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尹鑫茂,教授,yinxinmao@shu.edu.cn
ORCID:https://orcid.org/0000-0002-8246-4444
研究领域:量子材料的光谱学研究。利用多种光谱技术对物体中复杂的电荷-自旋-轨道-晶格相互耦合作用及演变过程进行研究,从而对量子材料的超导、磁性、量子相变等宏观物理性质,以及电子结构、自旋变化、量子态准粒子激发等微观物理性质进行信息解析。主要涉及高温超导材料,超巨磁阻材料,氧化物界面、二维材料及其界面等。近5年来在国际高水平期刊上发表论文近50篇,包括PRL, APR, Science Advances,Nature Communications等顶级期刊,多项研究被ScienceDaily, Phys.Org, EurekAlert AAAS, Materials Today等专业新闻媒体报道。研究成果多次被杂志选为封面文章。同时是多个知名国际期刊的特邀审稿人,包括Nature Communications, Advanced Functional Materials, ACS Nano, Advanced Optical Materials等。
教育经历:
2010.08 - 2015.06 博士, 新加坡国立大学, 物理
2006.09 - 2010.06 本科, 浙江大学, 竺可桢学院
工作经历:
2021.03 - 至今 教授(上海市海外高层次人才), 上海大学, 物理系
2014.08 - 2021.02 兼职研究员, 新加坡同步辐射光源
2014.08 - 2021.02 研究员, 新加坡国立大学, 物理系
研究兴趣:
高温超导量子材料及关联氧化物的电子结构的光谱学研究
钙钛矿氧化物界面(二维电子气)电子信息的光谱学研究
新型量子态准粒子的探索和光谱学研究
二维量子材料电子结构、量子相变的光谱学研究
代表性学术论文:
2021年:
18. Observation of perfect diamagnetism and interfacial effect on the electronic structures in Nd0.8Sr0.2NiO2 superconducting infinite layers. arXiv preprint arXiv:2104.14195 (2021)
17. 1D chained structure in quasi-metallic phase 2D transition metal dichalcogenides and their anisotropic electronic structures. Applied Physics Reviews 8, 011313 (2021) (invited review). Selected as Featured Article.
16. Dynamic Segregation of Reduced Ruddlesden-Popper Sr2NiO3 and SrNi2O3 Phases during SrNiO3 Epitaxial Growth. Science Advances 7(10), eabe2866 (2021).
2020年以前:
15. Phase diagram and superconducting dome of infinite-layer Nd1-xSrxNiO2 thin films. Physical Review Letters 125, 147003 (2020)
14. Interfacial oxygen-driven charge localization and plasmon excitation in unconventional superconductors. Advanced Materials 32, 2000153 (2020). Selected as Back Cover.
13. Anisotropic collective charge excitations in quasimetallic 2D transition-metal dichalcogenides. Advanced Science 7 (10), 1902726 (2020). Selected as Inside Cover. It was reported in many science news (Anisotropic plasmons in quasi-metallic 2D materials), such as Phys.Org, NewsBeezer, Knowledia New, QNewsHub.
12. Electronic Modulation in Site-Selective Occupation of Quasi-2D Triangular-lattice Cs2CuCl4-xBrx Perovskite. ACS Appl. Mater. Interfaces. 12 (3) 4114-4122 (2020).
11. Quantum correlated plasmons and their tunability in undoped and doped Mott-insulator cuprates. ACS Photonics 6(12), 3281-3289 (2019).
10. Modulation of new excitons in transition metal dichalcogenide-perovskite oxide system. Advanced Science 6 (12), 1900446 (2019). Selected as Frontispiece Cover.
9. Three-dimensional resonant exciton in monolayer tungsten diselenide actuated by spin-orbit coupling. ACS Nano 13 (12), 14529-14539 (2019).
8. Unravelling High-Yield Phase-Transition Dynamics in Transition Metal Dichalcogenides on Metallic Substrates. Advanced Science 6 (7), 1802093 (2019). Selected as Frontispiece Cover). It was reported in many science news (Phase transition dynamics in two-dimensional materials), such as ScienceDaily, Phys.Org, EurekAlert AAAS.
7. Oxygen Electromigration and Energy Band Reconstruction Induced by Electrolyte Field Effect at Oxide Interfaces. Physical Review Letters 121, 146802 (2018)
6. Modulation of manganite nano-film properties mediated by strong influence of strontium titanate excitons. ACS Applied Materials & Interfaces 10 (41), 35563-35570 (2018).
5. The Mechanism of Electrolyte Gating on High-Tc Cuprates: The Role of Oxygen Migration and Electrostatics. ACS Nano 11 (10), 9950 (2017)
4. Tunable Inverted Gap in Monolayer Quasi-Metallic MoS2 Induced by Strong Charge-Lattice Coupling. Nature Communications 8, 486 (2017). This work was highlighted inhttps://doi.org/10.1557/mrs.2017.246. It was reported in many science news (Scientists unravel new insights into promising semiconductor material), such as ScienceDaily, Phys.Org, EurekAlert AAAS, Materials Today News, AZoMaterials, EE World Online.
3. Unraveling the magnetic coupling in the interface of the exchange-biased IrMn/Permalloy multilayers. Materials Letters 187, 133-135 (2017).
2. Coexistence of Midgap Antiferromagnetic and Mott States in Undoped, Hole- and Electron-Doped Ambipolar Cuprates. Physical Review Letters 116, 197002 (2016).
1. Unraveling the interplay of electronic and spin structures in controlling macroscopic properties of manganite ultra-thin films. NPG (Nature Publishing Group) Asia Materials 7, e196 (2015).
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