Hydrogen-Terminated Graphene by Laser Vaporization-Controlled Condensation of Graphite Oxide. Observation of Hydrogen-Capped Carbon Chains C n H–, C n H+, and C n H2 + (n = 2–30) in the Gas Phase

Hydrogen-Terminated Graphene by Laser Vaporization-Controlled Condensation of Graphite Oxide. Observation of Hydrogen-Capped Carbon Chains C n H–, C n H+, and C n H2 + (n = 2–30) in the Gas Phase

We report the development of a facile process for the synthesis of hydrogen-terminated graphene using the laser vaporization-controlled condensation (LVCC) method. The method allows rapid deoxygenation of bulk graphite oxide (GO) in an atmosphere of helium or a helium–hydrogen mixture to produce hyd...

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Bibliographic Details
Published in:Journal of physical chemistry. C Vol. 117; no. 18; pp. 9485 - 9495
Main Authors: Afshani, Parichehr, Attah, Isaac, Moussa, Sherif, Terner, James, El-Shall, M. S
Format: Journal Article
Language:English
Published: American Chemical Society 09-05-2013
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Summary:We report the development of a facile process for the synthesis of hydrogen-terminated graphene using the laser vaporization-controlled condensation (LVCC) method. The method allows rapid deoxygenation of bulk graphite oxide (GO) in an atmosphere of helium or a helium–hydrogen mixture to produce hydrogen-terminated graphene (HTG) nanosheets without the need for any chemical reducing agents or solvents. Direct laser vaporization/ionization (LVI) of bulk GO in a vacuum coupled with a beam expansion of a carrier gas produces the carbon cluster series C n with n in the range 4–30, in addition to hydrogenated carbon ions with a significant enhancement in the ion intensity of the n-even ions suggesting the formation of hydrogen-capped polyyne chains corresponding to the H–(CC) n –H+ and H–(CC) n – formulas. In contrast, LVI of bulk graphite under identical experimental conditions generates mainly the carbon cluster series C n without any significant hydrogenation in both the positive and negative ion modes. The results confirm that the LVCC method of bulk GO produces HTG nanosheets which can be ionized and dissociated in a vacuum to produce the observed hydrogen-capped polyyne chains. These species could be deposited from the gas phase to form one-dimensional conducting molecular wires for a variety of potential applications in nanoelectronics, sensors, and devices.
ISSN:1932-7447
1932-7455
DOI:10.1021/jp401318d