Nanoengineering heat transfer performance at carbon nanotube interfaces.

Carbon nanotubes are superb materials for nanoscale thermal management and phononic devices applications, due to their extremely high thermal conductivity (3000-6600 W/mK) and quasi-one-dimensional geometry. However, the presence of interfaces between individual carbon nanotubes as found widely in nanocomposites, nanoelectronics, and nanodevices severely limits their performance for larger scale applications. Solving this issue requires a deep understanding of the heat transfer mechanism at this nanoscale interface between low-dimensional structures, where conventional models developed for interfaces in bulk materials do not apply. Here we address this challenge through a bottom-up approach based on atomistic simulations. We demonstrate that the huge thermal resistance of carbon nanotube junctions can be significantly improved through modifying the molecular structure at the interface to enhance both the matching of phonon spectra and phonon mode coupling. Specifically, two approaches based on polymer wrapping and metal coatings are investigated here and have shown to improve both the structural stability and interfacial thermal conductivity of carbon nanotube junctions. By properly designing the interface molecular structure between individual carbon nanotubes, significant performance gains up to a factor of 4 can be achieved. These results pave the way for future designs of thermal management networks and phononic devices with thermally transparent and structurally stable interfaces.

[1]  M. Buehler,et al.  Strain controlled thermomutability of single-walled carbon nanotubes , 2009, Nanotechnology.

[2]  M. Buehler,et al.  Hierarchical nanostructures are crucial to mitigate ultrasmall thermal point loads. , 2009, Nano letters.

[3]  F Cleri,et al.  Turning carbon nanotubes from exceptional heat conductors into insulators. , 2009, Physical review letters.

[4]  Markus J Buehler,et al.  Deformation and failure of protein materials in physiologically extreme conditions and disease. , 2009, Nature materials.

[5]  A. Broekhuis,et al.  Cross-linking of multiwalled carbon nanotubes with polymeric amines , 2008 .

[6]  C. N. Lau,et al.  Superior thermal conductivity of single-layer graphene. , 2008, Nano letters.

[7]  J. Brink,et al.  Doping graphene with metal contacts. , 2008, Physical review letters.

[8]  Claudio Toniolo,et al.  Energy transport in peptide helices , 2007, Proceedings of the National Academy of Sciences.

[9]  Jeffrey C Grossman,et al.  Nanomechanical energy transfer and resonance effects in single-walled carbon nanotubes. , 2007, Physical review letters.

[10]  A. Majumdar,et al.  Thermoelectricity in Molecular Junctions , 2007, Science.

[11]  P. Ajayan,et al.  Multisegmented one-dimensional hybrid structures of carbon nanotubes and metal nanowires , 2006 .

[12]  Wanlin Guo,et al.  Structural transformation of partially confined copper nanowires inside defected carbon nanotubes , 2006, Nanotechnology.

[13]  E. Pop,et al.  Electrical and thermal transport in metallic single-wall carbon nanotubes on insulating substrates , 2006, cond-mat/0609075.

[14]  Jennifer R. Lukes,et al.  Interfacial thermal resistance between carbon nanotubes: Molecular dynamics simulations and analytical thermal modeling , 2006 .

[15]  Fumihito Arai,et al.  Towards nanotube linear servomotors , 2006, IEEE Transactions on Automation Science and Engineering.

[16]  P. Ajayan,et al.  Carbon Nanotubes as High-Pressure Cylinders and Nanoextruders , 2006, Science.

[17]  Ravi Prasher,et al.  Predicting the thermal resistance of nanosized constrictions. , 2005, Nano letters.

[18]  J. Murthy,et al.  Percolating conduction in finite nanotube networks. , 2005, Physical review letters.

[19]  Jacqueline A. Cutroni,et al.  Sacrificial bonds and hidden length dissipate energy as mineralized fibrils separate during bone fracture , 2005, Nature materials.

[20]  A. Dalton,et al.  Hierarchical Self‐Assembly of Peptide‐Coated Carbon Nanotubes , 2004 .

[21]  P. McEuen,et al.  A tunable carbon nanotube electromechanical oscillator , 2004, Nature.

[22]  Simon Scheuring,et al.  Watching the photosynthetic apparatus in native membranes. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[23]  Scott T. Huxtable,et al.  Interfacial heat flow in carbon nanotube suspensions , 2003, Nature materials.

[24]  A. Nitzan,et al.  Thermal conductance through molecular wires , 2003, physics/0306187.

[25]  A. Majumdar,et al.  Nanoscale thermal transport , 2003, Journal of Applied Physics.

[26]  Donald W. Brenner,et al.  A second-generation reactive empirical bond order (REBO) potential energy expression for hydrocarbons , 2002 .

[27]  E. Grulke,et al.  Anomalous thermal conductivity enhancement in nanotube suspensions , 2001 .

[28]  Hongjie Dai,et al.  Formation of metal nanowires on suspended single-walled carbon nanotubes , 2000 .

[29]  A. Kidera,et al.  Vibrational energy transfer in a protein molecule. , 2000, Physical review letters.

[30]  Zettl,et al.  Low-friction nanoscale linear bearing realized from multiwall carbon nanotubes , 2000, Science.

[31]  W. Goddard,et al.  Thermal conductivity of carbon nanotubes , 2000 .

[32]  A. Zettl,et al.  Thermal conductivity of single-walled carbon nanotubes , 1998 .

[33]  F. Müller-Plathe A simple nonequilibrium molecular dynamics method for calculating the thermal conductivity , 1997 .

[34]  Steve Plimpton,et al.  Fast parallel algorithms for short-range molecular dynamics , 1993 .

[35]  R. Pohl,et al.  Thermal boundary resistance , 1989 .

[36]  Foiles,et al.  Embedded-atom-method functions for the fcc metals Cu, Ag, Au, Ni, Pd, Pt, and their alloys. , 1986, Physical review. B, Condensed matter.

[37]  M. Dresselhaus,et al.  Carbon nanotubes : synthesis, structure, properties, and applications , 2001 .