Phonon Engineering in Carbon Nanotubes by Controlling Defect Concentration

Outstanding thermal transport properties of carbon nanotubes (CNTs) qualify them as possible candidates to be used as thermal management units in electronic devices. However, significant variations in the thermal conductivity (κ) measurements of individual CNTs restrict their utilizations for this p...

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Veröffentlicht in:	Nano letters 2011-11, Vol.11 (11), p.4971-4977
Hauptverfasser:	Sevik, Cem, Sevinçli, Hâldun, Cuniberti, Gianaurelio, Çağın, Tahir
Format:	Artikel
Sprache:	eng
Schlagworte:	Carbon nanotubes Chairs Computer Simulation Condensed matter: structure, mechanical and thermal properties Cross-disciplinary physics: materials science rheology Defects Exact sciences and technology Graphene Lattice dynamics Materials science Micrometers Models, Chemical Nanoscale materials and structures: fabrication and characterization Nanostructure Nanotubes Nanotubes, Carbon - chemistry Nanotubes, Carbon - ultrastructure Particle Size Phonons Phonons in low-dimensional structures and small particles Physics Scattering Thermal Conductivity Thermal properties of condensed matter Thermal properties of small particles, nanocrystals, nanotubes Transport properties Vibration
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creator	Sevik, Cem Sevinçli, Hâldun Cuniberti, Gianaurelio Çağın, Tahir
description	Outstanding thermal transport properties of carbon nanotubes (CNTs) qualify them as possible candidates to be used as thermal management units in electronic devices. However, significant variations in the thermal conductivity (κ) measurements of individual CNTs restrict their utilizations for this purpose. In order to address the possible sources of this large deviation and to propose a route to solve this discrepancy, we systematically investigate the effects of varying concentrations of randomly distributed multiple defects (single and double vacancies, Stone–Wales defects) on the phonon transport properties of armchair and zigzag CNTs with lengths ranging between a few hundred nanometers to several micrometers, using both nonequilibrium molecular dynamics and atomistic Green’s function methods. Our results show that, for both armchair and zigzag CNTs, κ converges nearly to the same values with different types of defects, at all lengths considered in this study. On the basis of the detailed mean free path analysis, this behavior is explained with the fact that intermediate and high frequency phonons are filtered out by defect scattering, while low frequency phonons are transmitted quasi-ballistically even for several micrometer long CNTs. Furthermore, an analysis of variances in κ for different defect concentrations indicates that defect scattering at low defect concentrations could be the source of large experimental variances, and by taking advantage of the possibility to create a controlled concentration of defects by electron or ion irradiation, it is possible to standardize κ with minimizing the variance. Our results imply the possibility of phonon engineering in nanostructured graphene based materials by controlling the defect concentration.
doi_str_mv	10.1021/nl2029333
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However, significant variations in the thermal conductivity (κ) measurements of individual CNTs restrict their utilizations for this purpose. In order to address the possible sources of this large deviation and to propose a route to solve this discrepancy, we systematically investigate the effects of varying concentrations of randomly distributed multiple defects (single and double vacancies, Stone–Wales defects) on the phonon transport properties of armchair and zigzag CNTs with lengths ranging between a few hundred nanometers to several micrometers, using both nonequilibrium molecular dynamics and atomistic Green’s function methods. Our results show that, for both armchair and zigzag CNTs, κ converges nearly to the same values with different types of defects, at all lengths considered in this study. On the basis of the detailed mean free path analysis, this behavior is explained with the fact that intermediate and high frequency phonons are filtered out by defect scattering, while low frequency phonons are transmitted quasi-ballistically even for several micrometer long CNTs. Furthermore, an analysis of variances in κ for different defect concentrations indicates that defect scattering at low defect concentrations could be the source of large experimental variances, and by taking advantage of the possibility to create a controlled concentration of defects by electron or ion irradiation, it is possible to standardize κ with minimizing the variance. 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On the basis of the detailed mean free path analysis, this behavior is explained with the fact that intermediate and high frequency phonons are filtered out by defect scattering, while low frequency phonons are transmitted quasi-ballistically even for several micrometer long CNTs. Furthermore, an analysis of variances in κ for different defect concentrations indicates that defect scattering at low defect concentrations could be the source of large experimental variances, and by taking advantage of the possibility to create a controlled concentration of defects by electron or ion irradiation, it is possible to standardize κ with minimizing the variance. 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However, significant variations in the thermal conductivity (κ) measurements of individual CNTs restrict their utilizations for this purpose. In order to address the possible sources of this large deviation and to propose a route to solve this discrepancy, we systematically investigate the effects of varying concentrations of randomly distributed multiple defects (single and double vacancies, Stone–Wales defects) on the phonon transport properties of armchair and zigzag CNTs with lengths ranging between a few hundred nanometers to several micrometers, using both nonequilibrium molecular dynamics and atomistic Green’s function methods. Our results show that, for both armchair and zigzag CNTs, κ converges nearly to the same values with different types of defects, at all lengths considered in this study. 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subjects	Carbon nanotubes Chairs Computer Simulation Condensed matter: structure, mechanical and thermal properties Cross-disciplinary physics: materials science rheology Defects Exact sciences and technology Graphene Lattice dynamics Materials science Micrometers Models, Chemical Nanoscale materials and structures: fabrication and characterization Nanostructure Nanotubes Nanotubes, Carbon - chemistry Nanotubes, Carbon - ultrastructure Particle Size Phonons Phonons in low-dimensional structures and small particles Physics Scattering Thermal Conductivity Thermal properties of condensed matter Thermal properties of small particles, nanocrystals, nanotubes Transport properties Vibration
title	Phonon Engineering in Carbon Nanotubes by Controlling Defect Concentration
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