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Technology uptake in supply chains frequently encounters challenges when immediate, tangible benefits are not evident. Therefore, this article's central objective is to pinpoint the risks affecting the integration of supply chain technologies for enduring outcomes. Subsequently, these risks will be organized into a hierarchical structure, facilitating a clearer comprehension of their direct and indirect interconnections.

A combined TISM and quantitative approach has been used to build the hierarchal structure and to validate the direct, and indirect relationship among risks adopting supply chain technologies. A total of 41 respondents participated in the TISM survey, which resulted in creating a level hierarchical structure. Further, 233 responses are used for the quantitative study using SEM to validate the model obtained from TISM.

The study's findings indicated the social risks come out with the highest driving power. This includes the fear of job displacement, community disparity and change in the work culture of an organization. At the same time, technological risks can cause system integration, scalability issues, obsolesce compatibility issues, system failures and supply chain sustainability issues.

The novelty of the study can be found in the developed framework and its subsequent confirmation via quantitative evaluation. TISM provides the theoretical foundation, while a quantitative investigation is carried out to verify this theory.

The purpose of this paper that will address in this paper are: how to implement and test a reliable Block-chain-based energy system for the EU energy payments and logistic? What are the main results, impacts and implications of a Block-chain-based energy system for the EU energy payments and logistic?

The main aim of this study is to propose a Block-chain-based method to offer a secure, reliable and transparent method for energy logistic and payments for European Energy Transactions. To accomplish that aim, the research method of the study follows the design science research approach of smart contracts in the EU Energy logistic and payments. This research approach mainly consists of five sequential steps which are (1) problem and motivation identification, (2) solution objectives definition, (3) design and development and (4) demonstration and evaluation.

Results of data model demonstrate that the Block-chain-based energy system here can be used for any EU energy payments and logistics. Based on the data results of the model that mentioned above enhance the security and the integrity of the energy payments and logistic by using cryptographic techniques and consensus mechanisms to prevent and detect any tampering or falsification of the data on the Block-chain.

This paper represents a genuine piece of research that contributes to the field by providing new insights and understanding. The findings presented are the result of rigorous analysis and have not been previously published or submitted elsewhere for consideration.