Journal articles: 'Reactive Inkjet Printing'

1

Smith, Patrick J., and Aoife Morrin. "Reactive inkjet printing." Journal of Materials Chemistry 22, no. 22 (2012): 10965. http://dx.doi.org/10.1039/c2jm30649b.

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Kröber, Peter, Joseph T. Delaney, Jolke Perelaer, and Ulrich S. Schubert. "Reactive inkjet printing of polyurethanes." Journal of Materials Chemistry 19, no. 29 (2009): 5234. http://dx.doi.org/10.1039/b823135d.

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Teo, Mei Ying, Logan Stuart, Kean C. Aw, and Jonathan Stringer. "Micro-Reactive Inkjet Printing of Polyaniline." NIP & Digital Fabrication Conference 2018, no. 1 (September 23, 2018): 16–20. http://dx.doi.org/10.2352/issn.2169-4451.2018.34.16.

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4

Sturgess, Craig, Christopher J. Tuck, Ian A. Ashcroft, and Ricky D. Wildman. "3D reactive inkjet printing of polydimethylsiloxane." Journal of Materials Chemistry C 5, no. 37 (2017): 9733–43. http://dx.doi.org/10.1039/c7tc02412f.

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In this work a two-part polydimethylsiloxane (PDMS) ink has been developed, printed individually, and cured. The successful printing of PDMS has been used to fabricate complex 3D geometry for the first time using FRIJP.

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Gregory, David A., Yu Zhang, Patrick J. Smith, Xiubo Zhao, and Stephen J. Ebbens. "Reactive Inkjet Printing: Reactive Inkjet Printing of Biocompatible Enzyme Powered Silk Micro-Rockets (Small 30/2016)." Small 12, no. 30 (August 2016): 4022. http://dx.doi.org/10.1002/smll.201670148.

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Teo, Mei Ying, Logan Stuart, Harish Devaraj, Cody Yang Liu, Kean C. Aw, and Jonathan Stringer. "The in situ synthesis of conductive polyaniline patterns using micro-reactive inkjet printing." Journal of Materials Chemistry C 7, no. 8 (2019): 2219–24. http://dx.doi.org/10.1039/c8tc06485g.

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Teo, Mei Ying, Logan Stuart, Kean C. Aw, and Jonathan Stringer. "Micro-reactive Inkjet Printing of Three-Dimensional Hydrogel Structures." MRS Advances 3, no. 28 (December 28, 2017): 1575–81. http://dx.doi.org/10.1557/adv.2017.628.

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AbstractInkjet printing, of the researched techniques for printing of hydrogels, gives perhaps the best potential control over the shape and composition of the final hydrogel. It is, however, fundamentally limited by the low viscosity of the printed ink, which means that crosslinking of the hydrogel must take place after printing. This can be particularly problematic for hydrogels as the slow diffusion of the crosslinking species through the gel results in very slow vertical printing speeds, leading to dehydration of the gel and (if simultaneously deposited) cell death. Previous attempts to overcome this limitation have involved the sequential printing of alternating layers to reduce the diffusion distance of reactive species. In this work we demonstrate an alternative approach where the crosslinker and gelator are printed so that they collide with each other before impinging upon the substrate, thereby facilitating hydrogel synthesis and patterning in a single step. Using a model system based upon sodium alginate and calcium chloride a series of 3D structures are demonstrated, with vertical printing speeds significantly faster than previous work. The droplet collision is shown to increase advective mixing before impact, reducing the time taken for gelation to occur, and improving definition of printed patterns. With the facile addition of more printing inks, this approach also enables spatially varied composition of the hydrogel, and work towards this will be discussed.

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Al-Ghazzawi, Fatimah, Luke Conte, Klaudia K. Wagner, Christopher Richardson, and Pawel Wagner. "Rapid spatially-resolved post-synthetic patterning of metal–organic framework films." Chemical Communications 57, no. 38 (2021): 4706–9. http://dx.doi.org/10.1039/d1cc01349a.

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Shahariar, Hasan, Inhwan Kim, Henry Soewardiman, and Jesse S. Jur. "Inkjet Printing of Reactive Silver Ink on Textiles." ACS Applied Materials & Interfaces 11, no. 6 (January 15, 2019): 6208–16. http://dx.doi.org/10.1021/acsami.8b18231.

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Chu, Runshan, Yue Zhang, Tieling Xing, and Guoqing Chen. "The stability of disperse red/reactive-red dye inks." RSC Advances 10, no. 70 (2020): 42633–43. http://dx.doi.org/10.1039/d0ra07333d.

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Schuster, Fabian, Fabrice Ngako Ngamgoue, Tobias Goetz, Thomas Hirth, Achim Weber, and Monika Bach. "Investigations of a catalyst system regarding the foamability of polyurethanes for reactive inkjet printing." Journal of Materials Chemistry C 5, no. 27 (2017): 6738–44. http://dx.doi.org/10.1039/c7tc01784g.

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12

Yang, Hong Lin, Wei Xiang, and Guang Jie Chen. "Study on Preparation and Property of Regenerated Liquid Reactive Dyes Regenerated Magenta." Advanced Materials Research 941-944 (June 2014): 445–49. http://dx.doi.org/10.4028/www.scientific.net/amr.941-944.445.

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The regenerated liquid reactive dye Regenerated Magenta had been prepared with the waste reactive ink of Jettex R Magenta in the process of digital inkjet printing. The effects of quality percentage of waste ink, cosolvent, pH regulator on the stabilities of Regenerated Magenta had been investigated. The results show that the Regenerated Magenta ink prepared with waste ink 26%, N-methyl-2-pyrrolidone 4%, THAM 1%, ethanediol 3% and deionized water 67% has good performances such as particle sizes, surface tension, viscosity and conductivity. The characteristics of Regenerated Magenta ink meet the demands of the ink for digital inkjet printing.

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Zhu, Qian, Jian Da Cao, Wang Wei, Jing Cheng Zhong, Jia Yao, Ying Ye, and Xin Xin Yang. "Effects of the Cotton Fabric Pretreatment on Application Properties of Digital Inkjet Printing with Reactive Dyes." Advanced Materials Research 331 (September 2011): 398–401. http://dx.doi.org/10.4028/www.scientific.net/amr.331.398.

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Cotton fabric was directly inkjet printed with reactive dye ink, the ink would appear on the permeability of the fabric, the depth of color yield is low, light fastness is poor. Pretreatment agents with different mass fractions had been used to do the pretreatment of the cotton fabric before ink-jet printing, the results showed that: when the concentration of alginate ester or seaweed was between 1.0% -1.5%, the fabrics had the high color yield and the fixation color rate of the dye was the highest. When the amount of NaHCO3 was 3%, the inkjet printing effect of cotton fabrics was the best; color fastness of colors was all good. After Inkjet printing, the best effect can be achieved by steaming the cotton fabrics under the 100 °Csaturated water vapor for 25min: the colors of black, red and yellow of the K / S value were of the maximum, color fastness was fine.

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14

Jeon, Seongho, Jong Pil Lee, and Jong-Man Kim. "In situ synthesis of stimulus-responsive luminescent organic materials using a reactive inkjet printing approach." Journal of Materials Chemistry C 3, no. 12 (2015): 2732–36. http://dx.doi.org/10.1039/c5tc00334b.

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15

Wang, Yuehui, Dexi Du, Zhimin Zhou, Hui Xie, Jingze Li, and Yuzhen Zhao. "Reactive Conductive Ink Capable of In Situ and Rapid Synthesis of Conductive Patterns Suitable for Inkjet Printing." Molecules 24, no. 19 (September 30, 2019): 3548. http://dx.doi.org/10.3390/molecules24193548.

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We report a fabrication method of the conductive pattern based on in situ reactive silver precursor inks by inkjet printing. The reactive silver precursor inks were prepared with ethylene glycol and deionized water mixture as the solvent, and silver nitrate as silver source. Sodium borohydride solution as the reducing agent was first coated on photographic paper by screen printing process, and then dried at 50 °C for 4 h. Furthermore, the reactive silver precursor inks were printed on a photographic paper coated with sodium borohydride using inkjet printing to form silver nanoparticles in situ due to redox reaction, and thus a conductive pattern was obtained. The effects of the reactive silver precursor ink concentration and printing layer number and treatment temperature on the electrical properties and microstructures of the printed patterns were investigated systematically. The size range of in situ-formed silver nanoparticles was 50–90 nm. When the reactive silver precursor ink concentration was 0.13 g/mL, the five-layer printed pattern exhibited a sheet resistance of 4.6 Ω/γ after drying at room temperature for 2 h; furthermore, the sheet resistance of the printed pattern decreased to 1.4 Ω/γ after drying at 130 °C for 2 h. In addition, the display function circuit was printed on the photographic paper to realize the display of the numbers 0–99. It provides new research ideas for the development of environmentally friendly and low-cost flexible paper-based circuits.

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16

Li, Dapeng, David Sutton, Andrew Burgess, Derek Graham, and Paul D. Calvert. "Conductive copper and nickel lines via reactive inkjet printing." Journal of Materials Chemistry 19, no. 22 (2009): 3719. http://dx.doi.org/10.1039/b820459d.

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17

Wang, Tianming, Ranjana Patel, and Brian Derby. "Manufacture of 3-dimensional objects by reactive inkjet printing." Soft Matter 4, no. 12 (2008): 2513. http://dx.doi.org/10.1039/b807758d.

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18

Bao, Bin, Mingzhu Li, Yuan Li, Jieke Jiang, Zhenkun Gu, Xingye Zhang, Lei Jiang, and Yanlin Song. "Patterning Fluorescent Quantum Dot Nanocomposites by Reactive Inkjet Printing." Small 11, no. 14 (January 12, 2015): 1649–54. http://dx.doi.org/10.1002/smll.201403005.

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19

Deravi, Leila F., Jan L. Sumerel, Sarah L. Sewell, and David W. Wright. "Piezoelectric Inkjet Printing of Biomimetic Inks for Reactive Surfaces." Small 4, no. 12 (December 2008): 2127–30. http://dx.doi.org/10.1002/smll.200800536.

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20

Janoschka, Tobias, Anke Teichler, Bernhard Häupler, Thomas Jähnert, Martin D. Hager, and Ulrich S. Schubert. "Reactive Inkjet Printing of Cathodes for Organic Radical Batteries." Advanced Energy Materials 3, no. 8 (April 23, 2013): 1025–28. http://dx.doi.org/10.1002/aenm.201300036.

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21

Rider, Patrick, Yu Zhang, Christopher Tse, Yi Zhang, Dharana Jayawardane, Jonathan Stringer, Jill Callaghan, et al. "Biocompatible silk fibroin scaffold prepared by reactive inkjet printing." Journal of Materials Science 51, no. 18 (June 16, 2016): 8625–30. http://dx.doi.org/10.1007/s10853-016-0121-3.

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22

Kim, Kukjoo, Sung Il Ahn, and Kyung Cheol Choi. "Direct fabrication of copper patterns by reactive inkjet printing." Current Applied Physics 13, no. 9 (November 2013): 1870–73. http://dx.doi.org/10.1016/j.cap.2013.07.021.

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23

Stempien, Z., E. Rybicki, T. Rybicki, and M. Kozanecki. "Reactive inkjet printing of PEDOT electroconductive layers on textile surfaces." Synthetic Metals 217 (July 2016): 276–87. http://dx.doi.org/10.1016/j.synthmet.2016.04.014.

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24

Gregory, David A., Yu Zhang, Patrick J. Smith, Xiubo Zhao, and Stephen J. Ebbens. "Reactive Inkjet Printing of Biocompatible Enzyme Powered Silk Micro-Rockets." Small 12, no. 30 (June 27, 2016): 4048–55. http://dx.doi.org/10.1002/smll.201600921.

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25

Kheawhom, Soorathep, and Kamolrat Foithong. "Comparison of Reactive Inkjet Printing and Reactive Sintering to Fabricate Metal Conductive Patterns." Japanese Journal of Applied Physics 52, no. 5S1 (May 1, 2013): 05DB14. http://dx.doi.org/10.7567/jjap.52.05db14.

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26

Lefky, Christopher, Galen Arnold, and Owen Hildreth. "High-Resolution Electrohydrodynamic Printing of Silver Reactive Inks." MRS Advances 1, no. 34 (2016): 2409–14. http://dx.doi.org/10.1557/adv.2016.482.

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ABSTRACTNano-inkjet printing using an Electrohydrodynamic's (EHD) pulsed cone-jet approach has the potential to bring affordable additive manufacturing to the micro and nanoscale. Ink technology is a major limitation of current EHD techniques. Specifically, most EHD printing processes print either nanoparticles or polymers. The materials are structurally weak and often have poor electrical or mechanical properties. For example, printing nanoparticles effectively creates a cluster of nanoparticles that must be sintered to create a continuous material. To address these issues, we have been adapting reactive inks to work with an EHD pulsed cone-jet. Specifically, we demonstrate that silver micron-scale structures can be printed using an EHD pulsed cone-jet regime. These inks produce solid structures without sintering steps and with good electrical properties.1,2 This work shows that reactive ink chemistries can be combined with EHD printing to produce fine-resolution features consisting of solid metal without an annealing step.

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27

Mamidanna, Avinash, Zeming Song, Cheng Lv, Christopher S. Lefky, Hanqing Jiang, and Owen Hildreth. "Inkjet Printed Spiral Stretchable Electronics Using Reactive Ink Chemistries." MRS Advances 1, no. 51 (2016): 3465–70. http://dx.doi.org/10.1557/adv.2016.442.

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ABSTRACTFabrication methods and performance characteristics of spiral stretchable interconnects fabricated using drop-on-demand printing of silver reactive inks are discussed. This work details ink optimization, device fabrication, and device characterization while demonstrating the potential applications for reactive inks and new design strategies in stretchable electronics. Devices were printed with an ethanol stabilized silver diamine reactive ink and cycled to 160 % over 100 cycles with less than 10% increase in electrical resistance. Maximum deformation before failure was measured at 180% elongation. A novel method for fabrication of a stretchable electronics device has been studied and verified.

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28

Zhang, Liyuan, Kuanjun Fang, and Hua Zhou. "Interaction of Reactive-Dye Chromophores and DEG on Ink-Jet Printing Performance." Molecules 25, no. 11 (May 28, 2020): 2507. http://dx.doi.org/10.3390/molecules25112507.

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Digital inkjet printing has been widely used in textile industry. The quality of dye solutions and ink-jet droplets limits the ink-jet printing performance, which is very important for obtaining high-quality ink-jet printing images on fabrics. In this paper, we introduced diethylene glycol (DEG) into the dye solutions of Reactive Blue 49 and Reactive Orange 13, respectively, and investigated the interaction between dye chromophores and DEG molecules. Results indicated that the dye chromophores were featured in the aggregation. Adding DEG into the dye solution could effectively disaggregate clusters of reactive dyes, and eliminate satellite ink droplets, thus improving the resolution of the ink-jet printing image on fabrics. Under the same DEG concentration, the disaggregation effect was more obvious in Orange 13 than in Reactive Blue 49. Higher DEG concentration was required in Reactive Orange 13 solution for creating complete and stable ink drops. The surface tension and viscosity of the dye solutions were measured, and printing performance on cotton fabrics was evaluated. The interaction mechanism between dye chromophores and DEG molecules was also investigated. Results from this work are useful for high-quality ink-jet printing images on fabrics.

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Kim, Kukjoo, Sung Il Ahn, and Kyung Cheol Choi. "Simultaneous synthesis and patterning of graphene electrodes by reactive inkjet printing." Carbon 66 (January 2014): 172–77. http://dx.doi.org/10.1016/j.carbon.2013.08.055.

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30

Jeon, Seongho, Sumin Park, Jihye Nam, Youngjong Kang, and Jong-Man Kim. "Creating Patterned Conjugated Polymer Images Using Water-Compatible Reactive Inkjet Printing." ACS Applied Materials & Interfaces 8, no. 3 (January 14, 2016): 1813–18. http://dx.doi.org/10.1021/acsami.5b09705.

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31

Murray, Allison K., Tugba Isik, Volkan Ortalan, I. Emre Gunduz, Steven F. Son, George T. C. Chiu, and Jeffrey F. Rhoads. "Two-component additive manufacturing of nanothermite structures via reactive inkjet printing." Journal of Applied Physics 122, no. 18 (November 14, 2017): 184901. http://dx.doi.org/10.1063/1.4999800.

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32

Kastner, Julia, Thomas Faury, Helene M. Außerhuber, Thomas Obermüller, Hans Leichtfried, Michael J. Haslinger, Eva Liftinger, et al. "Silver-based reactive ink for inkjet-printing of conductive lines on textiles." Microelectronic Engineering 176 (May 2017): 84–88. http://dx.doi.org/10.1016/j.mee.2017.02.004.

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33

Zhang, Yu, David A. Gregory, Yi Zhang, Patrick J. Smith, Stephen J. Ebbens, and Xiubo Zhao. "Reactive Inkjet Printing of Functional Silk Stirrers for Enhanced Mixing and Sensing." Small 15, no. 1 (December 5, 2018): 1804213. http://dx.doi.org/10.1002/smll.201804213.

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34

Song, Yawei, Kuanjun Fang, Mohd Nadeem Bukhari, Yanfei Ren, Kun Zhang, and Zhiyuan Tang. "Green and Efficient Inkjet Printing of Cotton Fabrics Using Reactive Dye@Copolymer Nanospheres." ACS Applied Materials & Interfaces 12, no. 40 (September 11, 2020): 45281–95. http://dx.doi.org/10.1021/acsami.0c12899.

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35

Hou, Xueni, Guoqiang Chen, Tieling Xing, and Zhenzhen Wei. "Reactive ink formulated with various alcohols for improved properties and printing quality onto cotton fabrics." Journal of Engineered Fibers and Fabrics 14 (January 2019): 155892501984924. http://dx.doi.org/10.1177/1558925019849242.

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The formulated inks with desirable physical and chemical properties are of significance for inkjet printing, to endow the fabric with expected image quality and color performance. Here, various kinds of water-soluble alcohols are preferably selected and introduced into reactive ink with an objective to improve the physical and rheological properties of ink and print quality of cotton fabric. In this study, the effects of alcohols with different boiling points on the rheology properties, drying behavior, and storage stability of ink were extensively investigated. Moreover, the print image performance, including color strength, fixation rate, ink penetration, and outline sharpness, was evaluated. The results indicated that the inks containing glycerol, diethylene glycol, and triethylene glycol possessed slower evaporation rates, but the storage stability and the dye fixation value of these inks would be decreased. The addition of alcohols into the reactive dye ink could increase the ink penetration and reduce the line image quality. The ink containing 1,2-propanediol with a medium boiling point can effectively satisfy various properties of the reactive ink and improve the fixing rate and printing quality onto cotton fabrics. Furthermore, these findings shed light on the propriate selection of reactive ink with alcohols and provide valuable information for technicians and researchers working in the printing industry.

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36

Wang, Chenglong, Lili Wang, Yi Huang, Yiding Meng, Guangdong Sun, Qinguo Fan, and Jianzhong Shao. "Fabrication of reactive pigment composite particles for blue-light curable inkjet printing of textiles." RSC Advances 7, no. 57 (2017): 36175–84. http://dx.doi.org/10.1039/c7ra04576j.

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The Reactive Phthalocyanine Blue (RPB) was fabricated by two-step method, and then used to prepare blue light curable inks. After injection, RPB can participate in the copolymerization of oligomers and monomers under blue-LED irradiation.

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37

Rider, Patrick, Ian Brook, Patrick Smith, and Cheryl Miller. "Reactive Inkjet Printing of Regenerated Silk Fibroin Films for Use as Dental Barrier Membranes." Micromachines 9, no. 2 (January 27, 2018): 46. http://dx.doi.org/10.3390/mi9020046.

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38

Gadea, C., D. Marani, and V. Esposito. "Nucleophilic stabilization of water-based reactive ink for titania-based thin film inkjet printing." Journal of Physics and Chemistry of Solids 101 (February 2017): 10–17. http://dx.doi.org/10.1016/j.jpcs.2016.10.004.

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39

Petukhov, Dmitrii I., Marina N. Kirikova, Alexander A. Bessonov, and Marc J. A. Bailey. "Nickel and copper conductive patterns fabricated by reactive inkjet printing combined with electroless plating." Materials Letters 132 (October 2014): 302–6. http://dx.doi.org/10.1016/j.matlet.2014.06.109.

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40

Bao, Bin, Mingzhu Li, Yuan Li, Jieke Jiang, Zhenkun Gu, Xingye Zhang, Lei Jiang, and Yanlin Song. "Quantum Dots: Patterning Fluorescent Quantum Dot Nanocomposites by Reactive Inkjet Printing (Small 14/2015)." Small 11, no. 14 (April 2015): 1614. http://dx.doi.org/10.1002/smll.201570079.

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41

Schuster, Fabian, Thomas Hirth, and Achim Weber. "Reactive inkjet printing of polyethylene glycol and isocyanate based inks to create porous polyurethane structures." Journal of Applied Polymer Science 136, no. 3 (August 2, 2018): 46977. http://dx.doi.org/10.1002/app.46977.

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42

Chen, Jin-Ju, Guo-Qiang Lin, Yan Wang, Enrico Sowade, Reinhard R. Baumann, and Zhe-Sheng Feng. "Fabrication of conductive copper patterns using reactive inkjet printing followed by two-step electroless plating." Applied Surface Science 396 (February 2017): 202–7. http://dx.doi.org/10.1016/j.apsusc.2016.09.152.

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43

Wang, Lei, Kelu Yan, Chunyan Hu, and Bolin Ji. "Preparation and investigation of a stable hybrid inkjet printing ink of reactive dye and CHPTAC." Dyes and Pigments 181 (October 2020): 108584. http://dx.doi.org/10.1016/j.dyepig.2020.108584.

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44

Liu, Hailu, Dong Xie, Huayan Shen, Fayong Li, and Junjia Chen. "Functional Micro–Nano Structure with Variable Colour: Applications for Anti-Counterfeiting." Advances in Polymer Technology 2019 (December 8, 2019): 1–26. http://dx.doi.org/10.1155/2019/6519018.

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Colour patterns based on micro-nano structure have attracted enormous research interests due to unique optical switches and smart surface applications in photonic crystal, superhydrophobic surface modification, controlled adhesion, inkjet printing, biological detection, supramolecular self-assembly, anti-counterfeiting, optical device and other fields. In traditional methods, many patterns of micro-nano structure are derived from changes of refractive index or lattice parameters. Generally, the refractive index and lattice parameters of photonic crystals are processed by common solvents, salts or reactive monomers under specific electric, magnetic and stress conditions. This review focuses on the recent developments in the fabrication of micro-nano structures for patterns including styles, materials, methods and characteristics. It summarized the advantages and disadvantages of inkjet printing, angle-independent photonic crystal, self-assembled photonic crystals by magnetic field force, gravity, electric field, inverse opal photonic crystal, electron beam etching, ion beam etching, laser holographic lithography, imprinting technology and surface wrinkle technology, etc. This review will provide a summary on designing micro-nano patterns and details on patterns composed of photonic crystals by surface wrinkles technology and plasmonic micro-nano technology. In addition, colour patterns as switches are fabricated with good stability and reproducibility in anti-counterfeiting application. Finally, there will be a conclusion and an outlook on future perspectives.

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45

Śliwiak, Monika, Robert Bui, Michael A. Brook, and P. Ravi Selvaganapathy. "3D printing of highly reactive silicones using inkjet type droplet ejection and free space droplet merging and reaction." Additive Manufacturing 46 (October 2021): 102099. http://dx.doi.org/10.1016/j.addma.2021.102099.

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46

Xie, Ruyi, Kuanjun Fang, Weichao Chen, Zhen Shi, and Longyun Hao. "Effects of Polyols Solvents on Rheological Properties of Reactive Dye Inks for Textile Digital Inkjet Printing." NIP & Digital Fabrication Conference 2018, no. 1 (September 23, 2018): 69–71. http://dx.doi.org/10.2352/issn.2169-4451.2018.34.69.

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47

Shi, Furui, Qingbao Liu, Hongzhi Zhao, Kuanjun Fang, Ruyi Xie, Li Song, Mengyue Wang, and Weichao Chen. "Eco-Friendly Pretreatment to the Coloration Enhancement of Reactive Dye Digital Inkjet Printing on Wool Fabrics." ACS Sustainable Chemistry & Engineering 9, no. 30 (July 22, 2021): 10361–69. http://dx.doi.org/10.1021/acssuschemeng.1c03486.

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48

He, Yinfeng, Ruggero Foralosso, Gustavo F. Trindade, Alexander Ilchev, Laura Ruiz‐Cantu, Elizabeth A. Clark, Shaban Khaled, et al. "A Reactive Prodrug Ink Formulation Strategy for Inkjet 3D Printing of Controlled Release Dosage Forms and Implants." Advanced Therapeutics 3, no. 6 (February 19, 2020): 1900187. http://dx.doi.org/10.1002/adtp.201900187.

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49

Abulikemu, Mutalifu, Eman Husni Da'as, Hanna Haverinen, Dongkyu Cha, Mohammad Azad Malik, and Ghassan Elie Jabbour. "In Situ Synthesis of Self-Assembled Gold Nanoparticles on Glass or Silicon Substrates through Reactive Inkjet Printing." Angewandte Chemie International Edition 53, no. 2 (December 18, 2013): 420–23. http://dx.doi.org/10.1002/anie.201308429.

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50

Abulikemu, Mutalifu, Eman Husni Da'as, Hanna Haverinen, Dongkyu Cha, Mohammad Azad Malik, and Ghassan Elie Jabbour. "In Situ Synthesis of Self-Assembled Gold Nanoparticles on Glass or Silicon Substrates through Reactive Inkjet Printing." Angewandte Chemie 126, no. 2 (December 18, 2013): 430–33. http://dx.doi.org/10.1002/ange.201308429.

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Journal articles on the topic 'Reactive Inkjet Printing'

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