{"title":"采用 TOE-DCV 方法打造绿色供应链,促进半导体行业的可持续运营","authors":"Ranjan Chaudhuri , Bindu Singh , Amit Kumar Agrawal , Sheshadri Chatterjee , Shivam Gupta , Sachin Kumar Mangla","doi":"10.1016/j.ijpe.2024.109327","DOIUrl":null,"url":null,"abstract":"<div><p>Semiconductor industry plays a critical role for the global economy. Semiconductor industry provides various necessary technologies such as IoT, AI, modern fabrication technologies and so on to various industries including automotive industry, electronic and communication industry, healthcare industry, construction and building industry, space industry, and so on. However, semiconductor supply chain experiences various supply chain related risks and challenges because of its procedural complexities, global supply chain integrations, government policy and regulations, competitiveness, technological complexities, and so on. Not many studies available which investigated the risk, resilience, and complexities regarding green supply chain adoption by semiconductor industry. In this context, the objective of this study is to examine the risks, resilience, and complexities for managing the green supply chain adoption for higher sustainability in the semiconductor industry. Utilizing the TOE framework (Technology-Organization-Environment) and DCV (Dynamic Capability View), we developed a research model to achieve this purpose. Subsequently, this model was validated through structural equation modelling, involving 356 respondents affiliated with the semiconductor industry. This study highlights that technological risk aspects comprising of technological turbulence and risk, compatibility and complexity, organizational dynamic capabilities, and resilience along with appropriate policy and regulations could help successful adoption of green supply chain management in the semiconductor industry.</p></div>","PeriodicalId":14287,"journal":{"name":"International Journal of Production Economics","volume":"275 ","pages":"Article 109327"},"PeriodicalIF":9.8000,"publicationDate":"2024-07-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S0925527324001841/pdfft?md5=372f0ed6aee465c80396e979e107b8d4&pid=1-s2.0-S0925527324001841-main.pdf","citationCount":"0","resultStr":"{\"title\":\"A TOE-DCV approach to green supply chain adoption for sustainable operations in the semiconductor industry\",\"authors\":\"Ranjan Chaudhuri , Bindu Singh , Amit Kumar Agrawal , Sheshadri Chatterjee , Shivam Gupta , Sachin Kumar Mangla\",\"doi\":\"10.1016/j.ijpe.2024.109327\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>Semiconductor industry plays a critical role for the global economy. Semiconductor industry provides various necessary technologies such as IoT, AI, modern fabrication technologies and so on to various industries including automotive industry, electronic and communication industry, healthcare industry, construction and building industry, space industry, and so on. However, semiconductor supply chain experiences various supply chain related risks and challenges because of its procedural complexities, global supply chain integrations, government policy and regulations, competitiveness, technological complexities, and so on. Not many studies available which investigated the risk, resilience, and complexities regarding green supply chain adoption by semiconductor industry. In this context, the objective of this study is to examine the risks, resilience, and complexities for managing the green supply chain adoption for higher sustainability in the semiconductor industry. Utilizing the TOE framework (Technology-Organization-Environment) and DCV (Dynamic Capability View), we developed a research model to achieve this purpose. Subsequently, this model was validated through structural equation modelling, involving 356 respondents affiliated with the semiconductor industry. 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引用次数: 0
摘要
半导体产业对全球经济起着至关重要的作用。半导体行业为汽车行业、电子通信行业、医疗行业、建筑行业、航天行业等各行各业提供物联网、人工智能、现代制造技术等各种必要技术。然而,由于程序复杂、全球供应链整合、政府政策法规、竞争力、技术复杂性等原因,半导体供应链面临着各种与供应链相关的风险和挑战。有关半导体行业采用绿色供应链的风险、适应性和复杂性的研究并不多。在这种情况下,本研究的目的是探讨管理绿色供应链以提高半导体行业可持续发展的风险、复原力和复杂性。利用 TOE 框架(技术-组织-环境)和 DCV(动态能力视图),我们开发了一个研究模型来实现这一目的。随后,我们通过结构方程模型对这一模型进行了验证,共有 356 名半导体行业的受访者参与其中。本研究强调,由技术动荡和风险、兼容性和复杂性、组织动态能力和复原力组成的技术风险方面,以及适当的政策和法规,有助于在半导体行业成功采用绿色供应链管理。
A TOE-DCV approach to green supply chain adoption for sustainable operations in the semiconductor industry
Semiconductor industry plays a critical role for the global economy. Semiconductor industry provides various necessary technologies such as IoT, AI, modern fabrication technologies and so on to various industries including automotive industry, electronic and communication industry, healthcare industry, construction and building industry, space industry, and so on. However, semiconductor supply chain experiences various supply chain related risks and challenges because of its procedural complexities, global supply chain integrations, government policy and regulations, competitiveness, technological complexities, and so on. Not many studies available which investigated the risk, resilience, and complexities regarding green supply chain adoption by semiconductor industry. In this context, the objective of this study is to examine the risks, resilience, and complexities for managing the green supply chain adoption for higher sustainability in the semiconductor industry. Utilizing the TOE framework (Technology-Organization-Environment) and DCV (Dynamic Capability View), we developed a research model to achieve this purpose. Subsequently, this model was validated through structural equation modelling, involving 356 respondents affiliated with the semiconductor industry. This study highlights that technological risk aspects comprising of technological turbulence and risk, compatibility and complexity, organizational dynamic capabilities, and resilience along with appropriate policy and regulations could help successful adoption of green supply chain management in the semiconductor industry.
期刊介绍:
The International Journal of Production Economics focuses on the interface between engineering and management. It covers all aspects of manufacturing and process industries, as well as production in general. The journal is interdisciplinary, considering activities throughout the product life cycle and material flow cycle. It aims to disseminate knowledge for improving industrial practice and strengthening the theoretical base for decision making. The journal serves as a forum for exchanging ideas and presenting new developments in theory and application, combining academic standards with practical value for industrial applications.