÌØÕ÷¼°Ó°Ïì»úÖÆ[J].³¤½­Á÷Óò×ÊÔ´Óë»·¾³,2023,32(8):1628-1640.
LIU Li-ming,CHEN Jun-fei,WANG Chun-bao.Spatio-temporal Evolution and Influencing Mechanism of Water-energy-food-ecology Vulnerability:A Case Stu-dy of Yangtze River Economic Belt,China[J].Resources and Environment in the Yangtze River Basin,2023,32(8):1628-1640.
[79] RADINI S,MARINELLI E,AKYOL C,et al.Urban Water-energy-food-climate Nexus in Integrated Wa-stewater and Reuse Systems:Cyber-physical Framework and Innovations[J].Applied Energy,2021,298:117268.
[80] CRISTIANO E,DEIDDA R,VIOLA C.The Role of Green Roofs in Urban Water-energy-food-ecosystem Nexus:A Review[J].Science of the Total Environment,2021,756:143876.
[81] ÕÅ Óî,¶Å¹úÃ÷,ÀîÏ×Óî.¶«±±µØÇø¸ûµØÂÌÉ«ÀûÓÃЧÂʲâËã¼°Ó°ÏìÒòËØ[J].µØÇò¿ÆѧÓë»·¾³Ñ§±¨,2024,46(4):486-498.
ZHANG Yu,DU Guo-ming,LI Xian-yu.Estimation and Influencing Factors of Green Utilization Efficiency of Cultivated Land in Northeast China[J].Journal of Earth Sciences and Environment,2024,46(4):486-498.
[82] Íõ ÓÂ,ËïÈðÐÀ.ÍÁµØÀûÓñ仯¶ÔÇøÓòË®-ÄÜÔ´-Á¸Ê³ÏµÍ³ñîºÏЭµ÷¶ÈµÄÓ°Ïì:ÒÔ¾©½ò¼½³ÇÊÐȺΪÑо¿¶ÔÏó[J].×ÔÈ»×ÊԴѧ±¨,2022,37(3):582-599.
WANG Yong,SUN Rui-xin.Impact of Land Use Change on Coupling Coordination Degree of Regional Water-energy-food System:A Case Study of Beijing-Tianjin-Hebei Urban Agglomeration[J].Journal of Natural Resources,2022,37(3):582-599.
[83] ºÎÊçæÃ,ÍõÐãÀö,Àî³ÌÐã,µÈ.ºÓÄÏÊ¡Ë®-ÄÜÔ´-Á¸Ê³-ÍÁµØϵͳñîºÏЭµ÷ÐÔÑо¿[J].ÖйúÅ©Òµ×ÊÔ´ÓëÇø»®,2023,44(12):116-130.
HE Shu-ting,WANG Xiu-li,LI Cheng-xiu,et al.Stu-dy on the Coupling Coordination of Water-energy-food-land System in Henan Province[J].Chinese Journal of Agricultural Resources and Regional Planning,2023,44(12):116-130.
[84] ¹ËÜÔÀò,Ò¶³¤Ê¢,Â¥æÃæÃ,µÈ.³¤½­¾­¼Ã´øË®×ÊÔ´-ÄÜÔ´-Á¸Ê³-ÍÁµØñîºÏЭµ÷·¢Õ¹Ñо¿[J].ÈËÃñ³¤½­,2023,54(6):11-18,40.
GU Mo-li,YE Chang-sheng,LOU Ting-ting,et al.Coupling Mechanism of Coordinated Development of Land Use and Water-energy-food Systems in Yangtze River Economic Belt[J].Yangtze River,2023,54(6):11-18,40.
[85] FENG T T,LIU B,REN H R,et al.Optimized Model for Coordinated Development of Regional Sustainable Agriculture Based on Water-energy-land-carbon Ne-xus System:A Case Study of Sichuan Province[J].Energy Conversion and Management,2023,291:117261.
[86] ELAGIB N A,AL-SAIDI M.Balancing the Benefits from the Water-energy-land-food Nexus Through Ag-roforestry in the Sahel[J].Science of the Total Environment,2020,742:140509.

Memo

Memo:

-

Common functions

Last Update: 2025-06-20