基本信息
姓名:赖念筑
系所:热科学与能源工程系
职称:副教授
办公地点:机电楼914
邮箱:nclai@ustb.edu.cn
教育及工作经历
教育经历:
2005.09-2009.06 清华大学(台湾),化学专业,学士
2009.09-2014.12 清华大学(台湾),化学专业,博士
科研工作经历:
2015.02-2015.12 清华大学(台湾),博士后研究员
2016.01-2019.03 香港中文大学,Department of Mechanical and Automation Engineering, Research Associate
2019.05-2021.06 北京科技大学,特聘副教授
2021.07---至今 北京科技大学,副教授
2005.09-2009.06 清华大学(台湾),化学专业,学士
2009.09-2014.12 清华大学(台湾),化学专业,博士
科研工作经历:
2015.02-2015.12 清华大学(台湾),博士后研究员
2016.01-2019.03 香港中文大学,Department of Mechanical and Automation Engineering, Research Associate
2019.05-2021.06 北京科技大学,特聘副教授
2021.07---至今 北京科技大学,副教授
研究领域
1、电化学储能与能量转换技术(水系锌空电池,燃料电池,全固态锂电池,水电解);
2、光热相变储热技术(光热转化,光热电转化,防/除冰,海水淡化,电池热管理等);
3、制氢技术(变压吸附,工业副产氢CO深度去除,有机物重整制氢)
2、光热相变储热技术(光热转化,光热电转化,防/除冰,海水淡化,电池热管理等);
3、制氢技术(变压吸附,工业副产氢CO深度去除,有机物重整制氢)
研究生培养
学生培养:每年招收硕士研究生1-2人.
基本要求:愿意协同合作、互帮互助,具有耐心细心、正直善良的人格特质;愿意勇闯新领域,具有敢于接受挑战、坚持到底的精神;对科研充满热情,有志于研发新材料,突破领域关键性能.
欢迎有志于从事新型高比能、低成本、长寿命光热电储能关键材料开发与机理探索等相关研究的同学申报。在这里,只有你不想学,没有导师不教的知识;跨领域没有阻碍,得过且过才是最大的障碍.
基本要求:愿意协同合作、互帮互助,具有耐心细心、正直善良的人格特质;愿意勇闯新领域,具有敢于接受挑战、坚持到底的精神;对科研充满热情,有志于研发新材料,突破领域关键性能.
欢迎有志于从事新型高比能、低成本、长寿命光热电储能关键材料开发与机理探索等相关研究的同学申报。在这里,只有你不想学,没有导师不教的知识;跨领域没有阻碍,得过且过才是最大的障碍.
开设课程
本科生课程:
1.电化学原理与应用(专业素质拓展课,32学时)
研究生课程:
1.纳米能源材料分析技术(学科专业课,48学时)
1.电化学原理与应用(专业素质拓展课,32学时)
研究生课程:
1.纳米能源材料分析技术(学科专业课,48学时)
代表性论文及著作
代表性论文:
[1]HOU M, JIANG Z, SUN W, CHEN Z, CHU F*, LAI N C*. Efficient Photothermal Anti‐/Deicing Enabled by 3D Cu2‐xS Encapsulated Phase Change Materials Mixed Superhydrophobic Coatings [J]. Advanced Materials, 2024, 36(3): 2310312. (IF: 29.4)
[2]CHEN Z, ZHENG H, ZHANG J, JIANG Z, BAO C*, YEH C-H*, LAI N-C*. Covalent organic frameworks derived Single-Atom cobalt catalysts for boosting oxygen reduction reaction in rechargeable Zn-Air batteries [J]. Journal of Colloid and Interface Science, 2024, 670: 103-13. (IF: 9.9)
[3]ZHENG H, CHEN Z, ZHANG J, DENG S, SHAHBAZI S, ZHANG J, JIANG Z, LIU L*, YANG C-M*, LAI N-C*. One-step synthesis of thin-carbon-shell-encapsulated binary cobalt chromium nitrides for oxygen reduction reaction [J]. Applied Surface Science, 2024, 644: 158722. (IF: 6.7)
[4]ZHANG J, CHEN Z, YANG T-C, ZHANG J, ZHENG H, YEH C-H, JIANG Z, YANG C-M*, LIU L*, LAI N-C*. Interfacial engineering of high-performance Fe2P2O7-based electrocatalysts for alkaline exchange membrane fuel cells [J]. Electrochimica Acta, 2024, 485: 144098. (IF: 6.6)
[5]REN Y, HOU M, JIANG Z, SUN W, CHU F*, LAI N-C*. Photothermal superhydrophobic composite coatings based on n-tetradecane@ CaCO3/TiN microcapsules for anti-/deicing [J]. Surface and Coatings Technology, 2024, 485: 130888. (IF: 5.4)
[6]CHEN Z, ZHANG J, DENG S, HOU M, ZHANG X, JIANG Z*, LAI N-C*. Morphology-controlled synthesis of Cu2O encapsulated phase change materials: Photothermal conversion and storage performance in visible light regime [J]. Chemical Engineering Journal, 2023, 454, 140089. (IF: 15.1)
[7]ZHOU G, HOU M, REN Y, JIANG Z, LAI N-C*. Full-spectrum photo-thermal conversion enabled by plasmonic titanium carbide modified phase change microcapsules [J]. Journal of Energy Storage, 2023, 72: 108458. (IF: 9.4)
[8]HOU M, JIANG Z*, CHU F, ZHANG X, LAI N-C*. N-eicosane@ TiO2/TiN composite phase change microcapsules: Efficient visible light-driven reversible solid-liquid phase transition [J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2022, 651: 129674. (IF: 5.2)
[9]AI F, WANG Z, LAI N-C, ZOU Q, LIANG Z, LU Y-C*. Heteropoly acid negolytes for high-power-density aqueous redox flow batteries at low temperatures [J]. Nature Energy, 2022, 7(5): 417-26. (IF: 56.7)
[10]ZHOU Y, CONG G, CHEN H, LAI N-C, LU Y-C*. A self-mediating redox flow battery: high-capacity polychalcogenide-based redox flow battery mediated by inherently present redox shuttles [J]. ACS Energy Letters, 2020, 5(6): 1732-40. (IF: 22)
[11]LAI N-C, CONG G, LU Y-C*. A high-energy potassium–sulfur battery enabled by facile and effective imidazole-solvated copper catalysts [J]. Journal of Materials Chemistry A, 2019, (7): 20584-20589 (IF: 11.9)
[12]CONG G, WANG W, LAI N-C, LIANG Z, LU Y-C*. A high-rate and long-life organic–oxygen battery [J]. Nature Materials, 2019, 18(4): 390-6. (IF: 41.2)
[13]LAI N-C, CONG G, LIANG Z, LU Y-C*. A highly active oxygen evolution catalyst for lithium-oxygen batteries enabled by high-surface-energy facets [J]. Joule, 2018, 2(8): 1511-21. (IF: 39.8)
[14]LAI N-C, TSAI M-C, LIU C-H, CHEN C-S, YANG C-M*. Efficient selective oxidation of propylene by dioxygen on mesoporous-silica-nanoparticle-supported nanosized copper [J]. Journal of Catalysis, 2018, 365: 411-9. (IF: 7.3)
[15]WANG Y, LAI N-C, LU Y-R, ZHOU Y, DONG C-L, LU Y-C*. A solvent-controlled oxidation mechanism of Li2O2 in lithium-oxygen batteries [J]. Joule, 2018, 2(11): 2364-80. (IF: 39.8)
[16]WANG W, LAI N-C, LIANG Z, WANG Y, LU Y C*. Superoxide stabilization and a universal KO2 growth mechanism in potassium–oxygen batteries [J]. Angewandte Chemie-International Edition, 2018, 130(18): 5136-40. (IF: 16.6)
[17]CHEN H, LAI N-C, LU Y-C*. Silicon–carbon nanocomposite semi-solid negolyte and its application in redox flow batteries [J]. Chemistry of Materials, 2017, 29(17): 7533-42. (IF: 8.6)
更多内容详见个人学术主页:https://www.scopus.com/authid/detail.uri?authorId=54788984200
教材著作:
1.纳米材料化学基础,普通高等教育“十四五”规划教材,2024.
[1]HOU M, JIANG Z, SUN W, CHEN Z, CHU F*, LAI N C*. Efficient Photothermal Anti‐/Deicing Enabled by 3D Cu2‐xS Encapsulated Phase Change Materials Mixed Superhydrophobic Coatings [J]. Advanced Materials, 2024, 36(3): 2310312. (IF: 29.4)
[2]CHEN Z, ZHENG H, ZHANG J, JIANG Z, BAO C*, YEH C-H*, LAI N-C*. Covalent organic frameworks derived Single-Atom cobalt catalysts for boosting oxygen reduction reaction in rechargeable Zn-Air batteries [J]. Journal of Colloid and Interface Science, 2024, 670: 103-13. (IF: 9.9)
[3]ZHENG H, CHEN Z, ZHANG J, DENG S, SHAHBAZI S, ZHANG J, JIANG Z, LIU L*, YANG C-M*, LAI N-C*. One-step synthesis of thin-carbon-shell-encapsulated binary cobalt chromium nitrides for oxygen reduction reaction [J]. Applied Surface Science, 2024, 644: 158722. (IF: 6.7)
[4]ZHANG J, CHEN Z, YANG T-C, ZHANG J, ZHENG H, YEH C-H, JIANG Z, YANG C-M*, LIU L*, LAI N-C*. Interfacial engineering of high-performance Fe2P2O7-based electrocatalysts for alkaline exchange membrane fuel cells [J]. Electrochimica Acta, 2024, 485: 144098. (IF: 6.6)
[5]REN Y, HOU M, JIANG Z, SUN W, CHU F*, LAI N-C*. Photothermal superhydrophobic composite coatings based on n-tetradecane@ CaCO3/TiN microcapsules for anti-/deicing [J]. Surface and Coatings Technology, 2024, 485: 130888. (IF: 5.4)
[6]CHEN Z, ZHANG J, DENG S, HOU M, ZHANG X, JIANG Z*, LAI N-C*. Morphology-controlled synthesis of Cu2O encapsulated phase change materials: Photothermal conversion and storage performance in visible light regime [J]. Chemical Engineering Journal, 2023, 454, 140089. (IF: 15.1)
[7]ZHOU G, HOU M, REN Y, JIANG Z, LAI N-C*. Full-spectrum photo-thermal conversion enabled by plasmonic titanium carbide modified phase change microcapsules [J]. Journal of Energy Storage, 2023, 72: 108458. (IF: 9.4)
[8]HOU M, JIANG Z*, CHU F, ZHANG X, LAI N-C*. N-eicosane@ TiO2/TiN composite phase change microcapsules: Efficient visible light-driven reversible solid-liquid phase transition [J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2022, 651: 129674. (IF: 5.2)
[9]AI F, WANG Z, LAI N-C, ZOU Q, LIANG Z, LU Y-C*. Heteropoly acid negolytes for high-power-density aqueous redox flow batteries at low temperatures [J]. Nature Energy, 2022, 7(5): 417-26. (IF: 56.7)
[10]ZHOU Y, CONG G, CHEN H, LAI N-C, LU Y-C*. A self-mediating redox flow battery: high-capacity polychalcogenide-based redox flow battery mediated by inherently present redox shuttles [J]. ACS Energy Letters, 2020, 5(6): 1732-40. (IF: 22)
[11]LAI N-C, CONG G, LU Y-C*. A high-energy potassium–sulfur battery enabled by facile and effective imidazole-solvated copper catalysts [J]. Journal of Materials Chemistry A, 2019, (7): 20584-20589 (IF: 11.9)
[12]CONG G, WANG W, LAI N-C, LIANG Z, LU Y-C*. A high-rate and long-life organic–oxygen battery [J]. Nature Materials, 2019, 18(4): 390-6. (IF: 41.2)
[13]LAI N-C, CONG G, LIANG Z, LU Y-C*. A highly active oxygen evolution catalyst for lithium-oxygen batteries enabled by high-surface-energy facets [J]. Joule, 2018, 2(8): 1511-21. (IF: 39.8)
[14]LAI N-C, TSAI M-C, LIU C-H, CHEN C-S, YANG C-M*. Efficient selective oxidation of propylene by dioxygen on mesoporous-silica-nanoparticle-supported nanosized copper [J]. Journal of Catalysis, 2018, 365: 411-9. (IF: 7.3)
[15]WANG Y, LAI N-C, LU Y-R, ZHOU Y, DONG C-L, LU Y-C*. A solvent-controlled oxidation mechanism of Li2O2 in lithium-oxygen batteries [J]. Joule, 2018, 2(11): 2364-80. (IF: 39.8)
[16]WANG W, LAI N-C, LIANG Z, WANG Y, LU Y C*. Superoxide stabilization and a universal KO2 growth mechanism in potassium–oxygen batteries [J]. Angewandte Chemie-International Edition, 2018, 130(18): 5136-40. (IF: 16.6)
[17]CHEN H, LAI N-C, LU Y-C*. Silicon–carbon nanocomposite semi-solid negolyte and its application in redox flow batteries [J]. Chemistry of Materials, 2017, 29(17): 7533-42. (IF: 8.6)
更多内容详见个人学术主页:https://www.scopus.com/authid/detail.uri?authorId=54788984200
教材著作:
1.纳米材料化学基础,普通高等教育“十四五”规划教材,2024.
专利
发明专利:
1.赖念筑,陈正浩,张锦辉,郑昊,包成.一种锚定在MOFs衍生碳骨架上的过渡金属焦磷酸盐ORR催化剂及其制备方法和应用,发明专利.
1.赖念筑,陈正浩,张锦辉,郑昊,包成.一种锚定在MOFs衍生碳骨架上的过渡金属焦磷酸盐ORR催化剂及其制备方法和应用,发明专利.
获奖
1. 斐陶斐荣誉学会会员 ,2015.
代表性科研项目
主持:
1. 国家自然科学基金青年项目,介孔金属氮化物固溶体的可控合成及其电催化氧气还原机理研究,2022.01-2024.12.
2. 北京科技大学青年教师学科交叉项目,质子交换膜燃料电池高效能阴极催化剂的可控合成及其氧还原机理研究,2020.01-2021.12.
3. 中央高校基本科研业务费,基于过渡金属电催化剂的缺陷化学在氧气还原反应 (ORR) 的应用,2019.06-2021.05.
参与:
1. 国家重点研发计划重点专项,高性能、高可靠电池结构设计及可控制备技术研究,2021.12-2025.12.
2. 国家自然科学基金面上项目,全固态锂空气电池一体化正极界面输运及反应机制研究,2021.01-2024.12.
3. 北京市自然科学基金面上项目,基于两段式CO深度去除的燃料电池用氢气纯化研究,2022.01-2023.12.
教学项目:
1. 北京科技大学精品在线开放课程建设项目,《热工学》,2020.6-2021.6.
在线视频网址:https://www.icourse163.org/course/USTB-1461799172
1. 国家自然科学基金青年项目,介孔金属氮化物固溶体的可控合成及其电催化氧气还原机理研究,2022.01-2024.12.
2. 北京科技大学青年教师学科交叉项目,质子交换膜燃料电池高效能阴极催化剂的可控合成及其氧还原机理研究,2020.01-2021.12.
3. 中央高校基本科研业务费,基于过渡金属电催化剂的缺陷化学在氧气还原反应 (ORR) 的应用,2019.06-2021.05.
参与:
1. 国家重点研发计划重点专项,高性能、高可靠电池结构设计及可控制备技术研究,2021.12-2025.12.
2. 国家自然科学基金面上项目,全固态锂空气电池一体化正极界面输运及反应机制研究,2021.01-2024.12.
3. 北京市自然科学基金面上项目,基于两段式CO深度去除的燃料电池用氢气纯化研究,2022.01-2023.12.
教学项目:
1. 北京科技大学精品在线开放课程建设项目,《热工学》,2020.6-2021.6.
在线视频网址:https://www.icourse163.org/course/USTB-1461799172