Chemically driven carbon-nanotube-guided thermopower waves

Wonjoon Choi; Seunghyun Hong; Joel T. Abrahamson; Jae Hee Han; Changsik Song; Nitish Nair; Seunghyun Baik; Michael S. Strano

doi:10.1038/nmat2714

Chemically driven carbon-nanotube-guided thermopower waves

Wonjoon Choi, Seunghyun Hong, Joel T. Abrahamson, Jae Hee Han, Changsik Song, Nitish Nair, Seunghyun Baik, Michael S. Strano

Research output: Contribution to journal › Article › peer-review

179 Scopus citations

Abstract

Theoretical calculations predict that by coupling an exothermic chemical reaction with a nanotube or nanowire possessing a high axial thermal conductivity, a self-propagating reactive wave can be driven along its length. Herein, such waves are realized using a 7-nm cyclotrimethylene trinitramine annular shell around a multiwalled carbon nanotube and are amplified by more than 10⁴ times the bulk value, propagating faster than 2 m s ^-1, with an effective thermal conductivity of 1.2±80.2 kW m^-1 K 1 at 2,860 K. This wave produces a concomitant electrical pulse of disproportionately high specific power, as large as 7 kW kg^-1, which we identify as a thermopower wave. Thermally excited carriers flow in the direction of the propagating reaction with a specific power that scales inversely with system size. The reaction also evolves an anisotropic pressure wave of high total impulse per mass (300 N s kg^-1). Such waves of high power density may find uses as unique energy sources.

Original language	British English
Pages (from-to)	423-429
Number of pages	7
Journal	Nature Materials
Volume	9
Issue number	5
DOIs	https://doi.org/10.1038/nmat2714
State	Published - May 2010

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title = "Chemically driven carbon-nanotube-guided thermopower waves",

abstract = "Theoretical calculations predict that by coupling an exothermic chemical reaction with a nanotube or nanowire possessing a high axial thermal conductivity, a self-propagating reactive wave can be driven along its length. Herein, such waves are realized using a 7-nm cyclotrimethylene trinitramine annular shell around a multiwalled carbon nanotube and are amplified by more than 104 times the bulk value, propagating faster than 2 m s -1, with an effective thermal conductivity of 1.2±80.2 kW m-1 K 1 at 2,860 K. This wave produces a concomitant electrical pulse of disproportionately high specific power, as large as 7 kW kg-1, which we identify as a thermopower wave. Thermally excited carriers flow in the direction of the propagating reaction with a specific power that scales inversely with system size. The reaction also evolves an anisotropic pressure wave of high total impulse per mass (300 N s kg-1). Such waves of high power density may find uses as unique energy sources.",

author = "Wonjoon Choi and Seunghyun Hong and Abrahamson, {Joel T.} and Han, {Jae Hee} and Changsik Song and Nitish Nair and Seunghyun Baik and Strano, {Michael S.}",

note = "Funding Information: This work was supported primarily by a grant to M.S.S. from the Air Force Office of Scientific Research and from an NSF Career Award also to M.S.S. S.B. appreciates support by the WCU (World Class University) programme through the Korea Science and Engineering Foundation funded by the Ministry of Education, Science and Technology, Korea (R31-2008-000-10029-0). J.T.A. and W.J.C. acknowledge fellowship support from the National Science Foundation and ILJU, respectively. J-H.H. acknowledges support from the Korea Research Foundation (MOEHRD, KRF-2006-214-D00117). We acknowledge T. M. Swager for help with TNA extraction.",

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doi = "10.1038/nmat2714",

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AU - Choi, Wonjoon

AU - Hong, Seunghyun

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AU - Han, Jae Hee

AU - Song, Changsik

AU - Nair, Nitish

AU - Baik, Seunghyun

AU - Strano, Michael S.

N1 - Funding Information: This work was supported primarily by a grant to M.S.S. from the Air Force Office of Scientific Research and from an NSF Career Award also to M.S.S. S.B. appreciates support by the WCU (World Class University) programme through the Korea Science and Engineering Foundation funded by the Ministry of Education, Science and Technology, Korea (R31-2008-000-10029-0). J.T.A. and W.J.C. acknowledge fellowship support from the National Science Foundation and ILJU, respectively. J-H.H. acknowledges support from the Korea Research Foundation (MOEHRD, KRF-2006-214-D00117). We acknowledge T. M. Swager for help with TNA extraction.

PY - 2010/5

Y1 - 2010/5

N2 - Theoretical calculations predict that by coupling an exothermic chemical reaction with a nanotube or nanowire possessing a high axial thermal conductivity, a self-propagating reactive wave can be driven along its length. Herein, such waves are realized using a 7-nm cyclotrimethylene trinitramine annular shell around a multiwalled carbon nanotube and are amplified by more than 104 times the bulk value, propagating faster than 2 m s -1, with an effective thermal conductivity of 1.2±80.2 kW m-1 K 1 at 2,860 K. This wave produces a concomitant electrical pulse of disproportionately high specific power, as large as 7 kW kg-1, which we identify as a thermopower wave. Thermally excited carriers flow in the direction of the propagating reaction with a specific power that scales inversely with system size. The reaction also evolves an anisotropic pressure wave of high total impulse per mass (300 N s kg-1). Such waves of high power density may find uses as unique energy sources.

AB - Theoretical calculations predict that by coupling an exothermic chemical reaction with a nanotube or nanowire possessing a high axial thermal conductivity, a self-propagating reactive wave can be driven along its length. Herein, such waves are realized using a 7-nm cyclotrimethylene trinitramine annular shell around a multiwalled carbon nanotube and are amplified by more than 104 times the bulk value, propagating faster than 2 m s -1, with an effective thermal conductivity of 1.2±80.2 kW m-1 K 1 at 2,860 K. This wave produces a concomitant electrical pulse of disproportionately high specific power, as large as 7 kW kg-1, which we identify as a thermopower wave. Thermally excited carriers flow in the direction of the propagating reaction with a specific power that scales inversely with system size. The reaction also evolves an anisotropic pressure wave of high total impulse per mass (300 N s kg-1). Such waves of high power density may find uses as unique energy sources.

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Chemically driven carbon-nanotube-guided thermopower waves

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