Thermal resistance of the nanoscale constrictions between carbon nanotubes and solid substrates

Maune, Hareem; Chiu, Hsin-Ying; Bockrath, Marc

doi:10.1063/1.2219095

Cited by 76 publications

(87 citation statements)

References 26 publications

(27 reference statements)

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“…2,[5][6][7][8][9][10][11][12] This incongruity in some cases can be attributed to variations in thermal contact resistance R c , 13 a parameter that has recently received much attention, with studies on the subject reporting values that vary widely. 13,[14][15][16][17][18][19][20][21][22] For example, Maune et al perform thermometry employing electrical breakdown of CNTs to report R c values of 0.6--3.0 K·m/W, 15 whereas Tsen et al…”

mentioning

confidence: 99%

“…13,[15][16][17][18][19][20] However, many of these other studies use SEM imaging, 13,16,19,20 which is known to deposit significant amounts of carbonaceous material onto CNTs during imaging. 27 This material may reduce R c in the same manner that Pd does here.…”

mentioning

confidence: 99%

“…Similarly, other studies use a CNT manipulation-and-placement routine that explicitly calls for embedding the CNT in an acrylic adhesive. 2,28 For other studies that do not use SEM imaging or other adhesive coatings, 15,17,18 the measurements are performed at elevated temperatures, where near-field thermal radiation 29 may be playing a significant role in the transport phenomena, reducing the observed R c value. The results we report here do not use SEM imaging or adhesives, are well-characterized by TEM to exclude the possible presence of gross amounts of contaminating materials, and are carried out at relatively low temperatures, where thermal radiation effects are expected to play a diminished role in the transport.…”

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confidence: 99%

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Controlling the thermal contact resistance of a carbon nanotube heat spreader

Baloch

Voskanian

Cumings

2010

Applied Physics Letters

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The ability to tune the thermal resistance of carbon nanotube mechanical supports from insulating to conducting could permit the next generation of thermal management devices. Here, we demonstrate fabrication techniques for carbon nanotube supports that realize either weak or strong thermal coupling, selectively. Direct imaging by in-situ electron thermal microscopy shows that the thermal contact resistance of a nanotube weakly-coupled to its support is greater than 250 K·m/W and that this value can be reduced to

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Controlling the thermal contact resistance of a carbon nanotube heat spreader

Baloch

Voskanian

Cumings

2010

Applied Physics Letters

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“…We find that this configuration demands simpler fabrication, and as noted earlier, it will enable more complex geometries and larger currents than those possible for suspended nanotubes [40]. For example, to the best of our knowledge, the maximum current thus far achieved for suspended CNTs of length L is ∼ (10/L) µA [40], compared to 20 µA (L ≥ 3 µm) and 45 µA (L ≤ 1.5 µm) for surface-grown CNTs [41,42]. To verify simplicity in fabrication, we have also conducted a fabrication feasibility study, the detailed results of which will be made available elsewhere [28].…”

Section: Figmentioning

confidence: 99%

“…We usually assume a CNT current of 20 µA; noting that currents > 40 µA have been achieved experimentally [42], we perform some calculations at 35 µA in order to realistically characterize the nanotube trap sensitivity to current.…”

Section: Atomchip Designmentioning

confidence: 99%

Trapping cold atoms using surface-grown carbon nanotubes

et al. 2009

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We present a feasibility study for loading cold atomic clouds into magnetic traps created by singlewall carbon nanotubes grown directly onto dielectric surfaces. We show that atoms may be captured for experimentally sustainable nanotube currents, generating trapped clouds whose densities and lifetimes are sufficient to enable detection by simple imaging methods. This opens the way for a novel type of conductor to be used in atomchips, enabling atom trapping at sub-micron distances, with implications for both fundamental studies and for technological applications.

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Thermal and Structural Characterizations of Individual Single‐, Double‐, and Multi‐Walled Carbon Nanotubes

Pettes

Shi

2009

Adv Funct Materials

173

132

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Thermal conductance measurements of individual single‐ (S), double‐ (D), and multi‐ (M) walled (W) carbon nanotubes (CNTs) grown using thermal chemical vapor deposition between two suspended microthermometers are reported. The crystal structure of the measured CNT samples is characterized in detail using transmission electron microscopy (TEM). The thermal conductance, diameter, and chirality are all determined on the same individual SWCNT. The thermal contact resistance per unit length is obtained as 78–585 m K W−1 for three as‐grown 10–14 nm diameter MWCNTs on rough Pt electrodes, and decreases by more than 2 times after the deposition of amorphous platinum–carbon composites at the contacts. The obtained intrinsic thermal conductivity of approximately 42–48, 178–336, and 269–343 W m−1 K−1 at room‐temperature for the three MWCNT samples correlates well with TEM‐observed defects spaced approximately 13, 20, and 29 nm apart, respectively; whereas the effective thermal conductivity is found to be limited by the thermal contact resistance to be about 600 W m−1 K−1 at room temperature for the as‐grown DWCNT and SWCNT samples without the contact deposition.

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Thermal resistance of the nanoscale constrictions between carbon nanotubes and solid substrates

Cited by 76 publications

References 26 publications

Controlling the thermal contact resistance of a carbon nanotube heat spreader

Controlling the thermal contact resistance of a carbon nanotube heat spreader

Trapping cold atoms using surface-grown carbon nanotubes

Thermal and Structural Characterizations of Individual Single‐, Double‐, and Multi‐Walled Carbon Nanotubes

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