个人履历

2021.12 ~ 至今：厦门大学，能源学院，副教授，博士生导师

2020.11 ~ 2021.12：厦门大学，化学化工学院，博士后（导师：黄小青教授）

2017.9 ~ 2020.11：苏州大学，材料与化学化工学部，博士后（导师：黄小青教授）

2011.9 ~ 2017.6：苏州大学，材料与化学化工学部，博士（导师：姚建林教授、黄小青教授）

研究方向

多组分低维铂、钯、镍、稀土基功能纳米材料的可控合成、结构表征、催化性能、构效关系、催化机理及燃料电池与电解水器件应用

荣誉及奖励

福建省杰出青年科学基金获得者 (2024)

福建省级高层次人才 (2022)

厦门大学“南强青年拔尖人才支持计划” (2021)

江苏省科学技术一等奖 (2020)

苏州大学优秀博士后 (2020)

中国博士后科学基金第12批特别资助 (2019)

江苏省优秀博士学位论文 (2018)

苏州市自然科学优秀学术论文一等奖 (2018)

苏州市“四创”好青年 (2017)

苏州大学优秀博士学位论文 (2017)

苏州大学优秀毕业研究生 (2017)

代表性论著

迄今为止，共计发表SCI论文70篇，包括Science、Nat. Commun.、J. Am. Chem. Soc.、Angew. Chem. Int. Ed.、Adv. Mater.、Adv. Funct. Mater.、Energy Environ. Sci.、Chem、ACS Nano、ACS Catal.等，总他引6600余次；申请发明专利6项。

[1] L. Z. Bu, N. Zhang, S. J. Guo,* X. Zhang, J. Li, J. L. Yao, T. Wu, G. Lu, J. Y. Ma, D. Su,* X. Q. Huang,* Biaxially strained PtPb/Pt core/shell nanoplate boosts oxygen reduction catalysis. Science, 2016, 354 (6318), 1410−1414. (Highly Cited Paper, IF = 37.205)

[2] X. Lin, S. Z. Geng, X. L. Du, F. T. Wang, X. Zhang, F. Xiao, Z. Y. Xiao, Y. C. Wang, J. Cheng, Z. F. Zheng, X. Q. Huang, L. Z. Bu,* Efficient direct formic acid electrocatalysis enabled by rare earth-doped platinum-tellurium heterostructures. Nat. Commun., 2025, 16, 147. (Highly Cited Paper, IF = 15.7)

[3] Z. L. Huang, S. N. Hu, M. Z. Sun, Y. Xu,* S. H. Liu, R. J. Ren, L. Zhuang, T. S. Chan, Z. W. Hu, T. Y. Ding, J. Zhou, L. B. Liu, M. M. Wang, Y. C. Huang, N. Tian, L. Z. Bu,* B. L. Huang,* X. Q. Huang,* Implanting oxophilic metal in PtRu nanowires for hydrogen oxidation catalysis. Nat. Commun., 2024, 15, 1097. (Highly Cited Paper, IF = 14.7)

[4] C. H. Zhan, Y. Xu, Z. Q. Yang, L. Z. Bu,* H. Z. Zhu, Y. G. Feng, T. Yang, Y. Zhang, B. L. Huang,* Q. Shao, X. Q. Huang,* Subnanometer high-entropy alloy nanowires enable remarkable hydrogen oxidation catalysis. Nat. Commun., 2021, 12, 6261. (Highly Cited Paper, IF = 14.919)

[5] L. Z. Bu, S. J. Guo,* X. Zhang, X. Shen, D. Su, G. Lu, X. Zhu, J. L. Yao, J. Guo, X. Q. Huang,* Surface engineering of hierarchical platinum-cobalt nanowires for efficient electrocatalysis. Nat. Commun., 2016, 7, 11850. (Highly Cited Paper, IF = 12.353)

[6] X. R. Hu, Z. C. An, W. Z. Wang, X. Lin, T. S. Chan, C. H. Zhan, Z. W. Hu, Z. Q. Yang, X. Q. Huang,* L. Z. Bu,* Sub-monolayer SbOx on PtPb/Pt nanoplate boosts direct formic acid oxidation catalysis. J. Am. Chem. Soc., 2023, 145 (35), 19274−19282. (IF = 14.5)

[7] X. R. Hu, Z. Y. Xiao, W. Z. Wang, L. Z. Bu,* Z. C. An, S. H. Liu, C. W. Pao, C. H. Zhan, Z. W. Hu, Z. Q. Yang, Y. C. Wang, X. Q. Huang,* Platinum-lead-bismuth/platinum-bismuth core/shell nanoplate achieves complete dehydrogenation pathway for direct formic acid oxidation catalysis. J. Am. Chem. Soc., 2023, 145 (28), 15109−15117. (IF = 14.5)

[8] C. Y. Dong, X. Y. Wang, Z. P. Zhu, C. H. Zhan, X. Lin, L. Z. Bu,* J. Y. Ye, Y. C. Wang, W. Liu,* X. Q. Huang,* Highly selective synthesis of monoclinic-phased platinum-tellurium nanotrepang for direct formic acid oxidation catalysis. J. Am. Chem. Soc., 2023, 145 (28), 15393−15404. (IF = 14.5)

[9] L. Z. Bu, Q. Shao, B. E, J. Guo, J. L. Yao, X. Q. Huang,* PtPb/PtNi intermetallic core/atomic layer shell octahedra for efficient oxygen reduction electrocatalysis. J. Am. Chem. Soc., 2017, 139 (28), 9576−9582. (IF = 13.858)

[10] C. H. Zhan,# L. Z. Bu,# H. R. Sun, X. W. Huang, Z. P. Zhu, T. Yang, H. B. Ma, L. G. Li, Y. C. Wang,* H. B. Geng, W. Z. Wang, H. Z. Zhu, C. W. Pao, Q. Shao, Z. Q. Yang,* W. Liu,* Z. X. Xie, X. Q. Huang,* Medium/high‐entropy amalgamated core/shell nanoplate achieves efficient formic acid catalysis for direct formic acid fuel cell. Angew. Chem. Int. Ed., 2023, 62 (3), e202213783. (IF = 16.6)

[11] S. Z. Geng, R. J. Ren, R. Qin, N. J. Chen, J. Song, Z. F. Zheng, W. H. Huang, C. W. Pao, Z. W. Hu, L. Zhuang, X. Q. Huang, L. Z. Bu,* Lattice mismatched platinum-tellurium@platinum-ruthenium core@shell nanorods achieve ultrahigh alkaline hydrogen electrocatalysis for dual practical devices. Adv. Mater., 2026, 38 (10), e17683. (IF = 26.8)

[12] P. D. Fang, C. H. Zhan, Y. L. Kang, S. Z. Geng, M. Z. Sun, B. L. Huang,* J. Xia,* T. J. Mao, J. Wang, W. Z. Liao, Z. Chen,* T. S. Chan, Y. C. Huang, Z. W. Hu, X. Q. Huang,* L. Z. Bu,* Continuous surface strain regulation in trimetallic PtPbRu/Pt nanoplates for promoted formic acid oxidation catalysis. Adv. Mater., 2026, 38 (13), e22348. (IF = 26.8)

[13] L. Z. Bu,* J. S. Liang, F. D. Ning, J. Huang, B. L. Huang,* M. Z. Sun, C. H. Zhan, Y. H. Ma, X. C. Zhou, Q. Li,* X. Q. Huang,* Low‐coordination trimetallic PtFeCo nanosaws for practical fuel cells. Adv. Mater., 2023, 35 (11), 2208672. (IF = 29.4)

[14] L. Z. Bu, J. B. Ding, S. J. Guo,* X. Zhang, D. Su, X. Zhu, J. L. Yao, J. Guo, G. Lu, X. Q. Huang,* A general method for multimetallic platinum alloy nanowires as highly active and stable oxygen reduction catalysts. Adv. Mater., 2015, 27 (44), 7204−7212. (IF = 18.96)

[15] X. Lv, T. J. Mao, Y. S. Luo, Q. P. Yu, L. X. Si, Y. L. Kang, Q. P. Sun, J. Wang, W. H. Huang, C. W. Pao, S. Belin, Z. W. Hu, L. Z. Bu,* X. Q. Huang,* Unconventional platinum-antimony intermetallic nanosheets boost formic acid oxidation catalysis. Adv. Funct. Mater., 2026, 0, e75464. (IF = 19)

[16] C. H. Zhan, H. R. Sun, L. Z. Lü, L. Z. Bu,* L. G. Li, Y. H. Liu, T. Yang, W. L. Liu, X. Q. Huang,* Zinc intercalated lattice expansion of ultrafine platinum-nickel oxygen reduction catalyst for PEMFC. Adv. Funct. Mater., 2023, 33 (8), 2212442. (IF = 19)

[17] L. Z. Bu,* F. D. Ning, J. Zhou, C. H. Zhan, M. Z. Sun, L. G. Li, Y. M. Zhu, Z. W. Hu, Q. Shao, X. C. Zhou, B. L. Huang,* X. Q. Huang,* Three-dimensional porous platinum-tellurium-rhodium surface/interface achieve remarkable practical fuel cell catalysis. Energy Environ. Sci., 2022, 15 (9), 3877−3890. (IF = 39.714)

[18] L. Z. Bu, Q. Shao, Y. C. Pi, J. L. Yao, M. C. Luo, J. P. Lang, S. Hwang, H. L. Xin, B. L. Huang,* J. Guo, D. Su,* S. J. Guo,* X. Q. Huang,* Coupled s-p-d exchange in facet-controlled Pd3Pb tripods enhances oxygen reduction catalysis. Chem, 2018, 4 (2), 359−371. (IF = 18.205)

[19] X. Hu, K. Z. Jiang,* F. C. Wang, S. Z. Geng, Y. B. Liu, S. Meng, H. H. Su, S. Zhu, L. Z. Bu,* C. Chen,* S. J. Zheng,* Gas dynamically confined synthesis of platinum-based intermetallic nanowires for active and ultrastable oxygen reduction catalysis. ACS Nano, 2025, 19 (5), 31201−31212. (IF = 16.1)

[20] C. Y. Dong, B. Zhang, H. J. Song, S. Y. Zhou, J. Y. Ye, H. G. Liao, L. S. Dong, X. Q. Huang,* L. Z. Bu,* Platinum-tellurium heterojunction nanosheet assemblies for efficient direct formic acid electrooxidation catalysis. ACS Nano, 2024, 18 (14), 10008−10018. (IF = 15.8)

[21] C. S. He, L. L. Yang, X. H. Peng, S. H. Liu, J. Wang, C. Y. Dong, D. L. Du, L. G. Li,* L. Z. Bu,* X. Q. Huang,* Alkylamine-confined thickness-tunable synthesis of Co(OH)2-CoO nanosheets toward oxygen evolution catalysis. ACS Nano, 2023, 17 (6), 5861−5870. (IF = 17.1)

[22] L. Y. Wang, S. Meng, C. Y. Tang, C. H. Zhan, S. Z. Geng, K. Z. Jiang, X. Q. Huang,* L. Z. Bu,* PtNi/PtIn-skin fishbone-like nanowires boost alkaline hydrogen oxidation catalysis. ACS Nano, 2023, 17 (18), 17779−17789. (IF = 17.1)

[23] X. Zhang, X. Lin, X. Hu, S. Z. Geng, F. Xiao, K. Z. Jiang, S. R. Li, Z. F. Zheng, L. Z. Bu,* General method for trimetallic platinum-cobalt-rare earth alloys on nitrogen-doped carbon as efficient methanol electrooxidation catalysts. ACS Catal., 2024, 14 (1), 84−93. (IF = 13.1)

[24] L. Z. Bu,# C. Y. Tang,# Q. Shao, X. Zhu, X. Q. Huang,* Three-dimensional Pd3Pb nanosheet assemblies: high-performance non-Pt electrocatalysts for bifunctional fuel cell reactions. ACS Catal., 2018, 8 (5), 4569−4575. (IF = 12.221)

[25] F. Xiao, H. R. Sun, S. Z. Geng, X. Hu, K. Z. Jiang, Q. Zhang, Z. F. Zheng, W. Liu, X. Q. Huang, L. Z. Bu,* Rare earth-decorated platinum-nickel-cobalt knot-like nanowires achieve efficient bifunctional electrocatalysis for PEMFC. Nano Energy, 2025, 144, 111379. (IF = 17.1)

[26] C. Y. Dong, H. J. Song, L. Z. Bu,* Q. Z. Zheng, J. Y. Ye, Y. Ding, H. G. Liao, J. W. Yan, L. S. Dong, X. Q. Huang,* Controlling the distribution of metal elements in core@shell nanosheets for highly efficient direct formic acid electrooxidation. Nano Lett., 2025, 25 (23), 12285−12293. (IF = 9.1)

[27] S. Z. Geng, L. Y. Wang, W. Yan, C. H. Zhan, Y. H. Li, X. Q. Huang, L. Z. Bu,* Platinum-nickel@high-entropy alloy core@satellite nanowires as efficient bifunctional electrocatalysts for PEMFC. Nano Lett., 2025, 25 (3), 1010−1018. (IF = 9.1)

[28] L. B. Liu, L. J. Jin, Z. Y. Xiao, N. Fang, X. Lin, Y. J. Ji, Y. C. Wang, Y. Y. Li, X. Q. Huang,* L. Z. Bu,* Heterostructured Pt-PbS nanobelt achieves remarkable direct formic acid oxidation catalysis. Nano Lett., 2024, 24 (26), 8162−8170. (IF = 9.6)

[29] Y. M. Zhu,# J. H. Peng,# X. R. Zhu,# L. Z. Bu,* Q. Shao, C. W. Pao, Z. W. Hu, Y. F. Li, J. B. Wu,* X. Q. Huang,* A large-scalable, surfactant-free, and ultrastable Ru-doped Pt3Co oxygen reduction catalyst. Nano Lett., 2021, 21 (15), 6625−6632. (IF = 12.262)

[30] Y. G. Feng,# Z. L. Zhao,# F. Li,# L. Z. Bu,* Q. Shao, L. G. Li, J. B. Wu,* X. Zhu, G. Lu, X. Q. Huang,* Highly surface-distorted Pt superstructures for multifunctional electrocatalysis. Nano Lett., 2021, 21 (12), 5075−5082. (IF = 12.262)

[31] L. Z. Bu,# X. R. Zhu,# Y. M. Zhu,# C. Cheng, Y. F. Li, Q. Shao, L. Zhang, X. Q. Huang,* H-implanted Pd icosahedra for oxygen reduction catalysis: from calculation to practice. CCS Chem., 2021, 3 (8), 1972−1982. (IF = 11.2)

[32] L. Z. Bu, B. L. Huang, Y. M. Zhu, F. D. Ning, X. C. Zhou, X. Q. Huang,* Highly distorted platinum nanorods for high-efficiency fuel cell catalysis. CCS Chem., 2020, 2 (5), 401−412. (IF = 11.2)

[33] L. Y. Wang, C. H. Zhan, W. Yan, Y. H. Li,* L. Z. Bu,* Hierarchical platinum–nickel@platinum–tin core@shell nanowires achieve efficient fuel cell catalysis. J. Mater. Chem. A, 2024, 12 (22), 13458−13465. (IF = 10.8)

[34] Y. H. Liu, C. H. Zhan, J. T. Zhang, L. Z. Bu,* X. Q. Huang,* Mass production of a dealloyed Pt3Co/C catalyst for oxygen reduction catalysis in PEMFCs. J. Mater. Chem. A, 2023, 11 (3), 1455−1460. (IF = 11.9)

[35] M. M. Wang, M. J. Wang, C. H. Zhan, H. B. Geng, Y. H. Li,* X. Q. Huang,* L. Z. Bu,* Ultrafine platinum-iridium distorted nanowires as robust catalysts toward bifunctional hydrogen catalysis. J. Mater. Chem. A, 2022, 10 (36), 18972−18977. (IF = 14.511)

[36] J. T. Zhang,# J. B. Le,# Y. T. Dong, L. Z. Bu,* Y. Zhang, J. Cheng, L. G. Li, X. Q. Huang,* Face-centered cubic structured RuCu hollow urchin-like nanospheres enable remarkable hydrogen evolution catalysis. Sci. China Chem., 2022, 65 (1), 87−95. (IF = 10.138)

[37] L. B. Liu,# C. Y. Tang,# L. Z. Bu,* X. H. Xiao, X. Q. Huang,* Two-dimensional PtPb-PbS heterostructure enables improved kinetics and highlighted bifunctional antipoisoning for methanol electrooxidation. Sci. China Chem., 2022, 65 (6), 1112−1121. (IF = 10.138)

[38] L. Z. Bu, Q. Shao, X. Q. Huang,* Highly porous Pt-Pb nanostructures as active and ultrastable catalysts for polyhydric alcohol electrooxidations. Sci. China Mater., 2019, 62 (3), 341−350. (IF = 6.098)

[39] M. M. Wang,# C. Y. Tang,# S. Z. Geng, C. H. Zhan, L. Y. Wang, W. H. Huang, C. W. Pao, Z. W. Hu, Y. H. Li, X. Q. Huang, L. Z. Bu,* Compressive strain in platinum-iridium-nickel zigzag-like nanowire boosts hydrogen catalysis. Small, 2024, 20 (22): 2310036. (IF = 13)

[40] L. B. Liu, Y. J. Ji, W. T. You, S. H. Liu, Q. Shao,* Q. Y. Kong, Z. W. Hu, H. B. Tao, L. Z. Bu,* X. Q. Huang,* Trace lattice S inserted RuO2 flexible nanosheets for efficient and long-term acidic oxygen evolution catalysis. Small, 2023, 19 (38), 2208202. (IF = 13.3)

[41] T. Yang,# C. Y. Yang,# J. B. Le, Z. Y. Yu, L. Z. Bu,* L. G. Li, S. X. Bai, Q. Shao, Z. W. Hu, C. W. Pao, J. Cheng,* Y. G. Feng, X. Q. Huang,* Atomically isolated Pd sites within Pd-S nanocrystals enable trifunctional catalysis for direct, electrocatalytic and photocatalytic syntheses of H2O2. Nano Res., 2022, 15 (3), 1861−1867. (IF = 10.269)

[42] L. Z. Bu, Y. G. Feng, J. L. Yao,* S. J. Guo, J. Guo, X. Q. Huang,* Facet and dimensionality control of Pt nanostructures for efficient oxygen reduction and methanol oxidation electrocatalysts. Nano Res., 2016, 9 (9), 2811−2821. (IF = 8.893)

[43] J. J. Meng, L. Z. Bu,* D. Wang,* Molybdenum-modified platinum nanoparticles confined on Ni-encapsulated carbon nanotubes with strong metal-support interaction for efficient hydrogen evolution catalysis. Chem. Eng. Sci., 2025, 317, 122041. (IF = 4.3)

[44] D. W. Xu, D. P. Xuan, Y. C. Liao, F. Q. Luo, T. Y. Lyu, M. H. Chen, C. R. Liu, Q. Liu, Z. Wang, S. R. Li, D. C. Wang,* Z. F. Zheng,* L. Z. Bu,* Lignin-derived carbon membrane for the preparation of composite electrodes and applications in supercapacitors. Diam. Relat. Mater., 2022, 129, 109344. (IF = 4.1)