An Affordable Wet Chemical Route to Grow Conducting Hybrid Graphite-Diamond Nanowires: Demonstration by A Single Nanowire Device

We report an affordable wet chemical route for the reproducible hybrid graphite-diamond nanowires (G-DNWs) growth from cysteamine functionalized diamond nanoparticles ( ND-Cys ) via pH induced self-assembly, which has been visualized through SEM and TEM images. Interestingly, the mechanistic aspects...

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Veröffentlicht in:	Scientific reports 2017-09, Vol.7 (1), p.11243-13, Article 11243
Hauptverfasser:	Shellaiah, Muthaiah, Chen, Tin Hao, Simon, Turibius, Li, Liang-Chen, Sun, Kien Wen, Ko, Fu-Hsiang
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Schlagworte:	140/133 639/925/357 639/925/927 Coexistence Graphite Humanities and Social Sciences multidisciplinary Nanoparticles Nanotechnology Nanowires pH effects Science Science (multidisciplinary) Self-assembly
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description	We report an affordable wet chemical route for the reproducible hybrid graphite-diamond nanowires (G-DNWs) growth from cysteamine functionalized diamond nanoparticles ( ND-Cys ) via pH induced self-assembly, which has been visualized through SEM and TEM images. Interestingly, the mechanistic aspects behind that self-assembly directed G-DNWs formation was discussed in details. Notably, above self-assembly was validated by AFM and TEM data. Further interrogations by XRD and Raman data were revealed the possible graphite sheath wrapping over DNWs. Moreover, the HR-TEM studies also verified the coexistence of less perfect sp 2 graphite layer wrapped over the sp 3 diamond carbon and the impurity channels as well. Very importantly, conductivity of hybrid G-DNWs was verified via fabrication of a single G-DNW. Wherein, the better conductivity of G-DNW portion L2 was found as 2.4 ± 1.92 × 10 −6 mS/cm and revealed its effective applicability in near future. In addition to note, temperature dependent carrier transport mechanisms and activation energy calculations were reported in details in this work. Ultimately, to demonstrate the importance of our conductivity measurements, the possible mechanism behind the electrical transport and the comparative account on electrical resistivities of carbon based materials were provided.
doi_str_mv	10.1038/s41598-017-11741-9
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Interestingly, the mechanistic aspects behind that self-assembly directed G-DNWs formation was discussed in details. Notably, above self-assembly was validated by AFM and TEM data. Further interrogations by XRD and Raman data were revealed the possible graphite sheath wrapping over DNWs. Moreover, the HR-TEM studies also verified the coexistence of less perfect sp 2 graphite layer wrapped over the sp 3 diamond carbon and the impurity channels as well. Very importantly, conductivity of hybrid G-DNWs was verified via fabrication of a single G-DNW. Wherein, the better conductivity of G-DNW portion L2 was found as 2.4 ± 1.92 × 10 −6 mS/cm and revealed its effective applicability in near future. In addition to note, temperature dependent carrier transport mechanisms and activation energy calculations were reported in details in this work. 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subjects	140/133 639/925/357 639/925/927 Coexistence Graphite Humanities and Social Sciences multidisciplinary Nanoparticles Nanotechnology Nanowires pH effects Science Science (multidisciplinary) Self-assembly
title	An Affordable Wet Chemical Route to Grow Conducting Hybrid Graphite-Diamond Nanowires: Demonstration by A Single Nanowire Device
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