2009.09–2013.07，哈尔滨理工大学，材料物理学，学士

2013.08–2016.04，哈尔滨理工大学，物理学，硕士

2016.08–2019.06，哈尔滨理工大学，材料学，博士

2019.07–2023.05，哈尔滨理工大学，讲师/副教授

2020.05–2023.05，中国科学院金属研究所，博士后

2023.06–至今，中国科学院金属研究所，副研究员

1.塑晶玻璃晶体的热物性及功能特性研究

2.固态相变制冷与储热技术

3.基于第一性原理计算及机器学习，对新型形状记忆合金等热功能材料的设计与开发

1.黑龙江省自然科学基金优秀青年基金，2022–2025，项目负责人

2.国家自然科学基金青年基金，2021–2023，项目负责人

3.中国博士后科学基金面上资助项目，2021-2023，项目负责人

学术论文：(*:通讯作者)

1.K. Zhang#, Zhe Zhang#, H. Pan, X. Zhao, J. Qi, Zhao Zhang, R. Song, C. Yu, B. Huang, X. Li, H. Chen, C. Tan, W. Yin, W. Hu, M. Wübbenhorst, J. Luo*, D. Yu*, Z. Zhang, B. Li*. Glassy crystals with colossal multi-baroresponsivities. arXiv preprint arXiv:2209.04763, 2022

2.X. Zhao, K. Zhang*, Ji Qi, P. Liu, Z. Zhang, L. Qu, Z. Zhang & B. Li*. Low-pressure-driven barocaloric effects at colinear-to-triangular antiferromagnetic transitions in Mn3-xPt1+x. Microstructures, 3(3): 2023022, 2023

3.Q. Xia, C. Tan*, T. Ma, R. Liu, X. Tian & K. Zhang*. The impact of hydrostatic pressure and uniaxial strain on the of Ni-Co-Mn-Sb Heusler alloy involving 4O martensite. Materials Today Communications, 34:105271, 2023

4.K. Zhang, R. Song, J. Qi, Z. Zhang, Z. Zhang, C. Yu, K. Li, Z. Zhang & B. Li*. Colossal barocaloric effect in carboranes as a performance tradeoff. Advanced Functional Materials, 32:2112622, 2022

5.W. Zhao, K. Zhang*, E. Guo, X. Tian & C. Tan*. Martensitic transformation mechanism of Mg-Sc lightweight shape memory alloys. Scripta Materialia, 207:114316, 2022

6.X. Tian, D. Shi, K. Zhang*, H. Li, L. Zhou, T. Ma, C. Wang, Q. Wen & C. Tan*. Machine-learning model for prediction of martensitic transformation temperature in NiMnSn-based ferromagnetic shape memory alloys. Computational Materials Science, 215C:111811, 2022

7.Q. Xia, C. Tan*, B. Han, X. Tian*, L. Zhao, W. Zhao, T. Ma, C. Wang & K. Zhang*. Strain engineering in Ni-Co-Mn-Sn magnetic shape memory alloys: Influence on the magnetic properties and martensitic transformation. Materials, 15:5889, 2022

8.T. Ma, K. Zhang*, B. Han, L. Zhao, W. Zhao, C. Wang, X. Tian & C. Tan*. Dynamic control and increase of working temperature range in Ni-Mn-In-Co MCE materials by hydrostatic pressure or biaxial stress. Materials Today Communications, 32:104051, 2022

9.X. Wang, Ruixian Liu, K. Zhang*, R. Liu, J. Zhu, X. Tian & C. Tan*. Magnetic-induced dual-function tunable THz polarization conversion metamaterial based on Ni-Mn-Sn shape memory alloy films. Results in Optics, 9:100274, 2022

10.T. Ma, K. Zhang*, B. Han, L. Zhao, W. Zhao, C. Wang, R. Liu, X. Tian & C. Tan*. Simultaneous improvement of magnetic-field-induced working temperature and mechanical properties in Ni-Mn-In shape memory alloy. AIP Advances, 12: 065107, 2022

11.X. Tian, L. Zhou, K. Zhang*, Q. Zhao, H. Li, D. Shi, T. Ma, C. Wang, Q. Wen & C. Tan*. Screening for shape memory alloys with narrow thermal hysteresis using combined XGBoost and DFT calculation. Computational Materials Science, 211:111519, 2022

12.B. Han, X. Tian*, L. Zhao, W. Zhao, T. Ma, C. Wang, K. Zhang* & C. Tan*. Dynamically tunable operating temperature range of Ni-Co-Mn-Sn magnetic shape memory alloys via pressure modulation. Journal of Magnetism and Magnetic Materials, 553:169304, 2022

13.X. Tian, Q. Zhao, K. Zhang*, H. Li, B. Han, D. Shi, L. Zhou, T. Ma, C. Wang, Q. Wen* & C. Tan*. Accelerated design for elastocaloric performance in NiTi-based alloys through machine learning. Journal of Applied Physics,131(1):015104, 2022

14.K. Zhang*, T. Ma, J. Liu, X. Tian, J. Zhu & C. Tan*. Dynamically tunable and polarization-insensitive dual-band terahertz metamaterial absorber based on TiNi shape memory alloy films. Results in Physics, 23:104001, 2021

15.W. Zhao, E. Guo, K. Zhang*, X. Tian & C. Tan. Martensite phase structure of Mg-Sc lightweight shape memory alloy and the effect of rare earth elements doping. Scripta Materialia, 199:113863, 2021

16.C. Tan*, J. Liu, X. Tian, J. Zhu & K. Zhang*. Multifunctional and dynamically tunable terahertz metamaterials based on TiNi shape memory alloy films with a simple design. Results in Physics, 24:104165, 2021

17.B. Han, C. Tan*, L. Zhao, W. Zhao, T. Ma, C. Wang, K. Zhang* & X. Tian*. Investigation on phase structure and magnetic properties of high-temperature Ni-Pt-Co-Mn-Sn magnetic shape memory alloys by first-principles calculations. Computational Materials Science, 199:110748, 2021

18.K. Zhang, C. Tan*, W. Zhao, E. Guo & X. Tian. Computation-guided design of Ni-Mn-Sn ferromagnetic shape memory alloy with giant magnetocaloric effect and excellent mechanical properties and high working temperature via multi-element doping. ACS Applied Materials & Interfaces, 11(38):34827-34840, 2019

19.K. Zhang, C. Tan*, E. Guo, Z. Feng, J. Zhu, Y. Tong & W. Cai. Simultaneous tuning of martensitic transformation behavior, magnetic and mechanical properties in Ni-Mn-Sn magnetic alloy by Cu doping. Journal of Materials Chemistry C, 6:5228-5238, 2018

20.K. Zhang, X. Tian*, C. Tan, E. Guo, W. Zhao & W. Cai. Designing a new Ni-Mn-Sn ferromagnetic shape memory material with excellent performance by Cu doping. Metals, 8(3):152, 2018

发明专利：

1.张琨,谭昌龙,田晓华,赵文彬,黄跃武.“一种高温高韧大磁热效应的Ni-Co-Mn-Sn-Cu合金、制备方法及其应用” 201910798078.5

2.张琨，谭昌龙，刘娟，田晓华，黄跃武，赵文彬. “一种基于TiNi形状记忆合金薄膜的可动态调控的多功能太赫兹超材料器件” ZL 202011495226.5

3.李昺，张琨，张志东. “一种碳硼烷材料在固态制冷中的应用” 202110831315.0

4.李昺，张琨，张志东. “一种基于玻璃晶体且主动可控的固态相变储热方法” 202210034888.5; PCT/CN2022/072655

5.张琨，刘锐，谭昌龙，王晓川，刘瑞娴，田晓华. “一种基于Ni-Mn-Sn形状记忆合金薄膜的多功能太赫兹超材料吸收器” 202210592509.4

6.张琨，王晓川，谭昌龙，田晓华. “一种基于Ni-Mn-Sn形状记忆合金的多功能太赫兹超材料偏振转换器件” 202210592508.X

7.李昺，张琨，张志东.“一种基于玻璃晶体对压力响应实现压力传感的方法及其应用”202211074763.1

8.李昺，张琨，宋睿琪，王皓宇，张志东. “一种基于塑晶玻璃晶体相的精细化可控放热装置及放热方法和应用” 202310362509X

9.李昺，张琨，宋睿琪，王皓宇，张志东. “基于塑晶玻璃晶体相的精细化可控放热装置” 2023207446361

10.谭昌龙，杨杰，张琨，赵文彬，田晓华. “一种高弹热效应块体Co-V-Ga-Mn基记忆合金及其制备方法” 2023103205572

11.田晓华，赵文彬，詹亚博，谭昌龙，张琨. “一种高弹热性能的NiMnSnTi制备方法” 2023103205553