The research aimed to analyse the impact of blockchain technology on international trade and find out how blockchain technology can improve the various fields of international trade.
When talking about blockchain technology in academia, business, and society, frequently generalizations are still heared about its – supposedly inherent – enormous energy consumption. This perception inevitably raises concerns about the further adoption of blockchain technology, a fact that inhibits rapid uptake of what is widely considered to be a
Battery technology could enable the transport and power sectors to reduce emissions by 30% by 2030, on track to meet the 2°C goal of the Paris Agreement. According to the World Economic Forum, this battery revolution could also create 10 million jobs, add $150 billion to the global economy and provide electricity to 600 million
Many potential applications exist for blockchain technology, demonstrating how lucrative the blockchain industry is for innovative new companies that tap into it and utilize it. How much does it cost to develop a blockchain? Estimating cost is crucial in any project, especially when taking investors into consideration. In the context of blockchain technology, however,
Blockchain technology can trace the complete life cycle of lithium-ion batteries in the whole supply chain [5, 6, 7]. If properly used, it can support the responsible and efficient recycling and reuse of batteries for
The results show the ability of blockchain technology to track batteries and resolve issues of liability assignment in accidents and conflicts of interest that exist in the battery supply chain. The works in the literature that were evaluated point to cobalt as the main raw material to be screened due to legal, ethical, social
They found that under a carbon tax regime, carbon emission reduction encourages battery suppliers to adopt blockchain technology, while under carbon emission
Battery technology could enable the transport and power sectors to reduce emissions by 30% by 2030, on track to meet the 2°C goal of the Paris Agreement. According to the World Economic Forum, this battery
EU battery regulation requirements. 2023. The Regulation enters in Force (August 2023) 2024. Up-to date parameters for SoH and expected lifetime data for LMT, EV and stationary battery energy storage systems will be required as
Blockchain technology can trace the complete life cycle of lithium-ion batteries in the whole supply chain [5, 6, 7]. If properly used, it can support the responsible and efficient recycling and reuse of batteries for electric vehicles and portable electronic devices. The world has realized the necessity of a circular economy.
The results of this systematic review show that the development of a blockchain-based platform for battery tracking will allow for greater transparency across the entire supply chain:...
The results of this systematic review show that the development of a blockchain-based platform for battery tracking will allow for greater transparency across the entire supply
This paper examines the use of blockchain technology in power battery echelon recycling. The technology helps to improve battery capacity identification and market transaction trust. The...
This paper examines the use of blockchain technology in power battery echelon recycling. The technology helps to improve battery capacity identification and market transaction trust. The...
Blockchain-based battery tracking offers solutions to issues like information asymmetry, counterfeit battery risk, and technical barriers in assessing battery condition. This paper aims to identify the drivers behind
Considering the adoption of blockchain technology to enhance information traceability for retired power batteries, we construct three closed-loop supply chain decision-making models: a supply chain that does not adopt blockchain technology, a manufacturing enterprise that independently bears the input cost of blockchain technology
The results show the ability of blockchain technology to track batteries and resolve issues of liability assignment in accidents and conflicts of interest that exist in the
This paper presents a blockchain application for electric vehicles'' (EVs) battery charge and swap, considering two approaches: custom Ethereum blockchain and the IOTA public tangle. For both scenarios, the performance of the system is analyzed, highlighting the advantages and disadvantages of each method. The application is tested
After the emergence of the Internet of Things (IoT), the way devices interact with each other changed, as it allowed automation and seamless communication in various fields. However, various challenges related to security and trust have emerged, hindering the widespread adoption of the IoT. Blockchain technology is considered the ideal solution to face
The real-world use cases of blockchain technology, such as faster cross-border payments, identity management, smart contracts, cryptocurrencies, and supply chain–blockchain technology are here
Meanwhile, when the recycling cost is large, both manufacturers and retailers should adopt blockchain technology to obtain greater profits. Furthermore, with the improvement of traceability...
Blockchain-based battery tracking offers solutions to issues like information asymmetry, counterfeit battery risk, and technical barriers in assessing battery condition. This paper aims to identify the drivers behind manufacturers adopting blockchain for battery tracking and assess whether a mutually beneficial outcome exists.
This paper presents a blockchain application for electric vehicles'' (EVs) battery charge and swap, considering two approaches: custom Ethereum blockchain and the IOTA public tangle. For both scenarios, the performance of
You might already know about blockchain technology, and maybe even how your favorite cryptocurrency works, but do you know what a blockchain transaction is and how it works under the hood? Well on a base level, blockchain is just a massive distributed ledger or database, with its data stored on every computer in the system rather than a server
They found that under a carbon tax regime, carbon emission reduction encourages battery suppliers to adopt blockchain technology, while under carbon emission quota trading regulations, manufacturers'' investment decisions are influenced by unit outsourcing costs and the performance of blockchain technology.
Problem description. After power battery manufacturers embed blockchain technology, it has two main benefits. Firstly, it makes it possible to clearly identify the remaining capacity of SPBs and
Considering the adoption of blockchain technology to enhance information traceability for retired power batteries, we construct three closed-loop supply chain decision-making models: a supply chain that does not adopt blockchain technology, a manufacturing enterprise that independently bears the input cost of blockchain technology, and a scenario
At the same time, in a globalized supply chain, traceability and transparency have become crucial requirements. Blockchain technology can support to build supply chains with strong traceability and transparency characteristics (e.g. through the use of advanced RFID and GPS technologies) and deal with environmental, financial, and social
Meanwhile, when the recycling cost is large, both manufacturers and retailers should adopt blockchain technology to obtain greater profits. Furthermore, with the improvement of traceability...
This may be attributed to the embedding of blockchain technology in the process of echelon recycling and utilization of power batteries in the standardization of the spent battery market. The information on remaining capacity is now more transparent, which has led to increased transaction activity among market participants.
NEV retailers, battery manufacturers, and the government are facing a multitude of challenges. Blockchain technology can trace the complete life cycle of lithium-ion batteries in the whole supply chain [5, 6, 7].
Firstly, the adoption of blockchain consistently results in an increased profit for the manufacturer. Blockchain enhances the carbon emission reduction level, stimulates market demand, and increases recycling quantity. Therefore, the power battery manufacturer involved in recycling should actively participate in blockchain development.
Introducing blockchain technology by a manufacturer enables the tracing of the entire lifecycle of power batteries, standardizes consumer recycling behavior, and reduces the cost of retesting and evaluating batteries during the echelon utilization phase.
Embed blockchain technology in the supply chain of secondary recycling and utilization of power batteries under the traceability mechanism. Echelon utilizers should base their recycling mode decisions on the intensity of recycling competition, sensitivity to recycling prices, and the level of cost optimization coefficient.
The input cost of blockchain technology embedded in power battery is fully borne by the manufacturer and is a quadratic function of the level of blockchain technology embedded, i.e., 17, denotes the investment cost coefficient of blockchain technology embedded, and denotes the level of blockchain technology embedded.
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