参与河南省资源共享课程建设,先后荣获河南大学教学质量二等奖, 河南省教育系统教学技能竞赛二等奖,河南省教育系统教学技能竞赛一等奖,河南省教学标兵。相继主持国家自然科学基金项目、河南省自然科学基金项目和河南省教育厅科学技术研究重点研究项目,参与国家国家自然科学基金面上项目和河南省基础研究创新团队等多个研究课题,获得河南省自然科学二等奖1项。
Chen D., Wang C. L, Liu F. F., Peng C. X.∗, “Variation of magnetism in a two-dimensional non-van der Waals MnS2 bilayer,” Applied Surface Science, vol. 609, p. 155 336, 2023.
Chen X. F., Han W. N., Tian Z. Z., Yue Q., Peng C. X.∗, Wang C., Wang B., Yin H. B., Gu Q. F., “Exploration of Photocatalytic Overall Water Splitting Mechanisms in the Z-Scheme SnS2/β -As Heterostructure,” The Journal of Physical Chemistry C, vol. 127, pp. 6347–6355, 2023.
Chen X. F., Han W. N., Yue Q., Zhang Q. M., Liang Y., Peng C. X.∗, Yin H. B., “The Isoelectronic Dopant in the Z-Scheme SnS2/β-As Heterostructure Enhancing Photocatalytic Overall Water Splitting,” Inorganic Chemistry, 62, pp.17954–17960, 2023.
Chen X. F., Han W. N., Jia M. L., Ren F. Z., Peng C. X.∗, Gu Q. F., Wang B., Yin H. B., “A direct Z-scheme MoSi2N4/BlueP vdW heterostructure for photocatalytic overall water splitting,” Journal of Physics D-Applied Physics, vol. 55, p. 215 502, 2022.
Du X., Wang X., Xiao N. R., Tang Y. H., Peng C. X.∗, Wang K. F., “Atomic structure, electronic structure and optical absorption of inorganic perovskite compounds Cs2SnI6−nXn (X = F, Cl, Br; n = 0∼6): A first-principles study,” Solar Energy, vol. 245, pp. 25–36, 2022.
Fan W. J., Jin C., Peng C. X.∗, Ren F. Z., Li G. Q., Gu Q. F., “SrTiO3 /Ti3C2Tx Schottky heterojunction as a promising high-efficiency photocatalyst for H2 evolution,” Applied Physics Letters, vol. 121, p. 143905, 2022.
Han W. N., Chen X. F., Jia M. L., Ren F. Z., Peng C. X.∗, Yang H. G., Gu Q. F., Wang B., Yin H. B., “Adirect Z-scheme g-C6N6/InP van der Waals heterostructure: a promising photocatalyst for high-efficiency overall water splitting,” Journal of Physics D-Applied Physics, vol. 55, p. 264 001, 2022.
Li S. Y., Peng C. X.∗, Wang C., Chen Y. Q., Li L. W., Yang G., Cheng, Z. X., Wang, J. L., “In situ generation of flower-like and microspherical dendrites to improve thermoelectric properties of p-type Bi0.46Sb1.54Te3,” Materials Today Physics, vol. 23, p. 100633, 2022.
Ojih J., Onyekpe U., Rodriguez A., Hu J. J., Peng C. X.∗, Hu M., “Machine learning accelerated discovery of promising thermal energy storage materials with high heat capacity,” Acs Applied Materials & Interfaces, vol. 14, pp. 43 277–43 289, 2022.
Peng C. X., Fan W. J., Li Q., Han W. N., Chen X. F., Zhang G. B., Yan Y. L. Gu Q. F., Wang C., Zhang H. R., Zhang P. Y., “Boosting photocatalytic activity through tuning electron spin states and external fields,” Journal of Materials Science Technology, vol. 115, pp. 208–220, 2022.
Li L. W., Peng C. X.∗, Chen J., Ma Z., Chen Y. Q., Li S. Y., Wang J. L., Wang C., “Study the effect of alloying on the phase transition behavior and thermoelectric properties of Ag2S,” Journal of Alloys and Compounds, vol. 886, p. 161 241, 2021.
Liu L, Peng C. X.∗, Feng Z. Z., Yan Y. L., Zhang. G. B., Wang C., Zhang P. Y., Gu Q. F., “A Colossal Enhancement of Thermoelectric Performance of Monolayer SbAs Using Strain Engineering,” Physica Status Solidi-Rapid Research Letters, vol. 15, p. 2 100 175, 2021.