1995年于中国科技大学获材料物理专业硕士学位,2003年于中国科技大学获理学博士学位。1992-1995年于安徽工程大学工作,2003-2007年于南京大学做博士后研究,2007至今在上海大学工作,2010年晋升研究员。目前的研究方向包括功能纳米材料及其在光电、能源和生物医学中的应用。作为负责人,先后主持了多项国家级项目,包括自然科学基金的面上项目和重大研究计划培育项目。在Nature Communications、Advanced Materials、ACS Nano等国际著名期刊上发表SCI收录论文80多篇,引用超过6000次,单篇最高引用1700余次。其中的5篇代表性研究论文作为主要报奖材料,于2015年获上海市自然科学一等奖《荧光石墨烯量子点的可控制备及生物医学应用研究》;2018年获国家自然科学二等奖《石墨烯微结构调控及其表界面效应研究》。 
1992-1995年 中国科技大学,材料物理,硕士
2000-2003年 中国科技大学,凝聚态物理,理学博士
2003-2007年 南京大学博士后 
1. 生物医用材料 2. 纳米活性药物 3. 光电材料及器件 4. 储能材料及器件 
[1] "Gram-scale Synthesis of Single-crystalline Graphene Quantum Dots with Superior Optical Properties",Nature Communications(2014),5,5357–5366.
[2] "Hydrothermal Route for Cutting Graphene Sheets into Blue Luminescent Graphene Quantum Dots", Advanced Materials (2010), 22, 734.
[3] "Room-temperature decay and light reactivation of high-Tc ferromagnetism in an oxide-diluted magnetic semiconductor" Journal of The American Society (2006) , 128 , 12608-12609.
[4] "Single-Particle Spectroscopic Measurements of Fluorescent Graphene Quantum Dot", ACS Nano (2013), 7,10654-10661.
[5] "Li Storage Properties of Disordered Graphene Nano sheets", Chemistry of Materials(2009), 21, 3136.
[6] "Observation of pH-, solvent-, spin-, and excitation-dependent blue photoluminescence from carbon nanoparticles",Chimerical. Communications(2010),46, 3681.
[7] "Nearly monodisperse graphene quantum dots fabricated by amine-assisted cutting and ultrafiltration",Nanoscale(2013), 5,12098-12103.
[8] "Blue fluorescent carbon thin films fabricated from dodecylamine-capped carbon nanoparticles",Journal of Materials Chemistry(2011), 21, 3565.
[9] "Cutting sp2 clusters in graphene sheets into colloidal graphene quantum dots with strong green fluorescence", Journal of Materials Chemistry(2012), 22, 3314.
[10] "Electrophoretic fabrication of highly robust, efficient, and benign heterojunction photoelectrocatalysts based on graphene-quantum-dot sensitized TiO2 nanotube arrays", Journal of Materials Chemistry A(2013), 1,3551.
[11] "C-axis preferentially oriented and fully activated TiO2 nanotube arrays for lithium ion batteries and supercapacitors",Journal of Materials Chemistry A(2014),2,11454-11464.
[12] "Efficient Separation of Electron-Hole Pairs in Graphene Quantum Dots by TiO2 Heterojunctions for Dye Degradation",ACS Sustainable Chemistry & Engineering(2015),3,2405–2413.
[13] "Facile synthesis of fluorescent graphene quantum dots from coffee grounds for bioimaging and sensing",Chemical Engineering Journal(2016),300,75–82.
[14] "Surfactant-assisted nanocrystal filling of TiO2 nanotube arrays for dye-sensitized solar cells with improved performance", Journal of Power Sources (2013),236,10-16.
[15] "Reduction Mechanism and Capacitive Properties of Highly Electrochemically Reduced TiO2 Nanotube Arrays" Electrochimica Acta (2015) , 161 , 40-47.
[16] "Graphene supported Sn-Sb@carbon core-shell particles as a superior anode for lithium ion batteries", Electrochemistry Communications (2010) , 12 , 1302-1306. [17] "Carbon dot-passivated black phosphorus nanosheet hybrids for synergistic cancer therapy in the NIR-II window ", ACS Applied Materials & Interfaces (2019), 11, 44949. [18] "Carbon dot/WS2 heterojunctions for NIR-II enhanced photothermal therapy of osteosarcoma and bone regeneration", Chemical Engineering Journal (2020), 383, 123102. [19] "Enriched graphitic N dopants of carbon dots as F cores mediate photothermal conversion in the NIR-II window with high efficiency", Carbon (2020), 162, 220-233. [20] "NIR-responsive carbon dots for efficient photothermal cancer therapy at low power densities", Carbon (2018), 134, 153-162. [21] "Carbon dot-sensitized MoS2 nanosheet heterojunctions as highly efficient NIR photothermal agents for complete tumor ablation at an ultralow laser exposure", Nanoscale (2019), 11, 7209. [22] "A solvent-engineered molecule fusion strategy for rational synthesis of carbon quantum dots with multicolor bandgap fluorescence", Carbon (2018), 130, 153-163. [23]."Scalable synthesis of organic-soluble carbon quantum dots: superior optical properties in solvents, solids, and LEDs", Nanoscale (2017), 9, 13195-13202. [24] "Room-temperature synthesis of graphene quantum dots via electron-beam irradiation and their application in cell imaging", Chemical Engineering Journal (2017), 309, 374-380. [25] "Amphiphilic Graphene Quantum Dots as Self‐Targeted Fluorescence Probes for Cell Nucleus Imaging", Advanced Biosystems (2018), 1700191. [26] "Nitrogen and oxygen co-doped graphene quantum dots with high capacitance performance for micro-supercapacitors", Carbon (2018), 139, 67-75. [27] " Graphene hydrogel-based counter electrode for high efficiency quantum dot-sensitized solar cells", J. Mater. Chem. A (2017),5,1614-1622. [28] "Ultrastable Amine, Sulfo Cofunctionalized Graphene Quantum Dots with High Two-Photon Fluorescence for Cellular Imaging", ACS Sustainable Chem. Eng.(2018), 6, 4711-4716. [29] "Hierarchical 3D All-Carbon Composite Structure Modified with N-Doped Graphene Quantum Dots for High-Performance Flexible Supercapacitors", Small (2018), DOI: 10.1002/smll.201801498. [30] "MoO3 nanosheet arrays as superior anode materials for Li- and Na-ion batteries", Nanoscale (2018), 10, 16040-16049. 
国家自然基金面上项目3项
国家自然科学基金重大研究计划1项
上海市教委创新重点项目1项
上海市自然基金2项 
2015年上海市自然科学一等奖
2015年上海大学王宽诚育才奖 2018年国家自然科学二等奖 |