Wall "thickness" effects on Raman spectrum shift, thermal conductivity, and Young's modulus of single walled nanotubes
Abstract
We theoretically demonstrate that at a finite temperature, an effective wall thickness of a single walled carbon nanotube (SWNT) should be W=Ws+Wd, where Ws is the static thickness defined as the extension of the outmost electronic orbit and Wd the dynamic thickness due to thermal vibration of atoms. Both molecular simulations and a theoretical analysis show that Wd is proportional to T. We find that the increase of dynamic thickness with temperature is the main mechanism of Raman spectrum shift. The introduction of dynamic thickness changes some conclusions about the Young's modulus and reduces the values of thermal conductivity.
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