Hybrid Materials Research Center 1
1. From food waste to high-capacity hard carbon for rechargeable sodium-ion batteries
2. Optimizing nitrogen doping strategies in hard carbon for enhanced performance in sodium-ion batteries
3. Effect of pre-treatment conditions on the electrochemical performance of hard carbon derived from bio-waste
4. Towards high-performance sodium-ion batteries: A comprehensive review on NaxNiyFezMn1−(y+z)O2 cathode materials
5. Durable Cu-doped P3-type Na0.62Mn0.75Cu0.19O2 cathodes for high-capacity sodium-ion batteries
6. Present development and future perspectives on biowaste-derived hard carbon anodes for room temperature sodium-ion batteries
7. Enhanced electrochemical performance of sodium cathode materials with partial substitution of Zr
8. Emerging strategies on structural and constitutional modifications of zinc anode for enhanced performance in aqueous zinc-ion batteries
9. Electronic Structure Engineering of Honeycomb Layered Cathode Material for Sodium-Ion Batteries
10. Synergetic Lattice and Surface Engineering: Stable High-Voltage Cycle Performance in P3-Type Layered Manganese Oxide
11. Exploiting High-Voltage Stability of Dual-Ion Aqueous Electrolyte Reinforced by Incorporation of Fiberglass into Zwitterionic Hydrogel Electrolyte
12. Layered manganese oxide cathode boosting high-capacity and long-term cyclability in aqueous Zinc-Ion batteries
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