黄传甫,中国矿业大学材料与物理学院副教授、硕士生导师,获美国南加州大学物理学博士学位,2023—2024年南京大学访问学者。曾入选江苏省“双创博士”计划,江苏省“科技副总”,第十一批中国矿业大学青年优秀骨干教师等。
目前主要研究方向为金属纳米团簇/结构的等离激元性质调控、纳米颗粒的光催化性能改性,以及水团簇中酸性分子的解离机制。近年来主持和参与国家自然科学基金及美国国家自然科学基金等各类科研项目十余项。在 J. Chem. Phys.、Phys. Rev. A、PCCP、J. Phys. Chem.等经典期刊发表论文三十余篇。
部分论文(*通讯作者):
·C. F. Huang*, L. Zhuang, J. Wang, J. G. Wan. Correlation between acid dissociation states and average dipole moments of HCl-water clusters realized by a strong electric field. Physical Review A, 111, L020802 (2025).
·R. Han, X. Yang, L. Zhang, Y. Y. Li, L. W. Shi, C. Y. Lan, C. F. Huang*. Enhanced photocatalytic activity of Ho, Mn co-doped BiFeO3: Synthesis and mechanistic insight. Ceramics International, In press, (2025).
·X. Xi, Z. Wang, H. Zhang, J. G. Wan, C. F. Huang*, Nonlocal effects in plasmons of grooved gold cylindrical structures based on modified hydrodynamic theory. Journal of Physical Chemistry C, 129, 2074 (2025).
·X. Yang, R. Han, L. W. Shi, Y. Y. Li, C. Y. Lan, L. M. Chen, C. F. Huang*. Dual-site engineering of La/Ti co-doped BiFeO3 for enhanced visible-light photocatalytic degradation: Synergistic effects and high stability. Journal of Alloys and Compounds, 1039, 183239 (2025).
·L. Zhuang, J. Wang, J. G. Wan, C. F. Huang*, Why do dipole moments of HCl–water clusters fail to determine acid dissociation? Physical Chemistry Chemical Physics, 26, 17910(2024).
·J. Wang, L. Zhuang, J. G. Wan, C. F. Huang*. Dissociation of HBr in water clusters based on a hybrid density functional approach (Front Cover). Journal of Physical Chemistry A 128, 7364 (2024).
·C. F. Huang*, et al., Preparation, characterization, and mechanism for enhanced photocatalytic performance in Bi1-xSmxFeO3 nanoparticles. Journal of Sol-Gel Science and Technology, 110, 736 (2024).
·C. F. Huang*, Z. Wang, H. Zhang, Y. Nie, J. G. Wan, Tuning nonlocal effects in grooved cylindrical plasmons by hydrodynamic model: A competing mechanism. Results in Physics, 54, 107121 (2023).
·Y. Nie, H. E. Ma, Z. Wang, C. Y. Lan, W. Zhang, L. M. Chen, C. F. Huang*, New insights into the photocatalytic and magnetic activity of Co-doped BiFeO3 nanoparticles via competing structures. Journal of Physics D: Applied Physics, 56, 234002 (2023).
·H. Zhang, C. F. Huang*, Optical response and spill-out effects of metal nanostructures with arbitrary shape. Journal of the Optical Society of America B, 38, 3285 (2021).
·C. F. Huang*, and H. Zhang, A simple derivation of the shell polarizability formula and investigation of the plasmonic behavior of aluminum nanoshells with the Mie theory (Back Cover, 2021 PCCP Hot article). Physical Chemistry Chemical Physics, 23, 23501 (2021).
·C. F. Huang*, Experimental methodology of water cluster doping. Acta Physica Sinica, 70, 183601 (2021).
·C. F. Huang*, A new model for explanation and generation of branched flow of light. Applied Physics B: Lasers and Optics, 127, 58 (2021).
·C. F. Huang*, et al. Enhanced photoelectrocatalytic performance from size effects in pure and La-doped BiFeO3 nanoparticles.Applied Physics A: Materials Science & Processing, 126, 273 (2020).
·C. F. Huang*, Plasmonic resonance in sodium clusters: competition mechanism between electron spill-out effect and quantum pressure in electron gas, Journal of Cluster Science, 31, 563 (2020).
·C. F. Huang*, Experimental study on construction of a newly supersonic oven with liquid lithium, Journal of Heat Transfer, 140, 092003 (2018).
·C. F. Huang*, Investigation of a simple pickup method for doping molecules into water clusters, Journal of Cluster Science, 29(6): 959~963 (2018).
·C. F. Huang*, Thermodynamic model for calculation the position of quitting surface of supersonic beam based on speed measurements, Journal of Physical Chemistry A, 122, 8998 (2018).
·C. F. Huang, V. V. Kresin, Contamination-free loading of lithium metal into a nozzle source, Review of Scientific Instruments, 87, 066105 (2016).
·C. F. Huang, V. V. Kresin, A. Pysanenko, M. Fárník, Water cluster fragmentation probed by pickup experiments, Journal of Chemical Physics, 145, 104304 (2016).
