教育经历: 2018~2021 香港科技大学,工学院,博士(全额奖学金) 2016~2018 香港科技大学,工学院,硕士(全额奖学金) 工作经历: 2023~至今 仲恺农业工程学院,化工与材料学院,仲恺青年学者/特聘副教授 2021~2022 香港科技大学,工学院,博士后 科研项目: [1] 广东省自然科学基金面上项目(2024A1515010292),15万,2024.1-2026.12,主持 [2] 仲恺农业工程学院仲恺青年学者人才引进科研启动项目(KA23YY31821),15万,2023.01-2026.12,主持 [3] 揭阳市引进创新创业团队项目(JBGS005),200万,2024.9-2027.9,参与 近五年代表性论文: [1] A coordination-reinforced and encapsulated polymer electrolyte for durable and safe Na-metal batteries. Energy Storage Materials, 2026, 84: 104834. (通讯作者,IF: 20.2) [2] Solvation-regulated flame-retardant hybrid solid-like electrolytes enabling high-rate and wide-temperature sodium batteries. Composites Part B: Engineering, 2026, 311: 113215. (通讯作者,IF: 14.2) [3] Fast-charging solid-state Li batteries: materials, strategies, and prospects. Advanced Materials, 2025, 37(23): 2417796. (第一作者,IF: 26.8) [4] Manipulating the ionic conductivity and interfacial compatibility of polymer-in-dual-salt electrolytes enables extended-temperature quasi-solid metal batteries. Journal of Colloid and Interface Science, 2024, 666: 189-200. (通讯作者,IF: 9.7) [5] A wrapped and infiltrated ∼20-μm-thick 3D ceramic framework composite enables fast Li+ diffusion and interfacial compatibility for lithium-metal batteries. Composites Part B: Engineering, 2024, 272: 111192. (通讯作者,IF: 14.2) [6] Multiple Na+ transport pathways and interfacial compatibility enable high-capacity, room-temperature quasi-solid sodium batteries. Journal of Colloid and Interface Science, 2024, 666: 447-456. (通讯作者,IF: 9.7) [7] Improving room‐temperature Li‐metal battery performance by in situ creation of fast Li+ transport pathways in a polymer‐ceramic electrolyte. Small, 2023, 19(39): 2302691. (第一作者,IF: 12.1) [8] Strain engineering of antiperovskite materials for solid-state Li batteries: a computation-guided substitution approach. Journal of Materials Chemistry A, 2023, 11(35): 18984-18995. (共同一作,IF: 9.5) [9] In situ fabricated quasi-solid polymer electrolyte for high-energy-density lithium metal battery capable of subzero operation. Advanced Energy Materials, 2022, 12(2): 2102932. (第一作者,IF: 26) [10] Simultaneously improved surface and bulk participation of evolved perovskite oxide for boosting oxygen evolution reaction activity using a dynamic cation exchange strategy. Small, 2022, 18(47): 2204109. (通讯作者,IF: 12.1) [11] A hybrid dual-salt polymer electrolyte for sodium metal batteries with stable room temperature cycling performance. Energy Storage Materials, 2022, 46: 182-191. (共同一作,IF: 20.2) [12] Nonflammable, robust and flexible electrolytes enabled by phosphate coupled polymer–polymer for Li-metal batteries. Journal of Colloid and Interface Science, 2022, 621: 222-231. (通讯作者,IF: 9.7) [13]A solid-like dual-salt polymer electrolyte for Li-metal batteries capable of stable operation over an extended temperature range. Energy Storage Materials, 2021, 37: 609-618. (第一作者,IF: 20.2) [14] Ultrathin and nonflammable dual-salt polymer electrolyte for high-energy-density lithium-metal battery. Advanced Functional Materials, 2021, 31(17): 2010261. (共同一作,IF: 19) 专利: [1]一种基于氧空位氧化铈纳米填料的无定型聚醚复合电解质及其制备方法,2026-01-30, 中国, CN202511233214.8 (授权专利) [2] Synchronous process for producing non-flammable quasi-solid-state electrolyte and solid-state batteries using the electrolyte,2022.11,美国, 17/721,378 (授权专利) 教学相关: 2024年第十四届“挑战杯”广东大学生创业计划竞赛(省级银奖),第一指导老师 中国国际大学生创新大赛(2024)(省级铜奖),第一指导老师 2022年港澳台创新创业大赛优胜奖(广州市科技局) 2022年“京津冀-粤港澳”青年创新创业大赛总决赛金奖 2021年度香港科技大学-信和百万创业大賽广发创新奖
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