Graphene foam developed with a novel two-step technique for low and high strains and pressure-sensing applications

Yarjan Abdul Samad; Yuanqing Li; Andreas Schiffer; Saeed M. Alhassan; Kin Liao

doi:10.1002/smll.201403532

Graphene foam developed with a novel two-step technique for low and high strains and pressure-sensing applications

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223 Scopus citations

Abstract

Freestanding, mechanically stable, and highly electrically conductive graphene foam (GF) is formed with a two-step facile, adaptable, and scalable technique. This work also demonstrates the formation of graphene foam with tunable densities and its use as strain/pressure sensor for both high and low strains and pressures.

Original language	British English
Pages (from-to)	2380-2385
Number of pages	6
Journal	Small
Volume	11
Issue number	20
DOIs	https://doi.org/10.1002/smll.201403532
State	Published - 27 May 2015

Keywords

graphene foam
graphene oxide
pressure sensors
strain sensors

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title = "Graphene foam developed with a novel two-step technique for low and high strains and pressure-sensing applications",

abstract = "Freestanding, mechanically stable, and highly electrically conductive graphene foam (GF) is formed with a two-step facile, adaptable, and scalable technique. This work also demonstrates the formation of graphene foam with tunable densities and its use as strain/pressure sensor for both high and low strains and pressures.",

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AU - Samad, Yarjan Abdul

AU - Li, Yuanqing

AU - Schiffer, Andreas

AU - Alhassan, Saeed M.

AU - Liao, Kin

PY - 2015/5/27

Y1 - 2015/5/27

N2 - Freestanding, mechanically stable, and highly electrically conductive graphene foam (GF) is formed with a two-step facile, adaptable, and scalable technique. This work also demonstrates the formation of graphene foam with tunable densities and its use as strain/pressure sensor for both high and low strains and pressures.

AB - Freestanding, mechanically stable, and highly electrically conductive graphene foam (GF) is formed with a two-step facile, adaptable, and scalable technique. This work also demonstrates the formation of graphene foam with tunable densities and its use as strain/pressure sensor for both high and low strains and pressures.

KW - graphene foam

KW - graphene oxide

KW - pressure sensors

KW - strain sensors

UR - https://www.scopus.com/pages/publications/85027918161

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Graphene foam developed with a novel two-step technique for low and high strains and pressure-sensing applications

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Keywords

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