反应喷墨打印技术及其在功能材料领域的研究进展

doi:10.16085/j.issn.1000-6613.2015.05.025

摘要/Abstract

摘要： 反应喷墨打印技术作为喷墨打印电子技术的重要分支,因其可以在沉积材料的同时可得到器件而受到人们的广泛关注.本文详细阐述了反应喷墨打印技术在功能材料制备领域,特别是在金属材料、高分子材料、无机材料等方面的研究进展,说明了反应喷墨打印用墨水是未来喷墨印刷电子研究的关键技术之一,简要介绍了反应喷墨打印技术与三维打印的联系,指出其在金属电路、有机发光二极管等印刷电子产业领域有广阔的应用前景.

关键词: 反应, 喷墨打印, 纳米材料, 化学反应, 烧结

Abstract: Reactive inkjet printing is an important branch of inkjet-printing,for its devices can be synthesized at the same time as their final device geometries are patterned. Recent progress in functional materials,such as metal,polymer,and inorganic materials with reactive inkjet printing technology,is reviewed. It indicates that the research on inks is one key to develop reactive inkjet printing technology. The relationship between reactive inkjet printing and three dimensional printing is also introduced. It can be expected that reactive inkjet printing technology has board application in printed electronics,such as metallic circuits and organic light emitting devices.

Key words: reaction, inkjet printing, nanomaterials, chemical reaction, sintering

中图分类号:

黄琦金, 沈文锋, 宋伟杰. 反应喷墨打印技术及其在功能材料领域的研究进展[J]. 化工进展, 2015, 34(05): 1332-1339.

HUANG Qijin, SHEN Wenfeng, SONG Weijie. Development of reactive inkjet printing and its application in functional materials[J]. Chemical Industry and Engineering Progree, 2015, 34(05): 1332-1339.

参考文献

[1] 吴美兰,周雪琴,李巍,等. 纳米金属喷墨导电墨水研究进展[J]. 化工进展,2012,31(8):1806-1810.

[2] Roy S. Fabrication of micro-and nano-structured materials using mask-less processes[J]. Journal of Physics D:Applied Physics,2007,40(22):R413-R426.

[3] Chang S C,Liu J,Bharathan J,et al. Multicolor organic light-emitting diodes processed by hybrid inkjet printing[J]. Advanced Materials,1999,11(9):734-737.

[4] Yang Y,Chang S C,Bharathan J,et al. Organic/polymeric electroluminescent devices processed by hybrid ink-jet printing[J]. Journal of Materials Science:Materials in Electronics,2000,11(2):89-96.

[5] Yim Y,Park J,Park B. Solution-processed flexible ITO-free organic light-emitting diodes using patterned polymeric anodes[J]. Journal of Display Technology,2010,6(7):252-256.

[6] Park K W,Kang S B,Jeong J A,et al. Liquid crystal devices incorporating transparent Zn,Sn co-doped In₂O₃ electrodes prepared by direct inkjet-printing of nanosized particles[J]. Journal of Physics D:Applied Physics,2013,46(14):145301.

[7] Zhuang J L,Ar D,Yu X J,et al. Patterned deposition of metal-organic frameworks onto plastic,paper,and textile substrates by inkjet printing of a precursor solution[J]. Advanced Materials,2013,25(33):4631-4635.

[8] Rida A,Yang L,Vyas R,et al. Conductive inkjet-printed antennas on flexible low-cost paper-based substrates for RFID and WSN applications[J]. Antennas and Propagation Magazine,IEEE,2009,51(3):13-23.

[9] Lakafosis V,Rida A,Vyas R,et al. Progress towards the first wireless sensor networks consisting of inkjet-printed,paper-based RFID-enabled sensor tags[J]. Proceedings of the IEEE,2010,98(9):1601-1609.

[10] Lim Y Y,Goh Y M,Liu C. Surface treatments for inkjet printing onto a PTFE-based substrate for high frequency applications[J]. Industrial & Engineering Chemistry Research,2013,52(33):11564-11574.

[11] Cappi B,Özkol E,Ebert J,et al. Direct inkjet printing of Si₃N₄:Characterization of ink,green bodies and microstructure[J]. Journal of the European Ceramic Society,2008,28(13):2625-2628.

[12] Jeong J A,Kim J,Kim H K. Ag grid/ITO hybrid transparent electrodes prepared by inkjet printing[J]. Solar Energy Materials and Solar Cells,2011,95(7):1974-1978.

[13] Wang W,Su Y W,Chang C H. Inkjet printed chalcopyrite CuIn_xGa_1-xSe₂ thin film solar cells[J]. Solar Energy Materials and Solar Cells,2011,95 (9):2616-2620.

[14] Pi X,Zhang L,Yang D. Enhancing the efficiency of multicrystalline silicon solar cells by the inkjet printing of silicon-quantum-dot ink[J]. The Journal of Physical Chemistry C,2012,116(40):21240-21243.

[15] Smith P J,Morrin A. Reactive inkjet printing[J]. Journal of Materials Chemistry,2012,22(22):10965-10970.

[16] 高明,吴潇,石磊,等. 喷墨打印技术在材料科学中的应用[J]. 材料导报,2011(1):84-88.

[17] Le H P. Progress and trends in ink-jet printing technology[J]. Journal of Imaging Science and Technology,1998,42(1):49-62.

[18] Zhang Q,Zheng Y,Liu J. Direct writing of electronics based on alloy and metal (DREAM) ink:A newly emerging area and its impact on energy,environment and health sciences[J]. Frontiers in Energy,2012,6 (4):311-340.

[19] Li D,Sutton D,Burgess A,et al. Conductive copper and nickel lines via reactive inkjet printing[J]. Journal of Materials Chemistry,2009,19 (22):3719-3724.

[20] Magdassi S,Grouchko M,Berezin O,et al. Triggering the sintering of silver nanoparticles at room temperature[J]. ACS Nano,2010,4(4):1943-1948.

[21] Kao Z K,Hung Y H,Liao Y C. Formation of conductive silver films via inkjet reaction system[J]. Journal of Materials Chemistry,2011,21 (46):18799-18803.

[22] Layani M,Grouchko M,Shemesh S,et al. Conductive patterns on plastic substrates by sequential inkjet printing of silver nanoparticles and electrolyte sintering solutions[J]. Journal of Materials Chemistry,2012,22 (29):14349-14352.

[23] Chiolerio A,Virga A,Pandolfi P,et al. Direct patterning of silver particles on porous silicon by inkjet printing of a silver salt via in-situ reduction[J]. Nanoscale Research Letters,2012,7(1):1-7.

[24] Kim K,Ahn S I,Choi K C. Direct fabrication of copper patterns by reactive inkjet printing[J]. Current Applied Physics,2013,13(9):1870-1873.

[25] Abulikemu M,Da'as E H,Haverinen H,et al. In situ synthesis of self-assembled gold nanoparticles on glass or silicon substrates through reactive inkjet printing[J]. Angewandte Chemie,2014,126(2):430-433.

[26] Petukhov D I,Kirikova M N,Bessonov A A,et al. Nickel and copper conductive patterns fabricated by reactive inkjet printing combined with electroless plating[J]. Materials Letters,2014,132:302-306.

[27] Huang Q,Shen W,Xu Q,et al. Room-temperature sintering of conductive Ag films on paper[J]. Materials Letters,2014,123:124-127.

[28] Wünscher S,Abbel R,Perelaer J,et al. Progress of alternative sintering approaches of inkjet-printed metal inks and their application for manufacturing of flexible electronics[J]. Journal of Materials Chemistry C,2014,2,10232-10261

[29] Yoshioka Y,Jabbour G E. Inkjet printing of oxidants for patterning of nanometer-thick conducting polymer electrodes[J]. Advanced Materials,2006,18(10):1307-1312.

[30] Kröber P,Delaney J T,Perelaer J,et al. Reactive inkjet printing of polyurethanes[J]. Journal of Materials Chemistry,2009,19 (29):5234-5238.

[31] Ahn S I,Kim W K,Ryu S H,et al. OLED with a controlled molecular weight of the PVK [poly(9-vinylcarbazole)] formed by a reactive ink-jet process[J]. Organic Electronics,2012,13(6):980-984.

[32] Janoschka T,Teichler A,Häupler B,et al. Reactive inkjet printing of cathodes for organic radical batteries[J]. Advanced Energy Materials,2013,3 (8):1025-1028.

[33] Lennon A J,Utama R Y,Lenio M A T,et al. Forming openings to semiconductor layers of silicon solar cells by inkjet printing[J]. Solar Energy Materials and Solar Cells,2008,92 (11):1410-1415.

[34] Lennon A J,Ho-Baillie A W Y,Wenham S R. Direct patterned etching of silicon dioxide and silicon nitride dielectric layers by inkjet printing[J]. Solar Energy Materials and Solar Cells,2009,93 (10):1865-1874.

[35] Cha H,Ahn S Ⅱ,Choi K C. An inkjet printing method:Drop and synthesis (DAS). Application to the synthesis of ZnS:Mn nano-phosphor with a pattern[J]. Current Applied Physics,2010,10 (4):E109-E112.

[36] Kim K,Ahn S I,Choi K C. Simultaneous synthesis and patterning of graphene electrodes by reactive inkjet printing[J]. Carbon,2014,66:172-177.

[37] 汪焰恩,潘飞龙,杨明明. 基于三维打印骨支架制备及其性能[J]. 化工进展,2013,32(12):2940-2945.

[38] Wang T,Patel R,Derby B. Manufacture of 3-dimensional objects by reactive inkjet printing[J]. Soft Matter,2008,4 (12):2513-2518.

[39] Andres C M,Kotov N A. Inkjet deposition of layer-by-layer assembled films[J]. Journal of the American Chemical Society,2010,132(41):14496-14502.

[40] Layani M,Cooperstein I,Magdassi S. UV crosslinkable emulsions with silver nanoparticles for inkjet printing of conductive 3D structures[J]. Journal of Materials Chemistry C,2013,1(19):3244-3249.