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2D-printing ink based on ultrasound exfoliated graphite

A technique is described for producing 2D-printing ink based on ultrasound exfoliated graphite (UEG). It has been established that the conductivity of a film obtained by microfiltration of such ink is 26.4 S/cm. Data on the morphology, composition, and IR spectra of UEG films are provided and compar...

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Published in:	Technical physics letters 2017-03, Vol.43 (3), p.274-278
Main Authors:	Shul’ga, Yu. M., Lobach, A. S., Baskakov, S. A., Konev, D. A., Lyskov, N. V., Kabachkov, E. N.
Format:	Article
Language:	English
Subjects:	Classical and Continuum Physics Graphene Graphite Infrared spectroscopy Microfiltration Oxide coatings Physics Physics and Astronomy
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creator	Shul’ga, Yu. M. Lobach, A. S. Baskakov, S. A. Konev, D. A. Lyskov, N. V. Kabachkov, E. N.
description	A technique is described for producing 2D-printing ink based on ultrasound exfoliated graphite (UEG). It has been established that the conductivity of a film obtained by microfiltration of such ink is 26.4 S/cm. Data on the morphology, composition, and IR spectra of UEG films are provided and compared with analogous data for reduced graphene-oxide films.
doi_str_mv	10.1134/S1063785017030117
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subjects	Classical and Continuum Physics Graphene Graphite Infrared spectroscopy Microfiltration Oxide coatings Physics Physics and Astronomy
title	2D-printing ink based on ultrasound exfoliated graphite
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