基本信息

                    杨思维

中国科学院上海微系统与信息技术研究所
电子邮件: yangsiwei@mail.sim.ac.cn
通信地址: 上海市嘉定区平城路1455号


招生专业

080501-材料物理与化学

0805J1-纳米科学与技术

0805Z2-半导体材料与器件



研究领域

1. 新型碳基二维半导体材料结构设计、制备及基本物性研究

2. 石墨烯量子点结构调制与机器学习辅助发光机理研究

3. 石墨烯量子点表界面物理、化学、生物作用机制研究

4. 激发态下碳纳米结构表界面性质研究

5. 石墨烯量子点疾病诊疗技术探索与应用示范

教育与工作经历

2022-01--至今,    中国科学院上海微系统与信息技术研究所, 副研究员

2019-07--2020-12,  中国科学院上海微系统与信息技术研究所, 助理研究员

2017-06--2019-07,  中国科学院上海微系统与信息技术研究所, 博士后

2013-09--2017-05,  中国科学院上海微系统与信息技术研究所, 工学博士

所获荣誉

2014   研究生国家奖学金(博士)

2015   中国科学院大学必和必拓奖学金

2016   宝钢奖学金

2017   中国科学院院长特别奖,第二批博士后创新人才支持计划

2018   中国科学院优秀博士学位论文,嘉定区青年英才

2019   上海市物理学会优秀博士后

2021   成果入选2020年度中国眼科学十大进展,上海微系统所新微之星

2022   青促会成员

2024   Nanoscale新锐科学家奖(Emerging Investigators)  

主要研究成果

发表高水平学术论文160余篇,引用6000余次,H指数36,i10指数85


Google Scholar:https://scholar.google.com/citations?user=-RpXRccAAAAJ&hl=zh-CN


 

  1. Bandgap engineering of two-dimensional C3N bilayers. Nature Electronics, 2021, 4 (7), 486-494. (共同第一作者,引用33次)

  2. Accelerated proton dissociation in an excited state induces superacidic microenvironments around graphene quantum dotsNature Communications, 2024, 15:6634. (共同第一作者,通讯作者)

  3. C3N—A 2D Crystalline, Hole‐Free, Tunable‐Narrow‐Bandgap Semiconductor with Ferromagnetic Properties. Advanced Materials, 2017, 29 (16), 1605625. (第一作者,封面论文,Web of Science高引论文,引用469次)

  4. Symmetry-Triggered Tunable Phosphorescence Lifetime of Graphene Quantum Dots in a Solid StateAdvanced Materials2024, 2313639. (共同第一作者,通讯作者)

  5. Imaging cellular aerobic glycolysis using carbon dots for early warning of tumorigenesis. Advanced Materials, 2021, 33 (1), 2005096. (共同第一作者,引用60次)

  6. Modified Oxygen Metabolism Toward "Sunlight-Friendly" Photodynamic TherapyAdvanced Functional Materials20242414817 (通讯作者)

  7. Precursor Symmetry Triggered Modulation of Fluorescence Quantum Yield in Graphene Quantum Dots. Advanced Functional Materials2024, 2401246.  (共同第一作者,通讯作者)

  8. Emancipating target‐functionalized carbon dots from autophagy vesicles for a novel visualized tumor therapy. Advanced Functional Materials, 2018, 28 (30), 1800881. (封面论文,引用132次)

  9. The Synergistic Effect on the Mimetic Optical Structure of Feline Eyes toward Household Health Monitoring of Acute and Chronic Diseases. ACS NANO, 2024, 18, 4944. (通讯作者).

  10. Tumor diagnosis using carbon-based quantum dots: Detection based on the hallmarks of cancerBioactive Materials, 202433, 174. (共同第一作者,通讯作者)

  11. Enhancing the magnetic relaxivity of MRI contrast agents via the localizedsuperacid microenvironment of graphene quantum dots. Biomaterials, 2020, 250, 120056. (通讯作者,引用51次)

  12. Fabrication of Carbon‐Based Quantum Dots via a “Bottom‐Up” Approach:Topology, Chirality, and Free Radical Processes in “Building Blocks”. Small, 2023, 2205957 (共同第一作者,通讯作者,引用13次)

  13. Ordered Element Distributed C3N Quantum Dots Manipulated Crystallization Kinetics for 2D CsPbI3 Solar Cells with Ultra‐High PerformanceSmall2022, 18 (15), 2108090. (共同第一作者,封面论文)

  14. Graphene Quantum Dots with Pyrrole N and Pyridine N: Superior Reactive Oxygen Species Generation Efficiency for Metal‐Free Sonodynamic Tumor TherapySmall2021, 17 (10), 2004867. (第一作者,封面论文,引用85次)

  15. Carbon‐based quantum dots with solid‐state photoluminescent: mechanism, implementation, and application. Small, 2020, 16 (48), 2004621. (通讯作者,封面论文,引用192次)

  16. Tunable Synaptic Behavior Realized in C3N Composite based MemristorNano Energy2019, 58, 293-303. (共同第一作者,引用127次)

  17. Large-scale fabrication of heavy doped carbon quantum dots with tunable photoluminescence and sensitive fluorescence detection. Journal of Materials Chemistry A, 2014, 2 (23), 8660-8667. (第一作者,引用440次)

  18. Selenium doped graphene quantum dots as an ultrasensitive redox fluorescent switch. Chemistry of Materials, 2015, 27 (6), 2004–2011. (第一作者,引用207次)

  19. Ultra‐High Quantum Yield of Graphene Quantum Dots: Aromatic‐Nitrogen Doping and Photoluminescence Mechanism. Particle & Particle Systems Characterization, 2015, 32 (4), 434-440. (共同第一作者,引用212次)


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