«上一篇/Previous Article|本期目錄/Table of Contents|下一篇/Next Article»

j.issn.1674-3962.2014.03.02]
點擊復制

柔性大面積印刷電子新器件及其物聯網應用()

分享到：

中國材料進展[ISSN:1674-3962/CN:61-1473/TG]

卷:
期數:: 2014年第3期

頁碼:: 007-15

欄目:: 特約研究論文

出版日期:: 2014-03-30

文章信息/Info

Title:: Flexible Large Area Printed Electronics for the Internet-of-Things Applications

作者:: 鄭立榮、仇志軍、游胤濤、劉志英、楊庚、謝麗、鄒卓、馮藝、邵波濤、詹義強、梅永豐、劉冉; 復旦大學柔性微納電子與系統研究中心，復旦大學信息科學與工程學院，上海 200433

Author(s):: Lirong Zheng; Zhijun Qiu; Yintao You; Zhiying Liu; Geng Yang; Li Xie; Zhuo Zou; Yi Feng; Botao Shao; Yiqiang Zhan; Yongfeng Mei and Ran Liu; Center for Flexible Micro and Nano-Systems, School of Information Science and Engineering, Fudan University, Shanghai 200433, China)

關鍵詞:: 物聯網; 柔性電子; 大面積電子; 印刷電子; 系統與集成

DOI:: 10.7502/j.issn.1674-3962.2014.03.02

文獻標志碼:: A

摘要:: 作為一項新興技術，物聯網通過各種傳感器和智能標準通信接口，使得物理世界的“物”與信息網絡的“云”無縫鏈接，從而實現對物品對象的標識和智能管理。由于柔性電子特有的彎曲性和可延展性，使其在與物的結合中發揮出重要的作用，成為橋接“物”與“云”的關鍵技術。本文以作者自身的研究積累為基礎，全面綜述了國際上柔性大面積印刷電子新器件的最新研究進展，包括柔性薄膜晶體管、存儲器、各類傳感器等，以及柔性全金屬印制的射頻設別（RFID）技術和天線、智能包裝和可穿戴智慧醫療設備（Bio-Patch）等物聯網應用，對目前大面積柔性電子器件與系統在材料、器件以及系統集成等方面所面臨的諸多挑戰和困難展開了討論。

Abstract:: As an emerging technology, the internet of things (IoT) offers the potential to connect everyday’s objects in the real physical world to cyber space such that it forms a network of things for smart sensing, control and management. Due to its flexibility, bendability and deformability, flexible large area electronics (FLAE) have found a unique position for smart things, and it becomes a core-technology that bridges the real world things to cloud. In this article, we review advances and recent progress of FLAE, mainly based on the results developed in author’s group. This covers devices of printed thin film transistors (TFT), memories and flexible sensors etc., and integrated circuits and systems for IoT applications such as fully metallic printed RFID (radio frequency identification) tag and antenna, intelligent package and bio-patch for food safety and healthcare. Future challenges and difficulties for FLAE in materials preparation, devices fabrication and system integration etc., are also discussed.

參考文獻/References:

[1] Lirong Zheng（鄭立榮）, Hui Zhang（張暉）, Weili Han（韓偉力） et al., Technologies, Applications, and Governance in the Internet-of-Things, Internet of Things - Global Technological and Societal Trends: From Smart Environments and Spaces to Green ICT [M], River Publisher, ISBN 879232973X, 2011: 143-176

[2] International Telecommunication Union ITU. ITU internet Reports 2005: The Internet of Things[R]. Tunis: ITU, 2005.

[3] Li Zhiyu(李志宇).物聯網技術研究進展[J]. Computer Measurement & Control (計算機測量與控制)，2012, 20(6)：1445-1451.

[4] Lu Tao(盧濤)，You Anjun(尤安軍).美、歐、日、韓等國物聯網產業的發展戰略及其對我國的啟示[J]. Science & Technology Progress and Policy (科技進步與對策)，2012, 29(4)：47-51.

[5] Chen Liuqin(陳柳欽).物聯網：國內外發展動態及亟待解決的關鍵問題[J]. Decision-Making & Consultancy Newsletter (決策咨詢通訊)，2010,5：15-32.

[6] Zhan Y, Mei Y, Zheng L. Materials capability and device performance in flexible electronics for the Internet of Things[J]. Journal of Materials Chemistry C，2014 （待出版）.

[7] Cui Zheng(崔錚).Printed Electronics: Materials, Technologies and Applications(印刷電子學-材料、技術及其應用)[M].Beijing: High Education Press, 2012.

[8] MacDonald W A, Looney M K, MacKerron D, et al. Latest advances in substrates for flexible electronics [J]. Journal of the SID，2007,15(12)：1075-1083.

[9] Ji Lina(紀麗娜), Tang Xiaofeng(唐曉峰)，Yang Zhenguo(楊振國).噴墨印制PCB用新型納米銀導電油墨的研發現狀及趨勢[J]. Ink-Jet Printing Technology (噴墨打印技術)，2009,6：26-30.

[10] Sun Y, Rogers J A. Semiconductor Nanomaterials for Flexible Technologies: From Photovoltaics and Electronics to Sensors and Energy Storage[M]. Singapore: Elsevier Pte Ltd., 2010.

[11] Ortiz R P, Facchetti A, Marks T J. High-k Organic, Inorganic, and Hybrid Dielectrics for Low-Voltage Organic Field-Effect Transistors[J]. Chemical Reviews，2010,110(1)：205-239.

[12] Liu Z, Zhang Z -B, Chen Q, et al. Solution- processable nanotube/polymer composite for high-performance TFTs[J]. IEEE Electron Device Letters, 2011, 32(9),1299-1301.

[13] Liu Z, Gao X, Zhu Z, et al. Solution-processed logic Gates based on nanotube/polymer composite[J]. IEEE Transactions on Electron Devices, 2013,60(8) 2542-2547.

[14] Liu Z, Li H, Qiu Z,et al. Small-hysteresis thin-film transistors achieved by facile dip-coating of nanotube/polymer composite[J]. Advanced Materials, 2012, 24(27), 3633-3638.

[15] Qu M, Li H, Liu R, et al.Interaction of bipolaron with the H2O/O2 redox couple causes current hysteresis in organic thin-film transistors[J]. Nature Communications （已接受）

[16] Yang Y, Ouyang J, Ma LP, et al. Electrical Switching and Bistability in Organic/Polymeric Thin Films and Memory Devices[J]. Advanced Functional Materials, 2006, 16(8): 1001-1014.

[17] Scott J C, Bozano L D. Nonvolatile Memory Elements Based on Organic Materials[J]. Advanced Materials, 2007, 19(11): 1452-1463.

[18] Tang W, Shi H, Xu G,et al. Memory Effect and Negative Differential Resistance by Electrode- Induced Two-Dimensional Single-Electron Tunneling in Molecular and Organic Electronic Devices[J]. Advanced Materials, 2005, 17(19): 2307-2311.

[19] Wang M L, Zhou J, Gao X D, et al. Delayed-switch-on effect in metal-insulator-metal organic memories[J]. Appliled Physics Letters, 2007, 91: 143511.

[20] You Y T, Zeng Q, Yao Y, et al. Field-induced evolution of metallic nano-tips in indium tin oxide-tris- (8-hydroxyquinoline) aluminum-aluminum device[J]. Applied Physics Letters, 2012,100: 123304.

[21] Yao Y, You Y T, Si W, et al. Modeling the underlying mechanisms for organic memory devices: Tunneling, electron emission, and oxygen adsorbing[J]. Applied Physics Letters, 2012,100: 263307.

[22] Chen Y -F, Mei Y F, Kaltofen R,et al.Towards flexible magnetoelectronics: Buffer-enhanced and mechanically tunable GMR of Co/Cu multilayers on plastic substrates[J].Advanced Materials, 2008,20(17): 3224-3228.

[23] Mei Y F, Kiravittaya S, Harazim S, et al. Principles and applications of micro and nanoscale wrinkles[J]. Materials Science and Engineering: R: Reports, 2010 70(3-6): 209-224.

[24] Melzer M, Makarov D, Calvimontes A, et al. Stretchable magnetoelectronics[J].Nano Letters 2011, 11(6): 2522-2526.

[25] Melzer M, Karnaushenko D, Makarov D, et al. Elastic magnetic sensor with isotropic sensitivity for in-flow detection of magnetic objects[J].RSC Advances, 2012,2: 2284-2288.

[26] Karnaushenko D, Makarov D, Yan C L, et al. Printable Giant Magnetoresistive Devices[J]. Advanced Materials, 2012, 24(33): 4518–4522.

[27] Huang G S, Mei Y F. Thinning and shaping solid films into functional and integrative nanomembranes[J]. Advanced Materials, 2012, 24(19): 2517-2546.

[28] Shao B, Chen Q, Amin Y, et al. An ultra-low-cost RFID tag with 1.67 Gbps data rate by ink-jet printing on paper substrate [C].IEEE Asian Solid State Circuits Conference (A-SSCC),Beijing: Institute of Electrical and Electronics Engineers,2010: 1-4.

[29] Shao B, Chen Q, Liu R, et al. Design of fully printable and configurable chipless RFID tag on flexible substrate[J]. Microwave and Optical Technology Letters, 2012, 54(1): 226-230.

[30] Zheng L, Rodriguez S, Zhang L, et al. Design and implementation of a fully reconfigurable chipless RFID tag using Inkjet printing technology[C]. IEEE International Symposium on Circuits and Systems (ISCAS), Seattle, USA: Institute of Electrical and Electronics Engineers, 2008: 1524-1527.

[31] Shao B, Chen Q, Amin Y, et al. Process-dependence of inkjet printed folded dipole antenna for 2.45 GHz RFID tags[C]. 3rd IEEE European Conference on Antennas and Propagation (EuCAP),Berlin, Germany: Institute of Electrical and Electronics Engineers, 2009: 2336-2339.

[32] Shao B, Amin Y, Chen Q, et al. Directly-Printed Packaging Paper Based Chipless RFID Tag with Coplanar LC Resonator[J]. IEEE Antennas and Wireless Propagation Letters, 2013，12:1536-1225.

[33] Kortuem G. Smart Objects as Building Blocks for the Internet of the Things[J]. IEEE Internet Computing， 2010, 14(1)：44-51.

[34] Chen Z, Lu C. Humidity Sensors: A Review of Materials and Mechanisms[J]. Sensor Letters, 2005, 3（4）：274-295.

[35] Feng Y, Cabezas A L, Chen Q, et al. Flexible UHF Resistive Humidity Sensors Based on Carbon Nanotubes[J]. IEEE Sensors Journal 2012, 12(9)：2844-2850.

[36] Xie L, Feng Y, M?ntysalo M, et al. Integration of f-MWCNT Sensor and Printed Circuits on Paper Substrate[J]. IEEE Sensors Journal, 2013, 13(10)：3948-3956.

[37] Feng Y, Xie L, M?ntysalo M, et al. Electrical and Humidity-sensing Characterization of Inkjet -printed Multi-walled Carbon Nanotubes for Smart Packaging[C]. Proceedings of IEEE Sensors, USA: Institute of Electrical and Electronics Engineers (IEEE), 2013:1-4.

[38] M?ntysalo M, Xie L, Jonsson F, et al. System Integration of Smart Packages Using Printed Electronics[C]. Proceedings of Electronic Components and Technology Conference (ECTC), USA: Institute of Electrical and Electronics Engineers (IEEE), 2012: 997-1002.

[39] Feng Y, Chen Q, Zheng L-R. Design of A Printable Multi-functional Sensor for Remote Monitoring[C]. Proceedings of IEEE Sensors 2011, USA: Institute of Electrical and Electronics Engineers (IEEE), 2011:675-678.

[40] Yang G, Chen J, Xie L, et al. A Hybrid Low Power Bio-Patch for Body Surface Potential Measurement[J]. IEEE Journal of Biomedical and Health Informatics, 2013, 17(3):591-599.

[41] Yang G. Hybrid Integration of Active Bio-signal Cable with Intelligent Electrode: Steps toward Wearable Pervasive-Healthcare Applications [D]. Stockholm, Sweden: Royal Institute of Technology, 2013.

[42] Yang G, Chen J, Jonsson F, et al. A multi-parameter bio-electric ASIC sensor with integrated 2-wire data transmission protocol for wearable healthcare system[C]. Proceedings of Design, Automation & Test in Europe, Dresden, Germany: Institute of Electrical and Electronics Engineers (IEEE), 2012: 443-448.

[43] Yang G, Xie L, M?ntysalo M, et al. Bio-Patch Design and Implementation Based on a Low-Power System- on-Chip and Paper-based Inkjet Printing Technology[J]. IEEE Transactions on Information Technology in Biomedicine, 2012, 16(6): 1043-1050.

[44] Xie L, Yang G, M?ntysalo M, et al. A System-on-Chip and Paper-based Inkjet Printed Electrodes for a Hybrid Wearable Bio-Sensing System[C]. Proceedings of IEEE 34st Annual International Conference of the Engineering in Medicine and Biology Society, San Diego, USA: Institute of Electrical and Electronics Engineers (IEEE), 2012: 5026-5029.

[45] Xie L, Yang G, Xu L L, et al. Characterization of Dry Biopotential Electrodes[C]. Proceedings of IEEE 35st Annual International Conference of the Engineering in Medicine and Biology Society, Osaka, Japan: Institute of Electrical and Electronics Engineers (IEEE), 2013: 1478-1481.

[46] Xie L, Yang G, M?ntysalo M, et al. Heterogeneous Integration of Bio-Sensing System-on-Chip and Printed Electronics[J]. IEEE Journal on Emerging and Selected Topics in Circuits and Systems, 2012, 2(4): 672-682.

常用功能

工具/Tools

統計/Statistics

摘要瀏覽/Viewed9139
全文下載/Downloads5588
評論/Comments

更新日期/Last Update: 2014-02-27