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Tuning the thermal conductivity of graphene nanoribbons by edge passivation and isotope engineering: A molecular dynamics study

机译：通过边缘钝化和石墨化来调节石墨烯纳米带的热导率同位素工程：分子动力学研究

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Using classical molecular dynamics simulation, we have studied the effect of edge-passivation by hydrogen (H-passivation) and isotope mixture (with random or superlattice distributions) on the thermal conductivity of rectangular graphene nanoribbons (GNRs) (of several nanometers in size). We find that the thermal conductivity is considerably reduced by the edge H-passivation. We also find that the isotope mixing can reduce the thermal conductivities, with the superlattice distribution giving rise to more reduction than the random distribution. These results can be useful in nanoscale engineering of thermal transport and heat management using GNRs. (C) 2010 American Institute of Physics. [doi: 10.1063/1.3491267]

机译：使用经典的分子动力学模拟，我们研究了氢的边缘钝化（H钝化）和同位素混合物（具有随机或超晶格分布）对矩形石墨烯纳米带（GNR）（几纳米大小）的热导率的影响。。我们发现边缘H钝化大大降低了热导率。我们还发现，同位素混合可以降低热导率，超晶格分布比随机分布具有更大的降低率。这些结果可用于使用GNR的热传递和热管理的纳米级工程中。（C）2010美国物理研究所。 [doi：10.1063 / 1.3491267]

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Hu, J. N.; Schiffli, S.; Vallabhaneni, A.; Ruan, X. L.; Chen, Y. P.;
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1. Tuning the thermal conductivity of graphene nanoribbons by edge passivation and isotope engineering: A molecular dynamics study [J] . Jiuning Hu, Stephen Schiffli, Ajit Vallabhaneni, Applied Physics Letters . 2010,第13期

机译：通过边缘钝化和同位素工程调节石墨烯纳米带的热导率：分子动力学研究
2. Tuning thermal conductivity of porous graphene by pore topology engineering: Comparison of non-equilibrium molecular dynamics and finite element study [J] . Ghasemi H., Rajabpour A., Akbarzadeh A. H. International Journal of Heat and Mass Transfer . 2018,第auga期

机译：通过孔拓扑工程调整多孔石墨烯的导热系数：非平衡分子动力学与有限元研究的比较
3. Thermal Conductivity and Thermal Rectification in Graphene Nanoribbons: A Molecular Dynamics Study [J] . Hu JN, Ruan XL, Chen YP Nano letters . 2009,第7期

机译：石墨烯纳米带的热导率和热精馏：分子动力学研究
4. A molecular dynamics study on thermal conductivity of armchair graphene nanoribbon [C] . Asir Intisar Khan, Ishtiaque Ahmed Navid, Fahim Ferdous Hossain, IEEE Region 10 Conference . 2016

机译：扶手椅石墨烯纳米带导热系数的分子动力学研究
5. Nanoscale studies of thermal transport: R-matrix theory and thermal transport in strained graphene nanoribbons [D] . Gunawardana, K.G. S. H. 2011

机译：传热的纳米尺度研究：R-矩阵理论和应变石墨烯纳米带中的传热
6. Effect of Tensile Strain on Thermal Conductivity in Monolayer Graphene Nanoribbons: A Molecular Dynamics Study [O] . Jianwei Zhang, Xiaodong He, Lin Yang, 2013

机译：拉伸应变对单层石墨烯纳米带导热系数的影响：分子动力学研究
7. Tuning the thermal conductivity of graphene nanoribbons by edge passivation and isotope engineering: a molecular dynamics study [O] . Hu, Jiuning, Schiffli, Stephen, Vallabhaneni, Ajit, 2010

机译：通过边缘调整石墨烯纳米带的热导率钝化和同位素工程：分子动力学研究

Tuning the thermal conductivity of graphene nanoribbons by edge passivation and isotope engineering: A molecular dynamics study

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