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Frontiers of Engineering Management

, Volume 6, Issue 1, pp 87–101 | Cite as

Internal incentives and operations strategies for the water-saving supply chain with cap-and-trade regulation

  • Zhisong Chen
  • Li Fang
  • Huimin WangEmail author
Research Article

Abstract

Faced with the rapid development of modern industries of agriculture, manufacturing, and services, water resources are becoming increasingly scarce. Industries with high water consumption are generally regulated by the government’s water cap-and-trade (CAT) regulation to solve the contradiction between the limited water supply and the rapid growing water demand. Supply chain equilibrium and coordination models under the benchmark scenario without water saving and CAT regulation, water-saving supply chain equilibrium and coordination models under the scenario without/with CAT regulation are developed, analyzed and compared. The corresponding numerical and sensitivity analyses for all models are conducted and compared, and the managerial insights and policy recommendations are summarized in this article. The results indicate that (1) Conducting water saving could improve effectively the operational performance of the water-saving supply chain under the scenario without/with CAT regulation. (2) The coordination strategy based on the revenue sharing contract could efficiently coordinate the water-saving supply chain, enhance water consumption reduction rate, and improve the operational performance of the water-saving supply chain. (3) The implementation of CAT regulation enhances effectively water-consumption-reduction in the water-saving supply chain and improves the operational performance of water-saving supply chain. (4) Simultaneous implementation of CAT regulation by the government and adopting coordination strategy by the water-saving supply chain would be superior to any other scenarios/strategies. (5) A suitable water cap based on the industrial average water consumption and historical water consumption data are beneficial for constructing reasonable and effective incentive mechanism. (6) A higher marginal trade price could induce more reduction in water consumption and create better operational performance for the manufacturer and water-saving supply chain, both under the equilibrium and coordination strategies.

Keywords

water-saving supply chain equilibrium coordination internal incentive cap and trade regulation 

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References

  1. Campisano A, D’Amico G, Modica C (2017). Water saving and cost analysis of large-scale implementation of domestic rain water harvesting in minor Mediterranean Islands. Water (Basel), 9(12): 1–14Google Scholar
  2. Gao H, Wei T, Lou I, Yang Z, Shen Z, Li Y (2014). Water saving effect on integrated water resource management. Resources, Conservation and Recycling, 93: 50–58CrossRefGoogle Scholar
  3. Gilg A, Barr S (2006). Behavioural attitudes towards water saving? Evidence from a study of environmental actions. Ecological Economics, 57(3): 400–414CrossRefGoogle Scholar
  4. Hu Y, Moiwo J P, Yang Y, Han S, Yang Y (2010). Agricultural watersaving and sustainable groundwater management in Shijiazhuang Irrigation District, North China Plain. Journal of Hydrology (Amsterdam), 393(3–4): 219–232CrossRefGoogle Scholar
  5. Ji J, Zhang Z, Yang L (2017). Comparisons of initial carbon allowance allocation rules in an O2O retail supply chain with the cap-and-trade regulation. International Journal of Production Economics, 187: 68–84CrossRefGoogle Scholar
  6. Khatib J M (2015). Energy, Environmental & Sustainable Ecosystem Development: International Conference on Energy, Environmental & Sustainable Ecosystem Development (EESED 2015). Singapore: World ScientificCrossRefGoogle Scholar
  7. Liu H, Guo J, He W (2014). The research on subject behavioral risk of whole life-cycle water conservation projects. Frontiers of Engineering Management, 1(4): 348–352CrossRefGoogle Scholar
  8. Lu Y, Shang C (2014). The environmental impact of the three gorges project and the countermeasures. Frontiers of Engineering Management, 1(2): 120–128CrossRefGoogle Scholar
  9. Luckmann J, Grethe H, McDonald S (2016). When water saving limits recycling: Modelling economy-wide linkages of wastewater use. Water Research, 88: 972–980CrossRefGoogle Scholar
  10. Monaco F, Sali G, Hassen M B, Facchi A, Romani M, Valè G (2016). Water management options for rice cultivation in a temperate area: A multi-objective model to explore economic and water saving results. Water (Basel), 8(8): 1–21Google Scholar
  11. Nikouei A, Zibaei M, Ward F A (2012). Incentives to adopt irrigation water saving measures for wetlands preservation: An integrated basin scale analysis. Journal of Hydrology (Amsterdam), 464–465: 216–232CrossRefGoogle Scholar
  12. Novak J, Melenhorst M, Micheel I, Pasini C, Fraternali P, Rizzoli A E (2018). Integrating behavioural change and gamified incentive modelling for stimulating water saving. Environmental Modelling & Software, 102: 120–137CrossRefGoogle Scholar
  13. Ørum J E, Boesen M V, Jovanovic Z, Pedersen S M (2010). Farmers’ incentives to save water with new irrigation systems and water taxation–A case study of Serbian potato production. Agricultural Water Management, 98(3): 465–471CrossRefGoogle Scholar
  14. Peterson J M, Ding Y (2005). Economic adjustments to groundwater depletion in the high plains: Do water-saving irrigation systems save water? American Journal of Agricultural Economics, 87(1): 147–159CrossRefGoogle Scholar
  15. Shang H, Zhou S, Zhang L (2008). Circular Economy Development Evaluation and Policy Design. Beijing: China Financial & Economic Publishing HouseGoogle Scholar
  16. Varouchakis E A, Apostolakis A, Siaka M, Vasilopoulos K, Tasiopoulos A (2018). Alternatives for domestic water tariff policy in the municipality of Chania, Greece, toward water saving using game theory. Water Policy, 20(1): 175–188CrossRefGoogle Scholar
  17. WWAP (United Nations World Water Assessment Programme) (2015). The United Nations World Water Development Report 2015: Water for a Sustainable World. Paris: UNESCO (United Nations Educational, Scientific and Cultural Organization)Google Scholar
  18. Xie G (2015). Modelling decision processes of a green supply chain with regulation on energy saving level. Computers & Operations Research, 54: 266–273MathSciNetCrossRefzbMATHGoogle Scholar
  19. Xin B, Sun M (2018). A differential oligopoly game for optimal production planning and water savings. European Journal of Operational Research, 269(1): 206–217MathSciNetCrossRefzbMATHGoogle Scholar
  20. Xu X, He P, Hao X, Zhang Q (2017). Supply chain coordination with green technology under cap-and-trade regulation. International Journal of Production Economics, 183: 433–442CrossRefGoogle Scholar
  21. Xu X, Zhang W, He P, Xu X (2017). Production and pricing problems in make-to-order supply chain with cap-and-trade regulation. Omega, 66: 248–257CrossRefGoogle Scholar
  22. Yi Y, Li J (2018). Cost-Sharing contracts for energy saving and emissions reduction of a supply chain under the conditions of government subsidies and a carbon tax. Sustainability, 10(3): 895CrossRefGoogle Scholar
  23. Zhang D, Guo P (2016). Integrated agriculture water management optimization model for water saving potential analysis. Agricultural Water Management, 170: 5–19CrossRefGoogle Scholar
  24. Zhou L, Xu K, Cheng X, Xu Y, Jia Q (2017). Study on optimizing production scheduling for water-saving in textile dyeing industry. Journal of Cleaner Production, 141: 721–727CrossRefGoogle Scholar

Copyright information

© Higher Education Press 2019

Authors and Affiliations

  1. 1.Business SchoolNanjing Normal UniversityNanjingChina
  2. 2.Stern School of BusinessNew York UniversityNew YorkUSA
  3. 3.State Key Laboratory of Hydrology-Water Resources and Hydraulic EngineeringHohai UniversityNanjingChina
  4. 4.Business SchoolHohai UniversityNanjingChina
  5. 5.College of Management and EconomicsTianjin UniversityTianjinChina

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