2014.08-2019.07 清华大学 能源与动力工程系 工学博士
2011.08-2014.07 清华大学 经济管理学院 经济学学士（双学位）
2010.08-2014.07 清华大学 能源与动力工程系 工学学士

2023.01-至今 365速发国际最新平台 365速发国际官网 副教授（博导）
2021.06-2022.12 365速发国际最新平台 365速发国际官网 助理教授（博导）
2019.06-2021.05 365速发国际最新平台 365速发国际官网 博士后

朱炫灿团队致力于解决能源环境领域中气体吸附分离效率和能耗问题，基于对吸附/衰减机理的基础研究，合成高性能物理化学吸附材料，发展低压降结构性吸附器和高效吸附分离过程，在温和条件下实现CO、CO2、H2等气体分子的选择性捕集/纯化，建立吸附分离单元的技术经济性评价体系，对碳捕集与转化、高纯氢制取、空气分离等应用领域具有重要意义。

1. 新型固体吸附剂合成和原位表征
2. 吸附增强反应过程
3. 先进吸附分离系统的热质转递
4. 碳捕集/制氢技术系统集成和技术经济性分析
5. 负排放技术和有限空间气体净化

欢迎感兴趣的本科生、研究生、博士后联系！

已毕业学生情况：
2024 葛冰瑶 硕士 毕业去向：清华大学 攻读博士学位
研究生国家奖学金、上海市优秀毕业生、优秀硕士学位论文、清华大学未来学者奖学金
学位论文：基于胺嫁接纳米水滑石的余热驱动直接空气捕集技术研究

2023 苗诒贺（参与培养） 博士 毕业去向：365速发国际最新平台 博士后研究员
学位论文：基于空气碳捕集的固态胺吸脱附特性与稳定性研究

2023 王耀祖（参与培养） 硕士 毕业去向：清华大学 攻读博士学位
学位论文：添加剂改性固态胺吸附剂制备及直接空气碳捕集性能研究

《Clean Energy》青年编委
《Carbon Capture Science & Technology》青年编委
2024年第三届亚洲热科学大会（ACTS 2024）分会主席
2023年热功转换循环会议（HPC2023）分会主席
2023年碳捕集科学与技术国际会议（CCST2023）组委会成员和分会主席
全国节能减排大赛评审专家
国际吸附协会（IAS）会员
《洁净煤技术》青年编委
国际碳捕集协会（IACC）高级会员

项目负责人：
2023.07 上海交大-爱丁堡大学种子基金项目：“Materials, Structures and Instruments for Direct Air Capture”
2023.03 黑鲸能源横向项目：“直接空气捕集（DAC）技术”
2022.12 国家重点研发项目子课题：“新型快稳吸附剂定向设计与烟气CO2捕集性能研究”
2022.04 上海市科技兴农重点攻关项目（技术培育）：“低能耗转轮式空气源二氧化碳气肥系统研发”
2021.01 国家自然科学基金青年项目: “纳米水滑石复合材料捕集微量二氧化碳的吸附机理和循环特性”
2019.06 中国博士后科学基金第66批面上资助: “基于壳核复合材料的直接空气二氧化碳捕集机理研究”
2019.06 中国博士后创新人才支持计划项目: “空分纯化系统分子筛吸附强化与能量回收”

参与研究：
2023.01 国家自然科学基金重大项目课题：“热能高效存储转换及能质调控原理”
2022.09 上海市科技创新行动计划国际科技合作项目：“用于未来城市的工业热泵驱动DAC技术分析研究”
2022.07 国电投合作项目：“面向二氧化碳永久封存及燃料化的吸附式捕集技术”
2020.06 SJTU-NUS合作研究项目: “基于碳循环链的太阳能辅助生物质气化发电研究”
2019.06 国家重点研发项目: “分子筛吸附强化与能量回收技术”
2019.01 国家自然科学基金青年项目: “类水滑石中温变压吸附CO2吸附机理及传热传质特性研究”
2018.07 阿尔伯塔合作专项：“钾修饰水滑石CO2吸附机理及其在高纯氢制取中的应用”
2016.01 山西重大专项：“低能耗中温变压吸附H2/CO2分离与净化关键技术与装备开发”
2015.06 东芝国际合作项目：“High Purity Hydrogen Production by Novel Pressure Swing Adsorption Technology”
2014.12 广东电网横向项目：“IGCC系统中吸收增强制氢及燃烧前脱碳技术研究”
2013.08 国家863纵向项目：“基于中温干法硫碳共脱的低能耗CO2/H2分离技术”

专著：
[62] 朱炫灿, 钾修饰镁铝水滑石富氢气体中温CO/CO2净化研究, 北京: 清华大学出版社, 2021.4.
[61] Zhu, X.; Shi, Y.; Li, S.; Cai, N.; Anthony, Edward J., System and processes of pre-combustion carbon dioxide capture and separation. In pre-combustion carbon dioxide capture materials, The Royal Society of Chemistry: 2018; pp 281-334.

综述：
[60] 苗诒贺; 王耀祖; 刘雨杭; 朱炫灿; 李佳; 于立军, 添加剂改性固态胺吸附剂用于碳捕集的研究进展. 化工进展 2024, 43 (05), 2739-2759.
[59] Kou, X.; Wang, R.; Du, S.; Xu, Z.; Zhu, X., Heat pump assists in energy transition: Challenges and approaches. DeCarbon 2024, 3, 100033.
[58] Li, S.; Zhu, X.; Wang, D.; Hao, P.; Zhou, F.; Shi, Y.; Wang, R.; Cai, N., Elevated temperature adsorbents for separation applications. EnergyChem 2023, 5 (6), 100113.
[57] Zhang, C.; Zhang, X; Su, T.; Zhang, Y.; Wang, L.; Zhu, X., Modification schemes of efficient sorbents for trace CO2 capture. Renew. Sust. Energ. Rev. 2023, 184, 113473.
[56] Ku, H.; Miao, Y.; Wang, Y.; Chen, X.; Zhu, X.; Lu, H.; Li, J.; Yu, L., Frontier science and challenges on offshore carbon storage. Front. Env. Sci. Eng. 2023, 17 (7), 80.
[55] Wu, J.; Zhu, X.; Yang, F.; Wang, R.; Ge, T., Shaping techniques of adsorbents and their applications in gas separation: a review. J. Mater. Chem. A 2022, 10 (43), 22853-22895.
[54] Zhu, X.; Xie, W.; Wu, J.; Miao, Y.; Xiang, C.; Chen, C.; Ge, B.; Gan, Z.; Yang, F.; Zhang, M.; O'Hare, D.; Li, J.; Ge, T.; Wang, R., Recent advances in direct air capture by adsorption. Chem. Soc. Rev. 2022, 51 (15), 6574-6651.
[53] 朱炫灿; 葛天舒; 吴俊晔; 杨凡; 王如竹, 吸附法碳捕集技术的规模化应用和挑战. 科学通报 2021, 66 (22), 2861-2877.
[52] Gao, W.; Liang, S.; Wang, R.; Jiang, Q.; Zhang, Y.; Zheng, Q.; Xie, B.; Toe, C. Y.; Zhu, X.; Wang, J.; Huang, L.; Gao, Y.; Wang, Z.; Jo, C.; Wang, Q.; Wang, L.; Liu, Y.; Louis, B.; Scott, J.; Roger, A.; Amal, R.; He, H.; Park, S., Industrial carbon dioxide capture and utilization: state of the art and future challenges. Chem. Soc. Rev. 2020, 49 (23), 8584-8686.
[51] Zhu, X.; Li, S.; Shi, Y.; Cai, N., Recent advances in elevated-temperature pressure swing adsorption for carbon capture and hydrogen production. Prog. Energ. Combust. 2019, 75, 100784.

研究论文：
2025:
[50] Gan, Z.; Shao, Q.; Ge, B.; Wang, Q.; Zhu, X., Single-component and binary H2O and CO2 co-adsorption isotherm model on amine-functionalised Mg-Al mixed metal oxides. Carbon Capture Science & Technology 2025, 14, 100328.
[49] Zhang, X.; Zhang, D.; Zhang, C.; Ma, R.; Zhu, X.; Wang, L., Enhancing CO2 solubility for efficient carbon capture via self-assembly deep eutectic solvents on MOF-808. Sep. Purif. Technol. 2025, 358, 130331.
[48] Zhang, D.; Zhang, C.; Zhang, X.; Tian, Y.; Cheng, X.; Zhu, X.; Wang, L., Efficient low-pressure CO2 capture via ZIF-8 modified by deep eutectic solvents. Sep. Purif. Technol. 2025, 353, 128359.

2024:
[47] Ge, B.; Chen, C.; Xu, Y.; Roberts, S.; Zhang, M.; Shao, Q.; O'Hare, D.; Zhu, X., Enhancing adsorbent performance for direct air capture of CO2 by in-situ amine-grafting of layered double hydroxides. Chem. Eng. J. 2024, 500, 156782.
[46] Shao, Q.; Gan, Z.; Ge, B.; Liu, X.; Chen, C.; O'Hare, D.; Zhu, X., 3D printing of poly(ethyleneimine)-functionalized Mg-Al mixed metal oxide monoliths for direct air capture of CO2. J. Energy. Chem. 2024, 96, 491-500.
[45] Ge, B.; Zhang, M.; Hu, B.; Wu, D.; Zhu, X.; Eicker, U.; Wang, R., Innovative process integrating high temperature heat pump and direct air capture. Appl. Energ. 2024, 355, 122229.
[44] Wu, J.; Wang, K.; Zhao, J.; Chen, Y.; Gan, Z.; Zhu, X.; Wang, R.; Wang, C.; Tong, Y.; Ge, T., A direct air capture rotary adsorber for CO2 enrichment in greenhouses. Device 2024, 2 (11), 100510.
[43] Wu, J.; Chen, Y.; Xu, Y.; Chen, S.; Lv, H.; Gan, Z.; Zhu, X.; Wang, R.; Wang, C.; Ge, T., Facile synthesis of structured adsorbent with enhanced hydrophobicity and low energy consumption for CO2 capture from the air. Matter 2024, 7 (1), 123-139.

2023:
[42] Wang, Y.; Miao, Y.; Ge, B.; He, Z.; Zhu, X.; Liu, S.; Li, J.; Yu, L., Additives enhancing supported amines performance in CO2 capture from air. SusMat 2023, 3 (3), 416-430.
[41] Ge, B.; Chen, C.; Gan, Z.; Zhu, X.; Miao, Y.; Wang, Y.; Ge, T.; O'Hare, D.; Wang, R., Scalable synthesis of amine-grafted ultrafine layered double hydroxide nanosheets with improved carbon dioxide capture capacity from air. ACS Sustainable Chem. Eng. 2023, 11 (25), 9282-9287.
[40] Miao, Y.; Wang, Y.; He, Z.; Ge, B.; Zhu, X.; Li, J.; Yu, L., Mixed diethanolamine and polyethyleneimine with enhanced CO2 capture capacity from air. Adv. Sci. 2023, 10 (16), 2207253.
[39] 张鑫琦; 张宸; 张舵咏; 宣涛; 干卓臻; 朱炫灿; 王丽伟, 高选择性PEI@MOF-808吸附剂在潮湿烟气中的碳捕集性能研究. 化工学报 2023, 74 (10), 4330-4342.
[38] Wang, B.; Li, X.; Zhu, X.; Wang, Y.; Tian, T.; Dai, Y.; Wang, C., An epitrochoidal rotary reactor for solar-driven hydrogen production based on the redox cycling of ceria: Thermodynamic analysis and geometry optimization. Energy 2023, 270, 126833.

2022:
[37] Miao, Y.; Wang, Y.; Zhu, X.; Chen, W.; He, Z.; Yu, L.; Li. J., Minimizing the effect of oxygen on supported polyamine for direct air capture. Sep. Purif. Technol. 2022, 298, 121583.
[36] Wu, J.; Zhu, X.; Chen, Y.; Wang, R.; Ge, T., The analysis and evaluation of direct air capture adsorbents on the material characterization level. Chem. Eng. J. 2022, 450, 137958.
[35] Ling, Y.; Wang, H.; Liu, M.; Wang, B.; Li, S.; Zhu, X.; Shi, Y.; Xia, H.; Guo, K.; Hao, Y.; Jin, H., Sequential separation-driven solar methane reforming for H2 derivation under mild conditions. Energ. Environ. Sci. 2022, 15, 1861-1871.
[34] He, Z.; Wang, Y.; Miao, Y.; Wang, H.; Zhu, X.; Li, J., Mixed polyamines promotes CO2 adsorption from air. J. Environ. Chem. Eng. 2022, 10 (2), 107239.
[33] Yang, F.; Ge, T.; Zhu, X.; Wu, J.; Wang, R., Study on CO2 capture in humid flue gas using amine-modified ZIF-8. Sep. Purif. Technol. 2022, 287, 120535.
[32] Yang, F.; Zhu, X.; Wu, J.; Wang, R.; Ge, T., Kinetics and mechanism analysis of CO2 adsorption on LiX@ZIF-8 with core shell structure. Powder Technol. 2022, 399, 117090.

2021:
[31] Zhu, X.; Lyu, M.; Ge, T.; Wu, J.; Chen, C.; Yang, F.; O'Hare, D.; Wang, R., Modified layered double hydroxides for efficient and reversible carbon dioxide capture from air. Cell Reports Physical Science 2021, 2 (7), 100484.
[30] Zhu, X.; Ge, T; Yang, F.; Wang, R., Design of steam-assisted temperature vacuum-swing adsorption processes for efficient CO2 capture from ambient air. Renew. Sust. Energ. Rev. 2021, 137, 110651.
[29] Zhu, X.; Ge, T.; Yang, F.; Lyu, M.; Chen, C.; O'Hare, D.; Wang, R., Design of amine-functionalized layered double oxide nanosheets with efficient CO2 capture capacities from ambient air, ultrafast kinetics, and promising stability. Available at SSRN: https://ssrn.com/abstract=3811992.
[28] Miao, Y.; He, Z.; Zhu, X.; Izikowitz, D.; Li, J., Operating temperatures affect direct air capture of CO2 in polyamine-loaded mesoporous silica. Chem. Eng. J. 2021, 426, 131875.
[27] Wu, J.; Zhu, X.; Yang, F.; Ge, T.; Wang, R., Easily-synthesized and low-cost amine-functionalized silica sol-coated structured adsorbents for CO2 capture. Chem. Eng. J. 2021, 425, 131409.
[26] Yang, F.; Wu, J.; Zhu, X.; Ge, T.; Wang, R., Enhanced stability and hydrophobicity of LiX@ZIF-8 composite synthesized environmental friendly for CO2 capture in highly humid flue gas. Chem. Eng. J. 2021, 410, 128322.

2020:
[25] Zhu, X.; Ge, T.; Yang, F.; Lyu, M.; Chen, C.; O'Hare, D.; Wang, R., Efficient CO2 capture from ambient air with amine-functionalized Mg–Al mixed metal oxides. J. Mater. Chem. A 2020, 8 (32), 16421-16428.
[24] Zhu, X.; Chen, C.; Shi, Y.; O'Hare, D.; Cai, N., Aqueous miscible organic-layered double hydroxides with improved CO2 adsorption capacity. Adsorption 2020, 26 (7), 1127-1135.
[23] Zhu, X.; Hao, P.; Shi, Y.; Li, S.; Cai, N., Application of elevated temperature pressure swing adsorption in hydrogen production from syngas. Adsorption 2020, 26 (7): 1227-1237.
[22] Khalkhali, M.; Zhu, X.; Shi, Y.; Liu, Q.; Choi, P.; Zhang, H., Structure and CO2 physisorption capacity of hydrotalcite-derived oxide. J. CO2 Util. 2020, 36, 64-75.
[21] Liu, Z.; Hao, P.; Li, S.; Zhu, X.; Shi, Y.; Cai, N., Simulation and energy consumption comparison of gas purification system based on elevated temperature pressure swing adsorption in ammonia synthetic system. Adsorption 2020, 26 (7), 1239-1252.
[20] Hao, P.; Zhu, X.; Li, S.; Shi, Y.; Cai, N., Efficiency analysis of warm gas clean up in integrated gasification fuel cell (IGFC) system. Research Square 2020, DOI: 10.21203/rs.3.rs-42837/v1.

2019:
[19] Zhu, X.; Chen, C.; Wang, Q.; Shi, Y.; O'Hare, D.; Cai, N., Roles for K2CO3 doping on elevated temperature CO2 adsorption of potassium promoted layered double oxides. Chem. Eng. J. 2019, 366, 181-191.
[18] Zhu, X.; Chen, C.; Suo, H.; Wang, Q.; Shi, Y.; O'Hare, D.; Cai, N., Synthesis of elevated temperature CO2 adsorbents from aqueous miscible organic-layered double hydroxides. Energy 2019, 167, 960-969.
[17] Chen, Y.; Shi, Y.; Zhu, X.; Cai, N., Impedance characterization of elevated temperature carbon dioxide adsorption process on potassium-modified hydrotalcite. Sep. Purif. Technol. 2019, 212, 670-675.
[16] Hao, P.; Shi, Y.; Li, S.; Zhu, X.; Cai, N., Adsorbent characteristic regulation and performance optimization for pressure swing adsorption via temperature elevation. Energ. Fuel. 2019, 33 (3), 1767-1773.
[15] Li, S.; Hao, P.; Zhu, X.; Shi, Y.; Cai, N.; Li, S.; Jiang, H., On-site demonstration of an elevated temperature hydrogen clean-up unit for fuel cell applications. Adsorption 2019, 25 (8), 1683-1693.

2018:
[14] Zhu, X.; Shi, Y.; Li, S.; Cai, N., Two-train elevated-temperature pressure swing adsorption for high-purity hydrogen production. Appl. Energ. 2018, 229, 1061-71.
[13] Zhu, X.; Shi, Y.; Li, S.; Cai, N., Elevated temperature pressure swing adsorption process for reactive separation of CO/CO2 in H2-rich gas. Int. J. Hydrogen Energ. 2018, 43 (29), 13305-17.
[12] Hao, P.; Shi, Y.; Li, S.; Zhu, X.; Cai, N., Correlations between adsorbent characteristics and the performance of pressure swing adsorption separation process. Fuel 2018, 230, 9-17.

2017:
[11] Zhu, X.; Shi, Y.; Cai, N., CO2 residual concentration of potassium-promoted hydrotalcite for deep CO/CO2 purification in H2-rich gas. J. Energy Chem. 2017, 26 (5), 956-64.
[10] Zhu, X.; Shi, Y.; Cai, N., High-pressure carbon dioxide adsorption kinetics of potassium-modified hydrotalcite at elevated temperature. Fuel 2017, 207, 579-90.
[9] 朱炫灿; 史翊翔; 蔡宁生, 合成气微量CO深度净化新方法实验研究. 工程热物理学报 2017, 38 (2), 421-427.
[8] Zhu, X.; Shi, Y.; Cai, N., Investigation on the trace amount of released CO in sorption enhanced water gas shift reaction applied in pre-combustion CO2 capture and high purity H2 production. Energy Procedia 2017, 114, 2525-2536.

2016:
[7] Zhu, X.; Shi, Y.; Cai, N., Integrated gasification combined cycle with carbon dioxide capture by elevated temperature pressure swing adsorption. Appl. Energ. 2016, 176, 196-208.
[6] Zhu, X.; Shi, Y.; Cai, N., Characterization on trace carbon monoxide leakage in high purity hydrogen in sorption enhanced water gas shifting process. Int. J. Hydrogen Energ. 2016, 41 (40), 18050-61.
[5] 许凯; 史翊翔; 湛志钢; 徐齐胜; 朱炫灿; 李爽, 钾修饰镁铝复合金属氧化物脱除二氧化碳实验研究. 中国电机工程学报 2016, 36 (23), 6454-6459.

2015:
[4] Zhu, X.; Wang, Q.; Shi, Y.; Cai, N., Layered double oxide/activated carbon-based composite adsorbent for elevated temperature H2/CO2 separation. Int. J. Hydrogen Energ. 2015, 40 (30), 9244-53.
[3] 李爽; 史翊翔; 杨懿; 朱炫灿; 蔡宁生, 钾修饰水滑石吸附剂脱碳性能及颗粒强度实验研究. 工程热物理学报 2015, 36 (7), 1606-1610.

2014:
[2] Zhu, X.; Shi, Y.; Cai, N.; Li, S.; Yang, Y., Techno-economic evaluation of an elevated temperature pressure swing adsorption process in a 540 MW IGCC power plant with CO2 capture. Energy Procedia 2014, 63, 2016-2022.
[1] 朱炫灿; 史翊翔; 蔡宁生, 改性活性炭中温CO2吸附特性的实验研究. 中国工程热物理学会2014年学术会议, 西安, 2014.

[15] 王开强; 邵庆阳; 陈波; 朱炫灿; 刘巍巍; 杨凯雄; 洪正东; 马玉奇; 刘先洲; 姜维; 张喆. 二氧化碳吸附剂及其制备方法、以及相关装置: 中国, 发明专利, CN202411173286.3.
[14] 史翊翔; 李爽; 刘帅; 朱炫灿; 张幔; 蔡宁生. 一种煤气化耦合高温电解水制备含氢产品的方法及系统: 中国, 发明专利, CN202410235121.8.
[13] 朱炫灿; 邵庆阳; 葛冰瑶; 干卓臻; 王如竹. 一种3D打印胺功能金属氧化物吸附剂及其制备方法和应用: 中国, 发明专利, CN202410291155.9.
[12] 朱炫灿; 葛冰瑶; 陈春萍; 邵庆阳; 张幔; 戴默特·奥海尔; 王如竹. 一种胺嫁接水滑石材料及其制备方法和应用: 中国, 发明专利, CN202311322206.1.
[11] 朱炫灿; 葛冰瑶; 张幔; 胡斌; 吴迪; 王如竹. 一种蒸汽热泵辅助的直接空气碳捕集系统: 中国, 发明专利, CN202311029647.2.
[10] 胡斌; 蔡宏; 朱炫灿; 葛冰瑶; 干卓臻; 王如竹. 一种工业余热驱动的近零能耗直接空气捕集系统: 中国, 发明专利, CN202211298101.2.
[9] 胡斌; 葛冰瑶; 朱炫灿; 干卓臻; 吴迪; 王如竹. 一种双热源热泵型空气碳直接捕集系统: 中国, 发明专利, ZL202210612102.3.
[8] 朱炫灿; 吴俊晔; 葛天舒; 王如竹. 一种CO2气肥系统及运行方法: 中国, 发明专利, CN202210453027.0.
[7] 葛天舒, 吴俊晔, 朱炫灿, 杨凡, 王如竹. 基于胺功能化硅溶胶的整体结构吸附剂、制备方法及应用: 中国, 发明专利, CN202110484154.2.
[6] 吴俊晔, 葛天舒, 朱炫灿, 杨凡. 一种快速变温吸附转轮式直接空气二氧化碳捕集系统及方法: 中国, 发明专利, CN202011032726.5.
[5] 吴俊晔, 葛天舒, 朱炫灿, 杨凡. 一种快速变温吸附转轮式烟气二氧化碳捕集系统及方法: 中国, 发明专利, CN202011033932.8.
[4] 史翊翔, 李爽, 蔡宁生, 郝培璇, 朱炫灿. 一种中温真空变压吸附系统及方法: 中国, 发明专利, ZL201811160591.3.
[3] 蔡宁生, 史翊翔, 朱炫灿. 一种吸附剂真实高压吸附动力学测试装置及方法: 中国, 发明专利, ZL201710095774.0.
[2] 李汶颖, 史翊翔, 蔡宁生, 朱炫灿. 一种利用可再生电力的固体氧化物电解池制天然气的方法: 中国, 发明专利, ZL201310712385.X.
[1] 朱炫灿, 史翊翔, 蔡宁生. 一种浮体电解质液态储能电池单体结构: 中国, 发明专利, ZL201310177420.2.