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Progress in Additive Manufacturing

Erschienen in:

04.02.2019 | Review Article

3D-printing and advanced manufacturing for electronics

verfasst von: Alejandro H. Espera Jr., John Ryan C. Dizon, Qiyi Chen, Rigoberto C. Advincula

Erschienen in: Progress in Additive Manufacturing | Ausgabe 3/2019

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Abstract

Printed electronics currently holds a significant share in the electronics fabrication market due to advantages in high-throughput production and customizability in terms of material support and system process. The printing of traces and interconnects, passive and active components such as resistors, capacitors, inductors, and application-specific electronic devices, have been a growing focus of research in the area of additive manufacturing. Adaptation of new 3D-printing technologies and manufacturing methods, specifically for printed electronics, are potentially transformative in flexible electronics, wireless communications, efficient batteries, solid-state display technologies, etc. Other than printing new and reactive functional electronic materials, the functionalization of the printing substrates with unusual geometries apart from the conventional planar circuit boards will be a challenge. Building the substrate, printing the conductive tracks, pick-and-placing or embedding the electronic components, and interconnecting them, are fundamental fabrication protocols new 3D-printing systems should adopt for a more integrated fabrication. Moreover, designers and manufacturers of such systems will play an important role in scaling 3D-printed electronics from prototyping to high-throughput mass production. This review gives a groundwork for such understanding, defining methods and protocols, reviewing various 3D-printing methods, and describing the state-of-the-art in 3D-printed electronics and their future growth.

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Nature (2018) “Electronic devices”. https://www.nature.com/subjects/electronic-devices. Accessed 24 Oct 2018

Research B (2017) “Global Electronics Components Market Sees Continued Growth (7.7% CAGR),” GlobeNewswire, 9 October 2017. https://globenewswire.com/news-release/2017/10/09/1142799/0/en/Global-Electronics-Components-Market-Sees-Continued-Growth-7-7-CAGR.html. Accessed 24 Oct 2018

Cook B, Tehrani B, Cooper J, Kim S, Tentzeris M (2015) Integrated printing for 2D/3D flexible organic electronic devices. Handbook of flexible organic electronics. Woodhead Publishing, Cambridge, pp 199–216

Weiderrecht G (2009) Handbook of nanofabrication. Elsevier, New York

Mosses R, Brackenridge S (2003) A novel process for the manufacturing of advanced interconnects. Circuit World 29(3):18–21CrossRef

Zhao D, Liu T, Lin Z, Zhang M, Liang R, Wang B (2012) Fabrication and characterization of aerosol-jet printed strain sensors for multifunctional composite structures. Smart Mater Struct 21(11):115008CrossRef

Lu B, Li D, Tian X (2015) Development trends in additive manufacturing and 3D printing. Engineering 1:85–89,CrossRef

Shirasaki Y, Supran G, Bawendi M, Bulović V (2012) Emergence of colloidal quantum-dot light-emitting technologies. Nat Photonics 7:13–23CrossRef

Dizon J, Espera A, Chen Q, Advincula R (2017) Mechanical characterization of 3D-printed polymers. Additive Manuf 20:44–67CrossRef

10.

Macdonald E, Salas R, Espalin D, Perez M, Aguilera E, Muse D, Wicker R (2014) 3D printing for the rapid prototyping of structural electronics. IEEE Access 2:234–242CrossRef

11.

Macdonald E (2012) Integrating stereolithography and direct print technologies for 3D structural electronics fabrication. Rapid Prototyping J

12.

Ahn B, Duoss E, Motala M, Guo X, Park S-I, Xiong Y, Yoon J, Nuzzo R, Rogers J, Lewis J (2009) Omnidirectional Printing of Flexible, Stretchable, and Spanning Silver Microelectrodes. Science 323(5921):1590–1593CrossRef

13.

Lewis J, Ahn B (2015) Three-dimensional printed electronics. Nature 518:42–43CrossRef

14.

NanoMarkets Report (2007) Printed electronics: a manufacturing technology analysis and capability forecast 2007. http://www.nanomarkets.net. Accessed 2 June 2017

15.

All About Circuits (2017) Active vs passive devices. https://www.allaboutcircuits.com/textbook/semiconductors/chpt-1/active-versus-passive-devices/. Accessed 13 Jun 2017

16.

Poole I (2017) What is SMT surface mount technology—tutorial. http://www.radio-electronics.com/info/data/smt/what-is-surface-mount-technology-tutorial.php. Accessed 25 Jun 2017

17.

NanoMarkets L (2005) NanoMarkets printable electronics report 2005. http://www.nanomarket.net/

18.

Gibson I, Rosen D, Stucker B (2009) Additive manufacturing technologies: 3D printing, rapid prototyping, and direct digital manufacturing. Springer, Berlin

19.

John (2010) ICF techniques, 31 May 2010. http://www.circuitstoday.com/ic-fabrication-techniques. Accessed 2 Jun 2017

20.

Kunnari E, Valkama J, Keskinen M, Mansikkamaki P (2009) Environmental evaluation of new technology: printed electronics case study. J Cleaner Prod 17:791–799CrossRef

21.

Kipphan H (2011) Handbook of print media. Springer, Germany

22.

Océ D (2006) Printing, 10th ed. Océ Printing Systems GmbH, Poing

23.

Sekitani T, Noguchi Y, Zschieschang U, Klauk H, Someya T (2008) Organic transistors manufactured using inkjet technology with subfemtoliter accuracy. Proc Natl Acad Sci 105(13):4976–4980CrossRef

24.

Sridhar A, Blaudeck T, Baumann R (2011) Inkjet printing as a key enabling technology for printed electronics. Mater Matters 6(1):12–15

25.

Wood V, Panzer M, Chen J, Bradley M, Halpert J, Bawendi M, Bulovic V (2009) Inkjet-printed quantum dot–polymer composites for full-color AC-driven displays. Adv Mater 21(21):1–5

26.

Derby B (2010) Inkjet printing of functional and structural materials: fluid property requirements, feature stability, and resolution. Annu Rev Mater Res 40:395–414CrossRef

27.

Professional SPIE (2013) Chuck Hull: pioneer in stereolithography. https://spie.org/membership/spie-professional-magazine/spie-professional-archives-and-special-content/2013-january-spie-professional-archive/chuck-hull. Accessed 11 Jun 2017

28.

Grimm T (2004) User’s guide to rapid prototyping. Society of Manufacturing Engineers, Dearborn

29.

Hull CW (1986) Apparatus for production of three-dimensional objects by stereolithography. US Patent 4,575,330, 11 March 1986

30.

Melchels FPW, Feijen J, Grijpma DW (2010) A review on stereolithography and its applications in biomedical engineering. Biomaterials 31:6121–6130CrossRef

31.

Waterman N, Dickens P (1994) Rapid product development in the USA, Europe and Japan. World Class Design Manuf 1(3):27–36CrossRef

32.

Pham D, Gault R (1998) “A comparison of rapid prototyping technologies”. Int J Mach Tools Manuf 38:1257–1287CrossRef

33.

Campbell T, Williams C, Ivanova O, Garrett B (2011) Could 3D printing change the world? Atlantic Council, Washington

34.

Kazmer D (2001) Three-dimensional printing of plastics. In: Applied plastics engineering handbook—processing, materials, and applications, a volume in plastic design library, Elsevier, New York, pp 617–634

35.

Sachs E, Cima M, Cornie J (1990) Three dimensional printing: rapid tooling and prototypes directly from CAD representation. CIRP Annals Manuf Technol 39(1):201–204CrossRef

36.

Mota C, Puppi D, Dinucci D, Gazzarri M, CHielleni F (2013) Additive manufacturing of star poly(ε-caprolactone) wetspun scaffolds for bone tissue engineering applications. J Bioact Compatib Polym 28(4):320–340CrossRef

37.

Lewis J (2006) Direct ink writing of 3D functional materials. Adv Funct Mater 16:2193–2204CrossRef

38.

de Leon A, Chen Q, Palaganas N, Palaganas J, Manapat J, Advincula R (2016) High performance polymer nanocomposites for additive manufacturing applications. React Funct Polym 103:141–155CrossRef

39.

Mortara L, Hughes J, Ramsundar PLF, Probert D (2009) Proposed classification scheme for direct wire technologies. Rapid Prototyping J 15(4):299–309CrossRef

40.

Hon K, Li L, Hutchings I (2008) Direct writing technology—advances and developments. CIRP Ann Manuf Technol 57(2):601–620CrossRef

41.

Perez K, Williams C (2013) Combining additive manufacturing and direct wire for integrated electronics—a review. In: 24th International solid freeform fabrication symposium—an additive manufacturing conference, Texas

42.

Hoerber J, Glasschroeder J, Pfeffer M, Schilp J, Zaeh M, Franke J (2014) Approaches for additive manufacturing of 3D electronic applications. Proc CIRP 17:806–811CrossRef

43.

Robinson CJ, Stucker B, Lopes AJ, Wicker R, Palmer JA (2006) Integration of direct-write (DW) and ultrasonic consolidation (UC) technologies to create advanced structures with embedded electrical circuitry. In: 17th solid freeform fabrication symposium, Texas

44.

Medina F, Lopes A, Inamdar A, Hennessey R, Palmer J, Chavez B, Davis D, Gallegos P, Wicker R (2005) Hybrid manufacturing: integrating direct write and stereolithography. In: Solid freeform fabrication symposium proceedings, Austin, TX

45.

Janaki Ram G, Yang Y, George J, Robinson C, Stucker B (2006) Improving Linear Weld Density in Ultrasonically Consolidated Parts. In: Solid freeform fabrication symposium proceedings, Austin, TX

46.

Masurtschak S, Friel R, Gillner A, Ryll J, Harris R (2014) Laser-machined microchannel effect on microstructure and oxide formation of an ultrasonically processed aluminum alloy. J Eng Mater Technol 137(1):011006CrossRef

47.

3D Printing Processes. https://3dprintingindustry.com/3d-printing-basics-free-beginners-guide/processes/. Accessed 16 Jul 2017

48.

Manapat J, Chen Q, Ye P, Advincula R (2017) 3D printing of polymer nanocomposites via stereolithography. Macromol Mater Eng 302:1600553CrossRef

49.

Dizon J, Chen Q, Valino A, Advincula R (2018) Thermo-mechanical and swelling properties of three-dimensional-printed poly(ethylene glycol) diacrylate/silica nanocomposites. MRS Commun. https://doi.org/10.1557/mrc.2018.188 CrossRef

50.

Gebhardt A (2007) Generative manufacturing processes, rapid prototyping–rapid tooling–rapid manufacturing. Carl Hanser, Munich

51.

Zaeh M, Glasschroeder J, Krol T, Schilp J (2011) Innovative solutions for increasing the quality of components at additive manufacturing. Utz, Munich

52.

Gibbson I, Rosen D, Stucker B (2010) Additive manufacturing technologies, rapid prototyping to direct digital manufacturing. Springer, New York

53.

Lee D, Oh J (2010) Inkjet printing of conductive Ag lines and their electrical and mechanical characterization. Thin Solid Films 518(22):6352–6356CrossRef

54.

Hedges M (2010) 3D aerosol jet printing—an emerging mid manufacturing. In: 9th International congress molded interconnect devices, Fuerth

55.

Teschler L (2015) Your next circuit design could be fabricated on a printer. http://www.powerelectronictips.com/your-next-circuit-design-could-be-fabricated-on-a-printer/. Accessed 22 Jun 2017

56.

Krebs T (2010) Flexible circuits or printed circuit boards? Technology selection based on virtual prototypes. In: 9th International congress molded interconnect devices, Fuerth

57.

Frank J, Feldmann K, Fischer C (2009) Two approaches for the design of modeled interconnect devices (3D-MID). In: Proceedings 6th international conference on digital enterprise technology, Hongkong

58.

Falat T, Platek B, Felba J (2012) Sintering process of silver nanoparticles in ink-jet printed conductive microstructures—molecular dynamics approach. In: 13th International conference on thermal, mechanical and multi-physics simulation and experiments in microelectronics and microsystems

59.

Allen M (2011) Nanoparticle sintering methods and applications for printed electronics. In: Aalto University publication series, Helsinki

60.

Frank J (2013) Molded interconnect devices 3D-MID: materials, manufacturing, assembly and applications for molded circuit carriers. Carl Hanser, Munich

61.

Pfeffer M, Goth C, Craiovan D, Frank J (2011) 3D-Assembly of molded interconnect devices with standard smd pick & place machines using an active multi axis workpiece carrier. In: International symposium on assembly and manufacturing, IEEE, Tampere

62.

Miettinen J, Pekkanen V, Kaija K, Mansikkamaki P, Mantysalo J, Mantysalo M (2008) Inkjet printed system-in-package design and manufacturing. Microelectron J 39(12):1740–1750CrossRef

63.

editor OEA (2011) A roadmap for organic and printed electronics. Whitepaper-OE, Frankfurt

64.

Tseng H, Subramanian V (2011) All inkjet-printed, fully self-aligned transistors for low-cost circuit applications. Org Electron 12(2):249–256CrossRef

65.

Kim D, Lee S, Jeong S, Moon J (2009) All-ink-jet printed flexible organic thin-film transistors on plastic substrates. Electrochem Solid State Lett 12:H195-H197

66.

Saengchairat N, Tran T, Chua C (2017) A review: additive manufacturing for active electronic components. Virtual Phys Prototyp 12:31–46CrossRef

67.

Tan H, Tran T, Chua C (2016) A review of printed passive electronic components through fully additive manufacturing methods. Virtual Phys Prototyp 11:271–288CrossRef

68.

Ready S, Arias A, Sambandan S (2009) Ink jet printing devices and circuits. In: Materials research society fall meeting, Boston, MA

69.

Ready S, Wong W, Arias A, Apte R, CHabynic M, Street R, Salleo A (2006) Toolset for printed electronics. In: International conference on digital fabrication technologies, Denver, CO

70.

Ng T, Schwartz E, Lavery L, Whiting G, Krusor RB,B, Veres J, Broms P, Herlogsson L, Alam N, Hagel O, Nilsson J, Karlsson C (2012) Scalable printed electronics: a printed decoder addressing ferroelectric nonvolatile memory. Sci Rep 2:585CrossRef

71.

Ready S, Endicott F, Whiting G, Ng T, Chow E, Lu J (2013) 3D printed electronics. In: NIP 29 and Digital Fabrication pp 9–12

72.

MacDonald E, Wicker R (2016) Multiprocess 3D printing for increasing component functionality. Science 353:aaf2093CrossRef

73.

Jung S, Sou A, Gili E, Sirringhaus H (2013) Inkjet-printed resistors with a wide resistance range for printed read-only memory applications. Org Electron 14:699–702CrossRef

74.

3D-printing basic electronic components (2015) http://www.kurzweilai.net/3d-printing-basic-electronic-components. Accessed 6 July 2017

75.

Wu S-Y, Yang C, Hsu W, Lin L (2015) 3D-printed microelectronics for integrated circuitry and passive wireless sensors. Microsyst Nanoeng 1:15013CrossRef

76.

Kong Y, Tamargo I, Kim H, Johnson B, Gupta M, Koh T-W, Chin H-A, Steingart D, Rand B, McAlpine M (2014) 3D printed quantum dot light-emitting diodes. Nano Lett 14:7017–7020CrossRef

77.

Goh G, Ma J, Chua K, Shweta A, Yeong W, Zhang Y (2016) Inkjet-printed patch antenna emitter for wireless communication application. Virtual Phys Prototyp 11:289–294CrossRef

78.

Adams J, Bernhard J (2009) Tuning method for a new electrically small antenna with low Q. IEEE Antennas Wireless Propag Lett 8:303–306CrossRef

79.

Adams J, Duoss EB, Malkowski T, Motala M, Ahn B, Nuzzo R, Bernhard J, Lewis J (2011) Conformal printing of electrically snall antennas on three-dimensional surfaces. Adv Mater 23:1335–1340CrossRef

80.

Baca A, Yu K, Xiao J, Wang S, Yoon J, Ryu J, Stevenson D, Nuzzo R, Rockett A, Huang Y, Rogers J (2010) Compact monocrystalline silicon solar modules with high voltage outputs and mechanically flexible designs. Energy Environ Sci 3:208–211CrossRef

81.

Rogers J, Bao Z, Baldwin K, Dodabalapur A, Crone B, Raju V, Kuck V, Katz H, Amundson K, Ewing J, Drzaic P (2001) Paper-like electronic displays: large-area rubber-stamped plastic sheets of electronics and microencapsulated electrophoretic inks. Proc Natl Acad Sci/ USA 98(9):4835–4840CrossRef

82.

Fichet G, Corcoran N, Ho P, Arias A, MacKenzie J, Huck W, Friend R (2004) Self-organized photonic structures in polymer light-emitting diodes. Adv Mater 16:1908CrossRef

83.

Someya T, Kato Y, Sekitani S, Iba Y, Noguchi Y, Murase H, Kawaguchi, Sakurai T (2005) Conformable, flexible, large-area networks of pressure and thermal sensors with organic transistor active matrixes. Proc Natl Acad Sci USA 102(35):12321–12325CrossRef

84.

Cao Q, Hur S-H, Zhu Z-T, Sun Y, Wang C, Meitl M, Shim M, Rogers J (2006) Highly bendable, transparent thin-film transistors that use carbon-nanotube-based conductors and semiconductors with elastomeric dielectrics. Adv Mater 18:304–309CrossRef

85.

Gaikwad A, Whiting G, Steingart D, Arias A (2011) Highly flexible printed alkaline batteries based on mesh embedded electrodes. Adv Mater 23:3251CrossRef

86.

Liu H, Huang W, Gao J, Dai K, Zheng G, Liu C (2016) Piezoresistive behavior of porous carbon nanotube-thermoplastic polyurethane conductive nanocomposites with ultrahigh compressibility. Appl Phys Lett 108(1):11904CrossRef

87.

Yao H, Ge J, Wang C, Wang X, Hu W, Zheng Z, Ni Y, Yu S (2013) A flexible and highly pressure-sensitive graphene–polyurethane sponge based on fractured microstructure design. Adv Mater 25(46):6692–6698CrossRef

88.

Chen Q, Cao P, Advincula R (2018) Mechanically robust, ultraelastic hierarchical foam with tunable properties via 3D printing. Adv Func Mater 28:1800631CrossRef

89.

Fan YJ, Meng XS, Li HY, Kuang SY, Zhang L, Wu Y, Wang ZL, Zhu G (2017) Stretchable porous carbon nanotube-elastomer hybrid nanocomposite for harvesting mechanical energy. Adv Mater 29(2):1603115CrossRef

90.

Liu C, Choi J (2009) An embedded PDMS nanocomposite strain sensor toward biomedical applications. In: Engineering in Medicine and Biology Society, annual international conference of the IEEE, pp 6391–6394

91.

Amjadi M, Pichitpajongkit A, Lee S, Ryu S, Park I (2014) “Highly stretchable and sensitive strain sensor based on silver nanowire-elastomer nanocomposite. ACS Nano 8(5):5154–5163CrossRef

92.

Chen Q, Mangadlao J, Wallat J, de Leon A, Pokorski J, Advincula R (2017) 3D printing biocompatible polyurethane/poly (lactic acid)/graphene oxide nanocomposites: anisotropic properties. ACS Appl Mater Interfaces 9(4):4015–4023CrossRef

93.

Bates S, Farrow I, Trask R, RG S (2016) 3D printed elastic honeycombs with graded density for tailorable energy absorption. SPIE smart structures and materials + nondestructive evaluation and health monitoring. International Society for Optics and Photonics, Bellingham, p 979907

94.

Christ J, Aliheidari N, Ameli A, Potschke P (2017) 3D printed highly elastic strain sensors of multiwalled carbon nanotube/thermoplastic polyurethane nanocomposites. Mater Design 131:394–401CrossRef

95.

Muth J, Vogt D, Trugby R, Menguc Y, Kolesky D, Wood R, Lewis J (2014) Embedded 3D printing of strain sensors within highly stretchable elastomers. Adv Mater 26(36):6307–6312CrossRef

96.

Choi J-H, Wang H, Oh J, Paik T, Jo P, SUng J, Ye X, Zhao T, Murray DBT,C, Kagan C (2016) Exploiting the colloidal nanocrystal library to construct electronic devices. Science 352(6282):205–208CrossRef

97.

Wehner M, Truby R, Fitzgerald D, Mosadegh B, Whitesides G, Lewis J, Wood R (2016) An integrated design and fabrication strategy for entirely soft, autonomous robots. Nature 536:451–455CrossRef

98.

Malone E, Bery M, Lipson H (2008) Freeform fabrication and characterization of Zn-air batteries. Rapid Prototyp J 14(3):128–140CrossRef

99.

Sun K, Wei T-S, Ahn B, Seo J, DIllon S, Lewis J (2013) 3D printing of interdigitated Li-Ion microbattery architecture. Adv Mater 25:4539–4543CrossRef

100.

MarketsandMarkets (2016) Printed E market by material (Ink, Substrate), technology (inkjet, screen, gravure, flexographic), device (sensors, displays, batteries, rfid, lighting, photovoltaic) and geography—Global forecast to 2022. http://www.marketsandmarkets.com/Market-Reports/printed-electronics-market-197.html. Accessed 8 Jul 2017

101.

Sridhar A (2010) An inkjet printing-based process chain for conductive structures on printed circuit board materials. Thesis PhD, University of Twente, the Netherlands,

102.

Parashkhov R, Becker E, Riedl T, Johannes H-H, Kowalsky W (2005) All-organic thin-film transistors made of poly(3-butylthiophene) semiconducting and various polymeric insulating layers. In: W. Proc. IEEE, vol. 93, no. 7

103.

Vornbrock ADLF, Sung D, Kang H, Kitsomboonloha R, Subramanian V (2010) Fully gravure and ink-jet printed high speed pBTTT organic thin film transistors. Org Electron 11:2037. https://doi.org/10.1016/j.orgel.2010.09.003 CrossRef

104.

Pekkanen J (2007) Sintering of inkjet printed Ag nanoparticles. Master of Science thesis, Tampere, Finland

105.

Lam Research (2017) Products overview: enabling chipmakers to create the future. http://www.lamresearch.com/products/products-overview. Accessed 13 Jun 2017

106.

Gaynor A, Meisel N, Williams C, Guest J (2014) Multi-material topology optimization of compliant mechanisms created via PlyJet three-dimensional printing. J Manuf Sci Eng 136(6):061015CrossRef

107.

Gibson I, Rosen D, Stucker B (2010) Additive manufacturing technologies. Springer, BostonCrossRef

108.

Perelaer J, Schubert U, Jena F (2010) Inkjet printing and alternative sintering of narrow conductive tracks on flexible substrates for plastic electronic applications. Radio frequency identification fundamentals and applications, design methods and solutions. InTech, Rijeka, Croatia, pp 265–286

109.

Lee J-Y, An J, Chua C (2017) Fundamentals and applications of 3D printing for novel materials. Appl Mater Today 7:120–133CrossRef

Titel: 3D-printing and advanced manufacturing for electronics
verfasst von: Alejandro H. Espera Jr.
John Ryan C. Dizon
Qiyi Chen
Rigoberto C. Advincula
Publikationsdatum: 04.02.2019
Verlag: Springer International Publishing
Erschienen in: Progress in Additive Manufacturing / Ausgabe 3/2019
Print ISSN: 2363-9512
Elektronische ISSN: 2363-9520
DOI: https://doi.org/10.1007/s40964-019-00077-7

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