Abstract i List of Contents iii List of Tables v List of Figures vii I. Introduction 1 1.1. Rechargeable multivalent-ion batteries 1 1.2. Rechargeable magnesium batteries 3 1.3. Development of electrolytes 5 1.4. Discovery of high-voltage cathode materials 8 1.5. Objectives of the study 10 1.6. References 11 II. Evaluation of Sn-based Protective Layer for Magnesium Metal Anode in Strongly Solvating Chloride-Free Electrolyte 17 2.1. Introduction 17 2.2. Experimental Methods 18 2.3. Results and Discussion 20 2.4. Conclusion 29 2.5. References 30 III. Enhancing H2V3O8 Capacity as Magnesium-ion Battery Cathode via Understanding Mg2+ Diffusion Behavior 34 3.1. Introduction 34 3.2. Experimental Methods 36 3.3. Results and Discussion 38 3.4. Conclusion 44 3.5. References 45 IV. Iron Hexacyanoferrate as Cathode Material for Magnesium Batteries with Enhanced Capacity 48 4.1. Introduction 48 4.2. Experimental Methods 49 4.3. Results and Discussion 53 4.4. Conclusion 62 4.5. Supporting Tables 63 4.6. References 67 V. Demonstration of Rechargeable Magnesium Batteries comprising Vanadium Oxide and Prussian-Blue Analogue 72 5.1. Introduction 72 5.2. Experimental Methods 72 5.3. Results and Discussion 73 5.4. Conclusion 74 요 약 문 76
Research Interests
Magnesium; calcium; and zinc ion batteries; lithium all-solid-state batteries; Inorganic materials discovery; Solid state chemistry; Crystallography; Mg; Ca; Zn 이온 이차전지; 리튬 전고체전지; 신 무기재료 합성; 고체화학; 결정화학