磁电子材料与器件研究组

何日，博士，副研究员

电子邮箱：heri@nimte.ac.cn

教育工作经历：

(1) 2008-09 至 2012-06, 沈阳建筑大学, 无机非金属材料科学与工程, 学士

(2) 2012-09 至 2019-01, 东北大学, 材料学, 博士

(3) 2019-04 至 2021-05, 华南师范大学,先进光电子学院，博士后

(4) 2021-05 至 2023-12, 中国科学院宁波材料技术与工程研究所，中科院磁性材料与器件重点实验室，博士后

(5) 2023-12 至今中国科学院宁波材料技术与工程研究所，中科院磁性材料与器件重点实验室，副研究员

研究方向：长期从事材料理论计算模拟方向的研究工作，综合运用基于密度泛函理论的第一性原理计算、基于机器学习的深度势能分子动力学、基于朗道-德文希尔自由能的相场模型，研究复杂氧化物铁电、介电材料的构性关系，设计新型功能氧化物电子器件。

主持项目：
(1) 国家自然科学基金委员会,青年科学基金项目, 12204496, 基于深度学习的钛酸锶孪晶界多物理场响应的理论计算研究, 2023-01-01 至 2025-12-31,30万元,主持

(2) 浙江省自然科学基金委员会,自然科学基金探索项目, Q23A040003, 基于深度学习的铁基软磁非晶合金原子结构与构性关系的理论计算研究, 2023-01 至 2025-12,10万元,主持

(3) 宁波市自然科学基金委员会,自然科学基金一般项目, 基于深度学习的铪基铁电畴界、相界多物理场响应的理论计算研究, 2023-06 至 2025-6, 6万元,主持

(4) 国家自然科学基金委员会,专项项目, 12241201, 基于潜径迹方法的微纳尺度反应流动传质研究, 2023-01-01 至 2026-12-31, 30/300万元, 参与（材料所唯一）

论文发表情况：

(1) Ri He #; Bingwen Zhang#; Hua Wang; Lei Li; Tang Ping; Garrit Bauer; Zhicheng Zhong*; Acta Materialia 262, 119416 (2023).

(2) Ri He, Hua Wang*, Fucai Liu, Shi Liu, Houfang Liu, Zhicheng Zhong*; Unconventional ferroelectric domain switching dynamics in CuInP2S6 from first principles, Physical Review B 108, 024305 (2023).

(3) Ri He, Hongyu Wu, Xuejian Qin, Xuejiao Chen, Zhicheng Zhong*; Pressure-induced one-dimensional oxygen ion diffusion channel in lead-apatite, Physical Review B Appacped (2023).

(4) Ri He, H Xu, Peijun Yang, Kkai Chang, Hhua Wang, Zhicheng Zhong*; Ferroelastic twin wall mediated ferro-flexoelectricity and bulk photovoltaic effect in SrTiO3, arXiv:2310.10130 Physical Review L under review (2023).

(5) Minghao Shao#, Yuzhe Yang#, Ri He#, Ruiting Zhao, X Renshaw Wang, Zhicheng Zhong, Houfang Liu*, Yi Yang, Tian-Ling Ren; Advanced Electronic Materials, 2300352 (2023).

(6) Liang Gao, Ben-Lin Hu, Linping Wang, Jinwei Cao, Ri He, Fengyuan Zhang, Zhiming Wang, Wuhong Xue, Huali Yang, Run-Wei Li; Intrinsically elastic polymer ferroelectric by slight crosslinking. Science 381 (6657), 540-544 (2023).

(7) Qian Xiong^#, Xingbao Zhu^#, Ri He, Xueyi Mei, Yexin Zhang*, Zhicheng Zhong*, Wei Zhao, Weiming Nie, Jian Zhang*, Local Joule heating targets catalyst surface for hydrocarbon combustion, Journal of Industrial and Engineering Chemistry, 117, 273-281 (2023).

(8) Huiyuan Liu, Xiaojian Zhu, Zhecheng Guo, Ri He, Xinze Li, Qihao Sun, Xiaoyu Ye, Cui Sun, Yu Tian, Run-Wei Li; Artificial Spiking Neuron with Bursting Dynamics for Noise-Resistant Neuromorphic Coding, ACS Applied Electronic Materials (2023).

(9) Fenglin Deng, Hongyu Wu, Ri He, Peijun Yang, Zhicheng Zhong, Large-scale atomistic simulation of dislocation core structure in face-centered cubic metal with Deep Potential method, Computational Materials Science, 218: 111941 (2023).

(10) Ri He^#; Hongyu Wu^#; Linfeng Zhang; Xiaoxu Wang; Fangjia Fu; Shi Liu; Zhicheng Zhong ;Structural phase transitions in SrTiO₃ from deep potential molecular dynamics, Physical Review B, 105(6): 064104 (2022).

(11) Ri He; Hongyu Wu; Yi Lu; Zhicheng Zhong ; Origin of negative thermal expansion and pressure-induced amorphization in zirconium tungstate from a machine-learning potential, Physical Review B, 106: 174101 (2022).

(12) Hongyu Wu^#; Ri He^#; Yi Lu; Zhicheng Zhong; Large-scale Atomistic Simulation of Quantum Effects in SrTiO3 from First Principles, Physical Review B, 106：224102 (2022).

(13) W. Xue, Q. Jiang, F. Wang, Ri He, R. Pang, H. Yang, P. Wang, R. Yang, Z. Zhong, T. Zhai, X. Xu Discovery of Robust Ferroelectricity in 2D Defective Semiconductor α-Ga2Se3, Small, 10, 210059 (2022).

(14) H. Zhong, M. Li, Q. Zhang, L. Yang, Ri He, F. Liu, Z. Liu, G. Li, Q. Sun, D. Xie, F. Meng, Q. Li, M. He, E. Guo, C. Wang, Z. Zhong, X. Wang, L. Gu, G. Yang, K. Jin, P. Gao, C. Ge; Large-Scale Hf0.5Zr0.5O2 Membranes with Robust Ferroelectricity, Advanced Materials, 4, 2109889 (2022).

(15) S. Xie; Ri He; Q Zhu; M Jin; R Yang; S Shen; J Cui; Y Zou; M Zhang; L Shui, Colloids and Surfaces, A. Physicochemical and Engineering Aspects, 644 (2022).

(16) Jun Liang Lin^#, Yuanwei Sun^#, Ri He^#; Colossal Room-Temperature Ferroelectric Polarizations in SrTiO3/SrRuO3 Superlattices Induced by Oxygen Vacancies, Nano Letters, 22(17): 7104–7111 (2022).

(17) Ri He^#; Hongyu Wu^#; Shi Liu; Houfang Liu; Zhicheng Zhong ; Ferroelectric structural transition in hafnium oxide induced by charged oxygen vacancies, Physical Review B,104(18): L180102 (2021).

(18) Minghao Shao^#, Houfang Liu^#, Ri He^#, Xiaomei Li^#, Ruiting Zhao, Liang Wu, Ji Ma, Zhicheng Zhong, Yi Yu, Caihua Wan, Xuedong Bai, Tianling Ren, X. Renshaw Wang, arXiv preprint. 2106.10837. Physical Review L under review (2021).

(19) Ri He; Peiheng Jiang; Yi Lu; Yidao Song; Mingxing Chen; Mingliang Jin; Lingling Shui; Zhicheng Zhong; Polarity-induced electronic and atomic reconstruction at NdNiO2/SrTiO3 interfaces, Physical Review B, 102(3): 035118 (2020).

(20) Ri He^#; Jun Liang Lin^#; Qing Liu; Zhaoliang Liao; Lingling Shui; Zhan Jie Wang; Zhicheng Zhong; Run-Wei Li; Emergent ferroelectricity in otherwise nonferroelectric oxides by oxygen vacancy design at heterointerfaces, ACS Applied Materials & Interfaces, 12(40): 45602-45610 (2020).

(21) Jun Liang Lin^#; Ri He^#; Zengxing Lu; Yi Lu; Zhiming Wang; Zhicheng Zhong; Xiang Zhao; Run-Wei Li; Zhi Dong Zhang; Zhan Jie Wang; Oxygen vacancy enhanced ferroelectricity in BTO:SRO nanocomposite films, Acta Materialia, 199: 9–18 (2020).

(22) Song Y H, Wang M T, Ri He, Zong Y P, Jin J F. Grain Refinement by Second Phase Particles under Applied Stress in ZK60 Mg Alloy with Y through Phase Field Simulation. Materials, 11(10) (2018).

(23) Ri He; Ming-Tao Wang; Jian-Feng Jin; Ya-Ping Zong; Effect of elastic strain energy on grain growth and texture in AZ31 magnesium alloy by phase-field simulation, Chinese Physics B, 26(12): 128201 (2017).

(24) Xianggang Zhang, Wang MT, Ri He, Zong Y P. A phase field model to simulate competitive precipitation of Mg2Sn along the basal or pyramidal habit planes in Mg-2.2Sn-0.1Zn alloy. Computational Materials Science, 127: 261-269 (2017).

(25) Ri He; Mingtao Wang; Xiangang Zhang; Bernie Yaping Zong; Influence of second-phase particles on grain growth in AZ31 magnesium alloy during equal channel angular pressing by phase feld simulation, Modelling and Simulation in Materials Science and Engineering, 24: 055017 (2016).