Light & Engineering 32 (5) 2024

Volume 32
Date of publication 10/11/2024
Pages 90–105

Exploring the Influencing Factors of Closed-Loop Supply Chain Low-Carbon Transformation for LED Lighting Enterprises Using Fuzzy AHP-DEMATEL–VIKOR Methodology L&E, Vol.32, No.5, 2024

Articles authors:

Jienalin Zhang, Haofang Chen, Wei Lu, Kaixiang Feng

Jienalin Zhang, graduate student from the School of Masters of Applied Leadership and Management, Arizona State University. Her research areas are industrial finance, investment theory and practice

Haofang Chen, graduate student from the School of Economic, Social and Political Sciences, University of Southampton. His research area is Green economics

Wei Lu, graduate student from the School of Masters of Finance and Management, University of Exeter. Her research areas are finance, internal organizational management, as well as international business and marketing

Kaixiang Feng, graduate student from Henan University of Economics and Law. His research areas are industrial finance, investment theory and practice

Abstract:

A low-carbon lifestyle is an important approach to coordinating economic and social development with environmental protection. To explore the mechanism of low-carbon transformation of closed-loop supply chains for LED lighting enterprises under the dual-carbon strategy, this study employs a Fuzzy AHP (Analytic Hierarchy Process)-DEMATEL (Decision-making Trial and Evaluation Laboratory)-VIKOR (VIse Kriterijumska Optimizacija I Kompromisno Resenje, that means: Multi-criteria Optimization and Compromise Solution, with pronunciation: VIKOR) model to extract 18 influencing factors, clarify the relationships among them, and reveal the mechanism for the low-carbon transformation of closedloop supply chains in LED lighting enterprises. Results indicate that: (1) From the comprehensive weight data, the weight values of carbon reduction technology, low-carbon product sales price, carbon emission constraints, waste recycling rate, and consumer low-carbon preferences account for a larger proportion; (2) The centrality of the low-carbon product sales price factor is the highest, placing it at the core of the system; the reason degree of carbon reduction technology ranks first in this indicator system, with carbon reduction technology as the centre to deploy the low-carbon transformation actions of manufacturing enterprises under the carbon neutrality goal in the closed-loop supply chain; (3) The government, LED lighting enterprises, retailers, consumers, and recyclers work together to ensure the low-carbon transformation of the closed-loop supply chain for LED lighting enterprises.

References:

1. He, X.G., Meng, Z.Q., Zhou, H.A. A city road lighting power consumption and electricity theft monitoring system based on LoRa IoT // Journal of Hunan University (Natural Science Edition), 2023, Vol. 50, # 10, pp. 11–19.
2. Liang, J., Ning, S. Y., Lian, Y. S.et al. Research on chromatic difference evaluation based on LED lighting // Spectroscopy and Spectral Analysis, 2018, Vol. 38, # 10, pp. 3199–3204.
3. Zhao, Z.R., Ji, L.Y., Shen, Y.X., et al. Research on the uniformity of LED lighting system based on PSO particle swarm algorithm # Journal of Luminescence, 2013, Vol. 34, # 12, pp. 1677–1682.
4. Shi, L. N., Pan, Y. G., Dong, G.X. Optimization design and implementation of LED grating light modulator lighting system // Opto-Electronics & Laser, 2010, Vol. 21, # 8, pp. 1133–1137.
5. Zhu, R.B. Discussion on the application of solarLED systems in indoor environmental art design // Acta Energiae Solaris Sinica, 2022, Vol. 43, # 2, pp. 504–505.
6. Jaraite, J., Maria, C. Di. Did the EU ETS make a difference? An empirical assessment using Lithuanian firm-level data // Energy Journal, 2016, Vol. 37, # 1, pp. 1–23.
7. Gupta, S., Palsule-Desai, O.D. Sustainable supply chain management: review and research opportunities // IIMB Management Review, 2011, Vol. 23, # 4, pp. 234–245.
8. Zhao, J.H., Lin, J. Closed-loop supply chain pricing model under different subsidy objects // Journal of Management Engineering, 2017, Vol. 31, # 1, pp. 85–92.
9. Ferrer, G., Swaminathan, J.M. Managing new and remanufactured products // Management Science, 2006, Vol. 52, # 1, pp. 15–26.
10. Savaskan, R.C., Van Wassenhove, L.N. Reverse channel design: the case of competing retailers // Management Science, 2006, Vol. 52, # 1, pp. 1–14.
11. Atasu, A., Sarvary, M., Van Wassenhove L.N. Remanufacturing as a marketing strategy // Management Science, 2008, Vol. 54, # 10, pp. 1731–1746.
12. Benjaafar, S., Li, Y., Daskin, M. Carbon footprint and the management of supply chains: insights from simple models // IEEE Transactions on Automation Science and Engineering, 2013, Vol. 10, # 1, pp. 99–116.
13. Bonney, M., Jaber, M.Y. Environmentally responsible inventory models: non-classical models for a nonclassical era // International Journal of Production Economics, 2011, Vol. 133, # 1, pp. 43–53.
14. Springer, C., Evans, S., Lin, J., Roland-Holst, D.. Low carbon growth in China: the role of emissions trading in a transitioning economy // Applied Energy, 2019, Vol. 235, pp. 1118–1125.
15. Avci, B., Girotra, K., Netessine, S. Electric vehicles with a battery switching station: adoption and environmental impact // Management Science, 2014, Vol. 61, # 4, pp. 772–794.
16. A. Dumrongsiri, M. Fan, A. Jain, K. Moinzadeh. A supply chain model with direct and retail channels // European Journal of Operational Research, 2008, Vol. 187, # 3, pp. 691–718.
17. Chao, F., Wang, M. The heterogeneity of China’s pathways to economic growth, energy conservation and climate mitigation // Journal of Cleaner Production, 2019, Vol. 228, pp. 594–605.
18. He, P., He, Y., Xu, H. Channel structure and pricing in a dual-channel closed-loop supply chain with government subsidy // International Journal of Production Economics, 2019, Vol. 213, pp. 108–123.
19. Chen, H., Kang, J.N., Liao, H., Tang, B. J., Wei, Y.M. Costs and potentials of energy conservation in China’s coal-fired power industry: a bottom-up approach considering price uncertainties // Energy Policy, 2017, Vol. 104, pp. 23–32.
20. He, Y., Huang, H., Li, D. Inventory and pricing decisions for a dual-channel supply chain with deteriorating products // Operational Research, 2020, Vol. 20, # 3, pp. 1461–1503.
21. Boyabatlı, O., Nasiry, J., Zhou, Y. Crop planning in sustainable agriculture: dynamic farmland allocation in the presence of crop rotation benefits // Management Science, 2019, Vol. 65, # 5, pp. 1–17.
22. Batarfi, R., Jaber, M. Y., Zanoni, S. Dual-channel supply chain: a strategy to maximize profit // Applied Mathematical Modelling, 2016, Vol. 40, # 21–22, pp. 9454–9473.
23. Huo, T., Ren, H., Zhang X. et al. China’s energy consumption in the building sector: a Statistical Year book-Energy Balance Sheet based splitting method // Journal of Cleaner Production, 2018, Vol. 185, pp. 665–679.
24. Savaskan, R. C., Bhattacharya, S., Van Wassenhove, L.N. Closed-loop supply chain models with product remanufacturing // Management Science, 2004, Vol. 50, # 2, pp. 239–252.
25. Giri, B. C., Chakraborty, A., Maiti, T. Pricing and return product collection decisions in a closed-loop supply chain with dual-channel in both forward and reverse logistics // Journal of Manufacturing Systems, 2017, Vol. 42, pp. 104–123.
26. Schenkel, M., Caniëls, M. C. J., van der Laan, E. Understanding value creation in closed loop supply chains: Past findings and future directions // Journal of Manufacturing Systems, 2015, Vol. 37, # 3, pp. 729–745.

Keywords

DOI: https://doi.org/1033383/2024-034

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