纳米绿色印刷图案化技术研究进展
|
摘要
微纳制造技术是从纳米材料制备到器件应用的核心技术。面向微纳器件制造和系统集成,发展不同于传统微纳加工技术的低成本、高精度、绿色环保的纳米结构制造技术,是未来新型纳米结构器件的重要发展方向。绿色印刷技术作为增材制造方式,能耗少、材料普适性高,可望对新型纳米结构器件制造技术产生变革性影响。本文简要介绍了国家重点研发计划"绿色印刷制造技术与纳米结构器件系统集成应用"项目及其研究进展。
Micro-nano manufacturing technology is one of key issues for development of nanomaterials and nano-devices. Traditional micro-nano processing technology is difficult to meet the needs of new materials, new structures and new features in printed and flexible electronics, thus the development of low-cost, high resolution, and environmentally-friendly process for nanostructure manufacturing and integration is of great signifance. As an additive manufacturing approach, green printing technology is expected to have a transformative impact on new nanostructure manufacturing due to low energy consumption and high resolution and universal material availability. This paper briefly introduces the advances of the project of "Green Printing Manufacturing Technology and Nanostructured Device System Integration Application" of the National Key R&D Program, as well as its latest developments.
Micro-nano manufacturing technology is one of key issues for development of nanomaterials and nano-devices. Traditional micro-nano processing technology is difficult to meet the needs of new materials, new structures and new features in printed and flexible electronics, thus the development of low-cost, high resolution, and environmentally-friendly process for nanostructure manufacturing and integration is of great signifance. As an additive manufacturing approach, green printing technology is expected to have a transformative impact on new nanostructure manufacturing due to low energy consumption and high resolution and universal material availability. This paper briefly introduces the advances of the project of "Green Printing Manufacturing Technology and Nanostructured Device System Integration Application" of the National Key R&D Program, as well as its latest developments.
引文
[1] 彭万波.微纳制造技术的发展现状与发展趋势[J].航空精密制造技术,2009,45 (02),32
[2] The changing landscape of disruptive technologies,Global technology innovation hubs[C].KPMG International 2016
[3] Hou J,Li M Z,Song Y L.Patterned colloidal photonic crystals[J].Angew Chem Int Ed,2018,57 (10):2544—2553
[4] Wu L,Dong Z C,Li F Y,et al.Emerging progress of inkjet technology in printing optical materials[J].Adv Opt Mater,2016,4 (12):1915—1932
[5] 宋延林.从活字印刷到印刷制造[J].印刷工业,2016,11 (10):34—35
[6] 宋延林.纳米科学与技术[M].科学出版社,2018,北京
[7] Kuang M X,Wang L B,Song Y L.Controllable printing droplets for high-resolution patterns[J].Adv Mater,2014,26 (40):6950—6958
[8] Muth J T,Dixon P G,Woish L,et al.Architected cellular ceramics with tailored stiffness via direct foam writing[J].P Natl Acad Sci USA,2017,114 (8):1832—1837
[9] Layani M,Gruchko M,Milo O,et al.Transparent conductive coatings by printing coffee ring arrays obtained at room temperature[J].ACS Nano,2009,3 (11):3537—3542
[10] Wang C,Murphy P F,Yao N,et al.Growth of straight silicon nanowires on amorphous substrates with uniform diameter,length,orientation,and location using nanopatterned host-mediated catalyst[J].Nano Lett,2011,11 (12):5247—5251
[11] Sargent Jr,John F.The Obama administration's proposal to establish a national network for manufacturing innovation,2012
[12] 白春礼.创造未来的科技发展新趋势[J].中国科学院院刊,2015,30 (4):431—434
[13] Richard D,Clanet C,Quere D.Surface phenomena—Contact time of a bouncing drop[J].Nature,2002,417 (6891):811—811
[14] Guo D,Zheng X,Wang X H,et al.Formation of multicomponent size-sorted assembly patterns by tunable templated dewetting[J].Angew Chem Int Ed,2018,57 (49):16126—16130
[15] Su M,Huang Z D,Li F Y,et al.Microfiber-knitted crossweave patterns for multiresolution physical kineses analysis electronics[J].Adv Mater Technol-Us,2018,3(8):1800107
[16] Qian X,Cai Z R,Su M,et al.Printable skin-driven mechanoluminescence devices via nanodoped matrix modification[J].Adv Mater,2018,30(25):1800291
[17] Hu X T,Huang Z Q,Zhou X,et al.Wearable large-scale perovskite solar-power source via nanocellular scaffold[J].Adv Mater,2017,29(42):1703236
[18] Li H Z,Fang W,Li Y A,et al.Spontaneous droplets gyrating via asymmetric self-splitting on heterogeneous surfaces[J].Nat Commun,2019,10,950
[19] Huang Z D,Yang Q,Su M,et al.A general approach for fluid patterning and application in fabricating microdevices[J].Adv Mater,2018,30 (31):1870225
[20] 胡笑添,宋延林.2018 年钙钛矿太阳能电池研发热点回眸[J].科技导报,2019,37 (1):144—150
[21] Gu Z K,Huang Z D,Li C,et al.A general printing approach for scalable growth of perovskite single-crystal films[J].Sci Adv,2018,4 (6):eaat2390
[22] Hu X T,Huang Z Q,Li F Y,et al.Nacre-inspired crystallization and elastic “brick-and-mortar” structure for a wearable perovskite solar module[J].Energy Environ Sci,2019,12 (3):979—987
[23] Li P W,Zhang Y Q,Liang C,et al.Phase pure 2D perovskite for high-performance 2D—3D heterostructured perovskite solar cells[J].Adv Mater,2018,30 (52):1805323
[24] Li Fengzhu,Zhang Chaoshen,Huang Jinhua,et al.Cation-exchange approach for fabrication of efficient methylammonium tin iodide perovskite solar cells[J].Angew Chem Int Ed 2019,DOI:10.1002/anie.201902418
[2] The changing landscape of disruptive technologies,Global technology innovation hubs[C].KPMG International 2016
[3] Hou J,Li M Z,Song Y L.Patterned colloidal photonic crystals[J].Angew Chem Int Ed,2018,57 (10):2544—2553
[4] Wu L,Dong Z C,Li F Y,et al.Emerging progress of inkjet technology in printing optical materials[J].Adv Opt Mater,2016,4 (12):1915—1932
[5] 宋延林.从活字印刷到印刷制造[J].印刷工业,2016,11 (10):34—35
[6] 宋延林.纳米科学与技术[M].科学出版社,2018,北京
[7] Kuang M X,Wang L B,Song Y L.Controllable printing droplets for high-resolution patterns[J].Adv Mater,2014,26 (40):6950—6958
[8] Muth J T,Dixon P G,Woish L,et al.Architected cellular ceramics with tailored stiffness via direct foam writing[J].P Natl Acad Sci USA,2017,114 (8):1832—1837
[9] Layani M,Gruchko M,Milo O,et al.Transparent conductive coatings by printing coffee ring arrays obtained at room temperature[J].ACS Nano,2009,3 (11):3537—3542
[10] Wang C,Murphy P F,Yao N,et al.Growth of straight silicon nanowires on amorphous substrates with uniform diameter,length,orientation,and location using nanopatterned host-mediated catalyst[J].Nano Lett,2011,11 (12):5247—5251
[11] Sargent Jr,John F.The Obama administration's proposal to establish a national network for manufacturing innovation,2012
[12] 白春礼.创造未来的科技发展新趋势[J].中国科学院院刊,2015,30 (4):431—434
[13] Richard D,Clanet C,Quere D.Surface phenomena—Contact time of a bouncing drop[J].Nature,2002,417 (6891):811—811
[14] Guo D,Zheng X,Wang X H,et al.Formation of multicomponent size-sorted assembly patterns by tunable templated dewetting[J].Angew Chem Int Ed,2018,57 (49):16126—16130
[15] Su M,Huang Z D,Li F Y,et al.Microfiber-knitted crossweave patterns for multiresolution physical kineses analysis electronics[J].Adv Mater Technol-Us,2018,3(8):1800107
[16] Qian X,Cai Z R,Su M,et al.Printable skin-driven mechanoluminescence devices via nanodoped matrix modification[J].Adv Mater,2018,30(25):1800291
[17] Hu X T,Huang Z Q,Zhou X,et al.Wearable large-scale perovskite solar-power source via nanocellular scaffold[J].Adv Mater,2017,29(42):1703236
[18] Li H Z,Fang W,Li Y A,et al.Spontaneous droplets gyrating via asymmetric self-splitting on heterogeneous surfaces[J].Nat Commun,2019,10,950
[19] Huang Z D,Yang Q,Su M,et al.A general approach for fluid patterning and application in fabricating microdevices[J].Adv Mater,2018,30 (31):1870225
[20] 胡笑添,宋延林.2018 年钙钛矿太阳能电池研发热点回眸[J].科技导报,2019,37 (1):144—150
[21] Gu Z K,Huang Z D,Li C,et al.A general printing approach for scalable growth of perovskite single-crystal films[J].Sci Adv,2018,4 (6):eaat2390
[22] Hu X T,Huang Z Q,Li F Y,et al.Nacre-inspired crystallization and elastic “brick-and-mortar” structure for a wearable perovskite solar module[J].Energy Environ Sci,2019,12 (3):979—987
[23] Li P W,Zhang Y Q,Liang C,et al.Phase pure 2D perovskite for high-performance 2D—3D heterostructured perovskite solar cells[J].Adv Mater,2018,30 (52):1805323
[24] Li Fengzhu,Zhang Chaoshen,Huang Jinhua,et al.Cation-exchange approach for fabrication of efficient methylammonium tin iodide perovskite solar cells[J].Angew Chem Int Ed 2019,DOI:10.1002/anie.201902418