宁岁婷

发布时间：2025年07月01日 14:53 阅读人数：

	姓名：宁岁婷	研究方向：计算物理，材料物理，核技术应用
	导师类型：硕士生导师	主讲硕士生课程：
	职称：	主讲博士生课程：
	专业：	联系方式：ningsuiting@hbut.edu.cn

宁岁婷，女，博士，硕士生导师。2014年毕业于广西大学，获物理学专业学士学位；2023年毕业于武汉大学，获粒子物理与原子核物理专业博士学位。主要从事热电材料性能与缺陷的第一性原理计算、及材料微结构调控的实验研究。主持一项国家自然科学基金青年项目，作为骨干成员参与多项国家自然基金面上项目，发表SCI论文20余篇。

科研项目

1、国家自然科学基金青年项目 (项目号：12405334)：用正电子湮没研究Zintl化合物Mg₃Sb₂中的镁空位及其对热电输运的协同调控。 (主持)

2、湖北工业大学校科研启动基金：用正电子湮没研究GeTe中的空位缺陷调控及其对热电性能的协同优化。 (主持)

3、国家自然科学基金面上项目 (项目号：12175166)：β-Ga₂O₃中的缺陷结构对其热电性能调控的正电子湮没研究。 (参与)

4、国家自然科学基金面上项目 (项目号：12175079)：基于正电子湮没谱学研究冷烧结热电材料的微结构缺陷及其对热电性能的影响。 (参与)

5、国家自然科学基金面上项目 (项目号：12375289)：用正电子湮没研究硫族化合物中的空位缺陷调控及其对热电性能的协同优化。 (参与)

发表论文

[1] T. D. Zhang, S. T. Ning, T. T. Zhang, N. Qi, X. L. Su, X. F. Tang, and Z. Q. Chen*, Stepwise vacancy manipulation for optimized carrier concentration and blocked phonon transport realizing record high figure of merit zT in CuInTe₂, Advanced Functional Materials, 2025, 35，2419984.

[2] J. H. Xiang, T. T. Zhang, S. T. Ning, M. Jiang, N. Qi, and Z. Q. Chen*, Enhanced thermoelectric properties of Zintl compound KCaBi by tensile strain: A first-principles study, Physica B: Condensed Matter, 2025, 713, 417338.

[3] S. T. Ning, Z. Y. Zhang, N. Hu, N. J. Lv, M. Jiang, N. Qi, and Z. Q. Chen*, Tunable thermoelectric performance in metal–organic framework Ni(BDC) studied by first principles, Microporous and Mesoporous Materials, 2024, 364, 112880.

[4] X. B. Chen, S. T. Ning, T. Yu, X. Qu, N. Qi and Z. Q. Chen*, Optimization of carrier concentration in Cu₂₂Sn₁₀S₃₂ through In- and Zn-doping for enhanced thermoelectric performance, ACS Applied Energy Materials, 2024, 7, 508-516.

[5] W. F. Pan, S. T. Ning, L. L. Chen, and Z. Q. Chen*, First-principles study of bismuthene as a high energy density and excellent rate performance anode material for potassium-ion batteries, Physica Scripta, 2024, 99, 015930.

[6] F. Mo, T. T. Zhang, S. T. Ning, N. Qi, and Z. Q. Chen*, Thermoelectric performance of Ag₂GeX₃ (X = S, Se, Te) with intrinsically low lattice thermal conductivity: A first principles study, Physica B: Condensed Matter, 2024, 690, 416217.

[7] X. D. Zhao, T. Yu, B. Zhou, S. T. Ning, X. B. Chen, N. Qi, and Z. Q. Chen*, Extremely low lattice thermal conductivity and significantly enhanced near-room-temperature thermoelectric performance in α-Cu₂Se through the incorporation of porous carbon, ACS Applied Materials & Interfaces, 2024, 16, 1333-1341.

[8] T. Yu, S. T. Ning, T. T. Zhang, X. B. Chen, Q. Liu, N. Qi, Z. Q. Chen*, X. L. Su, and X. F. Tang, Vacancy controlled n–p conduction type transition in CuAgSe with superior thermoelectric performance. Journal of Materials Chemistry A, 2023, 11, 4088–4101.

[9] T. Yu, S. T. Ning, Q. Liu, T. T. Zhang, X. B. Chen, N. Qi, X. L. Su, X. F. Tang and Z. Q. Chen*, Balanced high thermoelectric performance in n-type and p-type CuAgSe realized through vacancy manipulation. ACS Applied Materials & Interfaces, 2023, 13, 40781-40791.

[10] T. T. Zhang, S. T. Ning, Z. Y. Zhang, N. Qi and Z. Q. Chen*, Dimensionality reduction induced synergetic optimization of the thermoelectric properties in Bi₂Si₂X₆ (X = Se, Te) monolayers, Physical Chemistry Chemical Physics, 2023, 25, 25029-25037.

[11] T. T. Zhang, T. Yu, S. T. Ning, Z. Y. Zhang, N. Qi and Z. Q. Chen*, Extremely low lattice thermal conductivity leading to superior thermoelectric performance in Cu₄TiSe₄. ACS Applied Materials & Interfaces, 2023, 15, 32453-32462.

[12] S. T. Ning, S. Huang, Z. Y. Zhang, N. Qi, M. Jiang, Z. Q. Chen* and X. F. Tang, Band convergence boosted high thermoelectric performance of Zintl compound Mg₃Sb₂ achieved by biaxial strains, Journal of Materiomics, 2022, 8, 1086-1094.

[13] S. T. Ning, S. Huang, Z. Y. Zhang, B. Zhao, R. Q. Zhang, N. Qi and Z. Q. Chen*, β-Ga₂O₃: a potential high-temperature thermoelectric material, Physical Chemistry Chemical Physics, 2022, 24, 12052–12062.

[14] S. T. Ning, S. Huang, T. T. Zhang, Z. Y. Zhang, N. Qi, and Z. Q. Chen*, Two-dimensional β-PdX₂ (X=S, Se and Te) monolayers for thermoelectric applications, Journal of Physical Chemistry C, 2022, 126, 17885–17893.

[15] H. J. Wu, S. T. Ning, X. B. Chen, T. Yu, T. D. Zhang, X. Qu, N. Qi and Z. Q. Chen*, Giant reduction in the thermal conductivity of porous β-Ga₂O₃ with multiple heat-blocking mechanisms. ACS Applied Energy Materials, 2022, 5, 11441−11449.

[16] T. D. Zhang, W. F. Pan, S. T. Ning, N. Qi*, Z. Q. Chen*, X. L. Su, and X. F. Tang, Vacancy Manipulation Induced Optimal Carrier Concentration, Band convergence and low lattice thermal conductivity in nano-crystalline SnTe yielding superior thermoelectric performance, Advanced Functional Materials, 2022, 2213761.

[17] C. Wang, X. D. Zhao, S. T. Ning, Q. R. Tao, Y. F. Tang, Z. Q. Chen, J. S. Wu, X. L. Su*, X. F. Tang*, Phase boundary mapping and suppressing Pb vacancies for enhanced thermoelectric properties in n-type Sb doped PbTe compounds, Materials Today Energy, 2022, 25, 100962.

[18] C. Wang, K. K. Liu, Q. R. Tao, X. D. Zhao, S. T. Ning, Y. F. Tang, Z. Q. Chen, J. S. Wu, X. L. Su*, C. Uher, Q. J. Zhang, and X. F. Tang*, Avoiding oxygen induced Pb vacancies for high thermoelectric performance of n-type Bi-doped Pb₁₋_xBi_xTe compounds, Materials Today Physics, 2022, 27, 100781.

[19] B. H. Jia, Y. Huang, Y. Wang, Y. S. Y. Zhou, X. D. Zhao, S. T. Ning, X. Xu, P. J. Lin, Z. Q. Chen, B. B. Jiang* and J. Q. He*, Realizing high thermoelectric performance in non-nanostructured n-type PbTe, Energy & Environmental Science, 2022, 15, 1920–1929.

[20] X. D. Zhao, S. T. Ning, N. Qi, Y. H. Li, Y. Dong, H. J. Zhang*, J. D. Liu, B. J. Ye, and Z. Q. Chen*, Synergetic optimization of electrical and thermal transport properties by Cu vacancies and nanopores in Cu₂Se, ACS Applied Materials & Interfaces, 2021, 13, 58936−58948.

[21] H. J. Wu, S. T. Ning, N. Qi, F. Ren*, Z. Q. Chen*, X. Su and X. F. Tang, Extremely low thermal conductivity of β-Ga₂O₃ with porous structure, Journal of Applied Physics, 2021, 130, 195103.

[22] H. J. Wu, L. L. Chen, S. T. Ning, X. D. Zhao, S. P. Deng, N. Qi, F. Ren*, Z. Q. Chen*, and J. Tang, Extremely low thermal conductivity and enhanced thermoelectric performance of porous Gallium-Doped In₂O₃, ACS Applied Energy Materials, 2021, 4, 12943−12953.

[23] S. T. Ning, S. Huang, Z. Y. Zhang, R. Q. Zhang, N. Qi and Z. Q. Chen*, High thermoelectric performance of topological half-Heusler compound LaPtBi achieved by hydrostatic pressure, Physical Chemistry Chemical Physics, 2020, 22, 14621-14629.

[24] Q. K. Zhang, S. T. Ning, N. Qi, Z. Q. Chen*, X. F. Tang, and Z. Y. Chen, Enhanced thermoelectric performance of a simple method prepared polycrystalline SnSe optimized by spark plasma sintering, Journal of Applied Physics, 2019, 125, 225109.

专利

李添悦，吕侯军，宁岁婷，一种基于PSD激光位置探测装置，实用新型专利 (公开号：CN207113796U)。