Investigation of potential in-situ polymerization reactions for use in lithium-ion batteries

Dube, Tafara

Title: Investigation of potential in-situ polymerization reactions for use in lithium-ion batteries
Creator: Dube, Tafara
Subject: Lithium ion batteries
Subject: Lithium cells
Subject: Electrochemistry
Date Issued: 2024-12
Date: 2024-12
Type: Master's theses
Type: text
Identifier: http://hdl.handle.net/10948/68851
Identifier: vital:77127
Description: With the rise in popularity of electric vehicles and portable electronic devices, having a reliable, lightweight, and long-lasting battery is crucial. This has led to the mass commercialisation of lithium-ion batteries (LIB’s) because they offer several advantages over other battery technologies. Over the years, one of the concerns was with the ease with which the batteries can burn or explode when subjected to certain extreme conditions. In order to build trust in these products and to expand the technology into more diverse applications, safety aspects of the batteries has become of widespread concern resulting in a key area of research. One aspect of improving the safety is by reducing the flammability of the battery by the addition of certain chemicals that stop or suppress the thermal runaway effect. However, this in-turn reduces the battery’s capacity and life-cycle performance. Researchers have used the idea of encapsulating these chemicals thereby physically separating them within the lithium-ion battery (LIB) electrolyte system with a minimum effect on performance. This research aims to explore use of R-diols and R-amines as additives that upon a thermal trigger would react with the lithium-ion battery electrolyte to stop the effect of the thermal runaway by forming carbamate derivatives which are gel-like or form solid aggregates. The R-diols or R-amines can react with electrolyte at higher temperatures with the lithium-hexafluorophosphate acting as a catalyst. This change in the physical state of the electrolyte increases the resistance inside the battery which then hinders ion movement and forms a physical barrier to reduce the effect of short circuiting when the separator or other components are damaged due to higher temperatures.
Description: Thesis (MSc) -- Faculty of Science, School of Biomolecular & Chemical Sciences, 2024
Format: computer
Format: online resource
Format: application/pdf
Format: 1 online resource (122 pages)
Format: pdf
Publisher: Nelson Mandela University
Publisher: Faculty of Science
Language: English
Rights: Nelson Mandela University
Rights: All Rights Reserved
Rights: Open Access

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