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Understanding Magnesium Ion Electrochemistry

Understanding Magnesium Ion Electrochemistry

Understanding Magnesium Ion Electrochemistry

This thesis examines the electrochemistry of magnesiumion systems by modifying the Lewis acidbase pair to improve the stability and performance of magnesium electrolytes. It specifically focuses on two novel approaches aimed at improving non-Grignard magnesium electrolytes oxidative stability and reducing corrosion in stainless steel systems. The work discusses the surface modification of carbon electrodes and the use of molybdenum-oxo complexes for proton reduction. It concludes in discussions toward future prospects in magnesium-ion electrochemistry, especially for high-performance energy storage systems.

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s115 Pages
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Understanding Magnesium Ion Electrochemistry

Understanding Magnesium Ion Electrochemistry

This thesis examines the electrochemistry of magnesiumion systems by modifying the Lewis acidbase pair to improve the stability and performance of magnesium electrolytes. It specifically focuses on two novel approaches aimed at improving non-Grignard magnesium electrolytes oxidative stability and reducing corrosion in stainless steel systems. The work discusses the surface modification of carbon electrodes and the use of molybdenum-oxo complexes for proton reduction. It concludes in discussions toward future prospects in magnesium-ion electrochemistry, especially for high-performance energy storage systems.

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