主要从事柔性微纳电子、新型智能电子器件的研究工作，至今已主持国家自然科基金面上项目、青年项目、上海市浦江人才计划，上海市自然科学基金等国家、省部级重点等科研项目10余项，参与科技部重点研发计划3项（任务负责人），专著/教材2部，并在Nature Communications、npj Flexible Electronics、Adv. Funct. Mater.、Small、ACS Mater. Lett.、Nanophotonics等国际学术期刊上发表论文95篇，申请/授权发明专利18项（其中授权发明专利7项，第一发明人）。目前的研究兴趣：

• 柔性微纳光/电子器件、新型存储器件；
• 柔性神经形态器件与芯片、神经网络的硬件实现；
• 智能光电传感器与芯片；
• 柔性传感器

Frontiers in Chemistry期刊Reviewer Editor；

国家自然科学基金、多省市自然科学基金评议人；

Springer/Wiley/OSA等出版期刊的审稿人。

• 2022年信息学院院长奖
• 
  
• 2018年信息学院院长奖
• 
  
• 2016年----上海市浦江人才计划
• 2011年----浙江省钱江人才计划

• 2015.7至今             复旦大学信息学院微纳系统中心
• 2011.5 至2014.3     日本名古屋大学物质科学研究中心   博士后
• 2007.11至2010.4    日本名古屋大学化学系   博士后
• 2006.6至于2015.6  浙江工业大学应用物理系   讲师 副教授
• 2001.9 至2006.6     浙江大学物理系   博士
• 1997.9 至2001.7     浙江大学物理系   学士
•  

《柔性电子器件》，研究生课程

《Energy Efficient Embedded Electronics》，专业硕士课程

《电子系统导论》，本科生课程

Books:

1. 胡来归，詹义强，丛春晓，蔚安然，《柔性电子器件》，化学工业出版社，2025。

2. 詹义强，胡来归，蔚安然，《半导体光电子学》(ISBN: 978-7-03-074749-5)，45.7万字，科学出版社，2023年3月第一版。

Selected publications （以发表当年统计的一区论文，1st or corresponding author) :

1. Direct self-assembly of organic micro-arrays with programmable multi-color patterns. Science China Materials, 2025, 68:441-447 (Cover paper).

2. In-situ artificial retina with all-in-one reconfigurable photomemristor networks, npj Flexible Electronics, 2023, 7, 29.

3. Flexible Memory Arrays of Oriented Molecular Ferroelectric Single Crystals with Nearly Saturated Polarization, Small, 2022, 18, 2203882.

4. Molecular ferroelectric/semiconductor interfacial memristors for artificial synapses, npj Flexible Electronics, 2022, 6, 16.

5. Single-Crystalline Thin-Film Memory Arrays of Molecular Ferroelectrics with Ultralow Operation Voltages, ACS Materials Letters 2022, 4(4), 758-763.  

6. Dewetting-assisted Patterning of Organic Semiconductors for Micro-OLED Arrays with a Pixel Size of 1 μm, Small Methods, 2022, 2101509. 

7. Highly efficient 1D/3D ferroelectric perovskite solar cell, Advanced Functional Materials, 2021, 31, 2100215. 

8. Self-assembled non-volatile micro memory arrays of molecular ferroelectrics, Journal of Materials Chemistry C, 2020,8:16742-16748.  (Back cover)

9. Direct laser writing of vertical junctions in graphene oxide films for broad spectral position-sensitive detectors, Nanophotonics, 2018, 7(9): 1563-1570 . 

10. Space-Charge-Stabilized Ferroelectric Polarization in Self-Oriented Croconic Acid Films, Advanced Functional Materials, 2018,28:1705463. 

11. Organic semiconductor/water interfaces for photoelectrical viscosity sensing, Electrochemistry Communications, 2018, 95:18-22

12. Organic optoelectronic interfaces with anomalous transient photocurrent, Journal of Material Chemistry C, 2015, 3:22-5135. (Review paper)

13. Storage of an electric field for photocurrent generation in ferroelectric-functionalized organic devices. Nature Communications, 2014, 5:3279.

Other selected publications（1st or corresponding author）：

1. In-plane polarization triggered WS₂-ferroelectric heterostructured synaptic devices, ACS Applied Materials & Interfaces, 2025, 17(4):7027-7035.

2. Transferable Self-Assembled Quantum Dot Microarrays for High-Resolution Luminescent Applications, ACS Applied Nano Materials, 2025, 8(5): 2493–2499.

3. Single-Crystalline Nanowires of Molecular Ferroelectric Semiconductors for Optoelectronic Memory, Nanomaterials. 2024, 14(23), 1920.

4. In-plane ferroelectric-reconfigured interface towards dual-modal intelligent vision, Next Nanotechnology, 2024, 5:100052.

5. Enhanced dielectric/ferroelectric properties of P(VDF-TrFE) composite films with organic perovskite ferroelectrics, Appl. Phys. Express, 2023, 16 031008.

6. Wafer-Scale Diisopropylammonium Bromide Films for Low-Power Lateral Organic Ferroelectric Capacitors, Advanced Electronic Materials, 2021, 7, 2000778.

7. Liquid metal-induced memristor behavior in polymer insulators, Physica Status Solidi (RRL)-Rapid Research Letters, 2020, 14, 2000050. (Cover paper).

8. Laser-scribed highly responsive infrared detectors with semi-reduced graphene oxide, Applied Physics Express 11, 015101, 2018.

9. Effect of photoinduced charge displacement on organic optoelectronic conversion, Physical Review B, 84(20), 205329, 2011.

10. Optoelectronic Conversion by Polarization Current, Triggered by Space Charges at Organic-based Interfaces, Appl. Phys. Lett, 96, 243303 (2010).