Retraction

This article was originally submitted to Trends in Renewable Energy on 8/1/2024. Following peer review and author revision, the article was accepted for publication on 9/2/2024. After professional English editing and layout editing, the proof was sent to the author on 9/15/2024 and the proof was published online as the paper in press.

On 9/18/2024, the editorial office was noticed that due to the conflict of interest, the author would like to withdraw this article from the production process. The editorial office followed up on the author's request and conducted an investigation. It’s concluded that this article is not a simultaneous submission. Although Turnitin Similarity Report (http://www.futureenergysp.com/index.php/tre/article/downloadSuppFile/183/43) showed a 48% similarity index, the highest similarity from a single publication is less 4%. As a review article, it indicated that some paragraphs need further revisions, but overall the article is of good quality.  

Now this paper has been officially withdrawn. However, the abstract and the proof are still kept on the journal website as a record.

Editors of Trends in Renewable Energy

September 27, 2024

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Abstract

Lithium-ion batteries have significant advantages such as high energy density, long cycle life and low self-discharge rate. Therefore, they are ideal for energy storage in electric vehicles. However, lithium-ion batteries are very sensitive to temperature, which affects the battery's cycle life, efficiency, reliability and safety. During the charging and discharging process, a large amount of heat is generated inside the battery due to the electrochemical reaction and resistance, causing the battery temperature to rise. When the temperature gets too high, thermal runaway, electrolyte fire and explosions may occur. As battery energy density increases, the demand for efficient thermal management continues to increase, and a compact and efficient battery thermal management system is essential. This paper introduces the development status of different thermal management technologies, reviews the application of microchannel liquid-cooling technology in the thermal management of prismatic lithium batteries, discusses the current research direction and status of microchannel technology, and finally looks forward to the future research and development direction of microchannel technology.

Citation: Zeng, Q. (2024). Research progress of microchannel liquid cooling technology in the application of thermal management of prismatic lithium batteries (Withdrawn). Trends in Renewable Energy, 10(3), 335-355. doi:http://dx.doi.org/10.17737/tre.2024.10.3.00183

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