Carbon fiber doped thermosetting elastomer for flexible sensors: physical properties and microfabrication

Ajit Khosla; Shreyas Shah; Md Nahin Islam Shiblee; Sajjad Husain Mir; Larry Akio Nagahara; Thomas Thundat; Praveen Kumar Shekar; Masaru Kawakami; Hidemitsu Furukawa

doi:10.1038/s41598-018-30846-3

Carbon fiber doped thermosetting elastomer for flexible sensors: physical properties and microfabrication

Ajit Khosla
, Shreyas Shah
, Md Nahin Islam Shiblee
, Sajjad Husain Mir
, Larry Akio Nagahara
, Thomas Thundat
, Praveen Kumar Shekar
, Masaru Kawakami
, Hidemitsu Furukawa

Department of Chemical and Biological Engineering

Yamagata University
Trinity College Dublin
Johns Hopkins University
Washington State University Vancouver

Research output: Contribution to journal › Article › peer-review

300 Scopus citations

Abstract

We have developed conductive microstructures using micropatternable and conductive hybrid nanocomposite polymer. In this method carbon fibers (CFs) were blended into polydimethylsiloxane (PDMS). Electrical conductivities of different compositions were investigated with various fiber lengths (50–250 μm), and weight percentages (wt%) (10–60 wt%). Sample composites of 2 cm × 1 cm × 500 μm were fabricated for 4-point probe conductivity measurements. The measured percolation thresholds varied with length of the fibers: 50 wt% (307.7 S/m) for 50 µm, 40 wt% (851.1 S/m) for 150 µm, and 30 wt% (769.23 S/m) for 250 μm fibers. The conductive composites showed higher elastic modulus when compared to that of PDMS.

Original language	English
Article number	12313
Journal	Scientific Reports
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41598-018-30846-3
State	Published - Dec 1 2018

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title = "Carbon fiber doped thermosetting elastomer for flexible sensors: physical properties and microfabrication",

abstract = "We have developed conductive microstructures using micropatternable and conductive hybrid nanocomposite polymer. In this method carbon fibers (CFs) were blended into polydimethylsiloxane (PDMS). Electrical conductivities of different compositions were investigated with various fiber lengths (50–250 μm), and weight percentages (wt\%) (10–60 wt\%). Sample composites of 2 cm × 1 cm × 500 μm were fabricated for 4-point probe conductivity measurements. The measured percolation thresholds varied with length of the fibers: 50 wt\% (307.7 S/m) for 50 µm, 40 wt\% (851.1 S/m) for 150 µm, and 30 wt\% (769.23 S/m) for 250 μm fibers. The conductive composites showed higher elastic modulus when compared to that of PDMS.",

author = "Ajit Khosla and Shreyas Shah and Shiblee, \{Md Nahin Islam\} and Mir, \{Sajjad Husain\} and Nagahara, \{Larry Akio\} and Thomas Thundat and Shekar, \{Praveen Kumar\} and Masaru Kawakami and Hidemitsu Furukawa",

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doi = "10.1038/s41598-018-30846-3",

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T1 - Carbon fiber doped thermosetting elastomer for flexible sensors

T2 - physical properties and microfabrication

AU - Khosla, Ajit

AU - Shah, Shreyas

AU - Shiblee, Md Nahin Islam

AU - Mir, Sajjad Husain

AU - Nagahara, Larry Akio

AU - Thundat, Thomas

AU - Shekar, Praveen Kumar

AU - Kawakami, Masaru

AU - Furukawa, Hidemitsu

PY - 2018/12/1

Y1 - 2018/12/1

N2 - We have developed conductive microstructures using micropatternable and conductive hybrid nanocomposite polymer. In this method carbon fibers (CFs) were blended into polydimethylsiloxane (PDMS). Electrical conductivities of different compositions were investigated with various fiber lengths (50–250 μm), and weight percentages (wt%) (10–60 wt%). Sample composites of 2 cm × 1 cm × 500 μm were fabricated for 4-point probe conductivity measurements. The measured percolation thresholds varied with length of the fibers: 50 wt% (307.7 S/m) for 50 µm, 40 wt% (851.1 S/m) for 150 µm, and 30 wt% (769.23 S/m) for 250 μm fibers. The conductive composites showed higher elastic modulus when compared to that of PDMS.

AB - We have developed conductive microstructures using micropatternable and conductive hybrid nanocomposite polymer. In this method carbon fibers (CFs) were blended into polydimethylsiloxane (PDMS). Electrical conductivities of different compositions were investigated with various fiber lengths (50–250 μm), and weight percentages (wt%) (10–60 wt%). Sample composites of 2 cm × 1 cm × 500 μm were fabricated for 4-point probe conductivity measurements. The measured percolation thresholds varied with length of the fibers: 50 wt% (307.7 S/m) for 50 µm, 40 wt% (851.1 S/m) for 150 µm, and 30 wt% (769.23 S/m) for 250 μm fibers. The conductive composites showed higher elastic modulus when compared to that of PDMS.

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DO - 10.1038/s41598-018-30846-3

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VL - 8

JO - Scientific Reports

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ER -

Carbon fiber doped thermosetting elastomer for flexible sensors: physical properties and microfabrication

Abstract

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