Direct write dispenser printed energy storage devices

Christine C. Ho, Jayme Scot Keist, Ba Q. Quan, James W. Evans, Paul K. Wright

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

As electronic devices become smaller in size and more specialized in functionality, a paradigm shift in energy storage design and manufacture is beginning to emerge, and can be realized with the development of simple, low-cost, solutions-based processing methods to incorporate custom energy buffers directly onto a device. We have been developing the materials and direct write fabrication methods for printing carbon based electrochemical microcapacitors and zinc microbatteries directly onto a substrate. Our materials efforts include the optimization of mechanical and ionic transport properties of ionic liquid gel electrolytes, and this has enabled the fabrication of completely printable "solid-state" capacitors and batteries, mitigating manufacturing and packaging concerns. Through a pneumatic direct write dispenser printing system, the energy storage devices can be patterned and integrated directly on-chip, and initial device characterization has been conducted.

Original languageEnglish (US)
Title of host publicationJim Evans Honorary Symposium - Held During TMS 2010 Annual Meeting and Exhibition
Pages317-324
Number of pages8
StatePublished - May 28 2010
EventJim Evans Honorary Symposium - TMS 2010 Annual Meeting and Exhibition - Seattle, WA, United States
Duration: Feb 14 2010Feb 18 2010

Publication series

NameTMS Annual Meeting

Other

OtherJim Evans Honorary Symposium - TMS 2010 Annual Meeting and Exhibition
CountryUnited States
CitySeattle, WA
Period2/14/102/18/10

Fingerprint

dispensers
Dispensers
energy storage
Energy storage
Printing
Fabrication
Ionic Liquids
printing
Ionic liquids
Pneumatics
Transport properties
Electrolytes
Zinc
Packaging
Buffers
fabrication
Capacitors
Carbon
Gels
pneumatics

All Science Journal Classification (ASJC) codes

  • Condensed Matter Physics
  • Mechanics of Materials
  • Metals and Alloys

Cite this

Ho, C. C., Keist, J. S., Quan, B. Q., Evans, J. W., & Wright, P. K. (2010). Direct write dispenser printed energy storage devices. In Jim Evans Honorary Symposium - Held During TMS 2010 Annual Meeting and Exhibition (pp. 317-324). (TMS Annual Meeting).
Ho, Christine C. ; Keist, Jayme Scot ; Quan, Ba Q. ; Evans, James W. ; Wright, Paul K. / Direct write dispenser printed energy storage devices. Jim Evans Honorary Symposium - Held During TMS 2010 Annual Meeting and Exhibition. 2010. pp. 317-324 (TMS Annual Meeting).
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Ho, CC, Keist, JS, Quan, BQ, Evans, JW & Wright, PK 2010, Direct write dispenser printed energy storage devices. in Jim Evans Honorary Symposium - Held During TMS 2010 Annual Meeting and Exhibition. TMS Annual Meeting, pp. 317-324, Jim Evans Honorary Symposium - TMS 2010 Annual Meeting and Exhibition, Seattle, WA, United States, 2/14/10.

Direct write dispenser printed energy storage devices. / Ho, Christine C.; Keist, Jayme Scot; Quan, Ba Q.; Evans, James W.; Wright, Paul K.

Jim Evans Honorary Symposium - Held During TMS 2010 Annual Meeting and Exhibition. 2010. p. 317-324 (TMS Annual Meeting).

Research output: Chapter in Book/Report/Conference proceedingConference contribution

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Ho CC, Keist JS, Quan BQ, Evans JW, Wright PK. Direct write dispenser printed energy storage devices. In Jim Evans Honorary Symposium - Held During TMS 2010 Annual Meeting and Exhibition. 2010. p. 317-324. (TMS Annual Meeting).