Chemically driven carbon-nanotube-guided thermopower waves

BibTex:
Research areas:	Uncategorized	Year:	2010
Type of Publication:	Article
Authors:	Wonjoon Choi, Joel T. Abrahamson Seunghyun Hong
Journal:	Nature Materials	Volume:	9
Number:	5	Pages:	423-429
Month:	MAY 2010

@article{RefWorks:933, author = "Wonjoon Choi,Seunghyun Hong,Joel T. Abrahamson,Jae-Hee Han,Changsik Song,Nitish Nair,Seunghyun Baik,Michael S. Strano", 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 10(4) times the bulk value, propagating faster than 2 m s(-1), with an effective thermal conductivity of 1.28 +/- 0.2 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.", isbn = "1476-1122", journal = "Nature Materials", month = "MAY 2010", note = "PT: J; TC: 21; UT: WOS:000276953500023", number = "5", pages = "423-429", title = "{C}hemically driven carbon-nanotube-guided thermopower waves", volume = "9", year = "2010", }
Note:	PT: J; TC: 21; UT: WOS:000276953500023
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 10(4) times the bulk value, propagating faster than 2 m s(-1), with an effective thermal conductivity of 1.28 +/- 0.2 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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