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Microsystem Technologies
Erschienen in: Microsystem Technologies 10/2017

19.11.2016 | Technical Paper

Facial fabrication of paper-based flexible electronics with flash foam stamp lithography

verfasst von: XinHua Yao, Tian Jia, ChaoQi Xie, JianZhong Fu, Yong He

Erschienen in: Microsystem Technologies | Ausgabe 10/2017

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Abstract

Paper-based flexible electronics/circuit have a bright potential in displays, transistor and sensors due to low cost and disposability. Here we presented a facile microfabrication method for paper-based flexible electronics with flash foam stamp lithography (FFSL), which can be implemented in resource-limited laboratory. Only two steps are needed. Firstly, negative patterns of circuit are stamped on the paper with polydimethylsiloxane (PDMS) ink to form hydrophobic barriers after PDMS is solidified. Then the patterned paper is immersed in the conductive ink to absorb ink and acquire circuits. In this paper we present foldable, waterproof and multi-layer paper-based flexible electronics can be easily fabricated. Also as FFSL can be also directly used in fabrication of microfluidic paper-based analytical devices (μPADs), this method has a promising potential in fabricating electrodes of μPADs.
Vorheriger Artikel High performance planar micro-transformer using novel crossover connection
Nächster Artikel Vibration protection of laptop hard disk drives in harsh environmental conditions

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Literatur
Ahmed S, Bui MPN, Abbas A (2016) Paper-based chemical and biological sensors: engineering aspects[J]. Biosens Bioelectron 77:249–263CrossRef
Andersson P, Forchheimer R, Tehrani P et al (2007) Printable all-organic electrochromic active-matrix displays[J]. Adv Funct Mater 17(16):3074–3082CrossRef
Cate DM, Adkins JA, Mettakoonpitak J et al (2014) Recent developments in paper-based microfluidic devices[J]. Anal Chem 87(1):19–41CrossRef
Chen Y, Li Y, Xu D et al (2015) Fabrication of stretchable, flexible conductive thermoplastic polyurethane/graphene composites via foaming[J]. RSC Adv 5(100):82034–82041CrossRef
Deganello D, Cherry JA, Gethin DT et al (2010) Patterning of micro-scale conductive networks using reel-to-reel flexographic printing[J]. Thin Solid Films 518(21):6113–6116CrossRef
Gao Y, Li H, Liu J (2012) Direct writing of flexible electronics through room temperature liquid metal ink[J]. PLoS One 7(9):e45485CrossRef
Ge S, Ge L, Yan M et al (2012) A disposable paper-based electrochemical sensor with an addressable electrode array for cancer screening[J]. Chem Commun 48(75):9397–9399CrossRef
Gwon H, Kim HS, Lee KU et al (2011) Flexible energy storage devices based on graphene paper[J]. Energy Environ Sci 4(4):1277–1283CrossRef
He Y, Wu Y, Xiao X et al (2014) A low-cost and rapid microfluidic paper-based analytical device fabrication method: flash foam stamp lithography[J]. RSC Adv 4(109):63860–63865CrossRef
He Y, Xiao X, Wu Y et al (2015a) A facile and low-cost micro fabrication material: flash foam[J]. Sci Rep 5:13522CrossRef
He Y, Wu Y, Fu JZ et al (2015b) Fabrication of paper-based microfluidic analysis devices: a review[J]. RSC Adv 5(95):78109–78127CrossRef
Hübler A, Trnovec B, Zillger T et al (2011) Printed paper photovoltaic cells[J]. Adv Energy Mater 1(6):1018–1022CrossRef
Karthik PS, Singh SP (2015) Conductive silver inks and their applications in printed and flexible electronics[J]. RSC Adv 5(95):77760–77790CrossRef
Krebs FC (2009) Pad printing as a film forming technique for polymer solar cells[J]. Sol Energy Mater Sol Cells 93(4):484–490CrossRef
Lessing J, Glavan AC, Walker SB et al (2014) Inkjet printing of conductive inks with high lateral resolution on omniphobic “RF Paper” for paper-based electronics and MEMS[J]. Adv Mater 26(27):4677–4682CrossRef
Li W, Wang M, Liu G et al (2016) Direct writing of stable Cu–Ag-based conductive patterns for flexible electronics[J]. RSC Adv 6:10670–10676CrossRef
Liana DD, Raguse B, Gooding JJ et al (2012) Recent advances in paper-based sensors[J]. Sensors 12(9):11505–11526CrossRef
Muth JT, Vogt DM, Truby RL et al (2014) Embedded 3D printing of strain sensors within highly stretchable elastomers [J]. Adv Mater 26(36):6307–6312CrossRef
Nie Z, Nijhuis CA, Gong J et al (2010) Electrochemical sensing in paper-based microfluidic devices[J]. Lab Chip 10(4):477–483CrossRef
Reddy NK, Devika M, Tu CW (2014) High-quality ZnO nanorod based flexible devices for electronic and biological applications[J]. RSC Adv 4(71):37563–37568CrossRef
Russo A, Ahn BY, Adams JJ et al (2011) Pen-on-paper flexible electronics[J]. Adv Mater 23(30):3426–3430CrossRef
Sun B, Long YZ, Chen ZJ et al (2014) Recent advances in flexible and stretchable electronic devices via electrospinning[J]. J Mater Chem C 2(7):1209–1219CrossRef
Tai YL, Yang ZG (2011) Fabrication of paper-based conductive patterns for flexible electronics by direct-writing[J]. J Mater Chem 21(16):5938–5943CrossRef
Thom NK, Yeung K, Pillion MB et al (2012) “Fluidic batteries” as low-cost sources of power in paper-based microfluidic devices[J]. Lab Chip 12(10):1768–1770CrossRef
Tobjörk D, Österbacka R (2011) Paper electronics[J]. Adv Mater 23(17):1935–1961CrossRef
Tok JBH, Bao Z (2012) Recent advances in flexible and stretchable electronics, sensors and power sources[J]. Sci China Chem 55(5):718–725CrossRef
Xia Y, Si J, Li Z (2016) Fabrication techniques for microfluidic paper-based analytical devices and their applications for biological testing: a review[J]. Biosens Bioelectron 77:774–789CrossRef
Yamada K, Henares TG, Suzuki K et al (2015) Paper-based inkjet-printed microfluidic analytical devices[J]. Angew Chem Int Ed 54(18):5294–5310CrossRef
Yu L, Chen Q, Tian YL et al (2015) One-post patterning of multiple protein gradients using a low-cost flash foam stamp[J]. Chem Commun 51(99):17588–17591CrossRef
Yun S, Jang SD, Yun GY et al (2009) Paper transistor made with covalently bonded multiwalled carbon nanotube and cellulose[J]. Appl Phys Lett 95(10):104102CrossRef
Zhai D, Zhang T, Guo J et al (2013) Water-based ultraviolet curable conductive inkjet ink containing silver nano-colloids for flexible electronics[J]. Colloids Surf A 424:1–9CrossRef
Zheng Y, He Z, Gao Y et al (2013) Direct desktop printed-circuits-on-paper flexible electronics[J]. Sci Rep 3:1786CrossRef
Zielke D, Hübler AC, Hahn U et al (2005) Polymer-based organic field-effect transistor using offset printed source/drain structures[J]. Appl Phys Lett 87(12):123508CrossRef
Metadaten
Titel
Facial fabrication of paper-based flexible electronics with flash foam stamp lithography
verfasst von
XinHua Yao
Tian Jia
ChaoQi Xie
JianZhong Fu
Yong He
Publikationsdatum
19.11.2016
Verlag
Springer Berlin Heidelberg
Erschienen in
Microsystem Technologies / Ausgabe 10/2017
Print ISSN: 0946-7076
Elektronische ISSN: 1432-1858
DOI
https://doi.org/10.1007/s00542-016-3207-6

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