Diameter-dependent kinetics of activation and deactivation in carbon nanotube population growth

Carbon

Volumn 50, Issue 14, 2012, Pages 5106-5116

  Bedewy, Mostafa ^a   Meshot, Eric R ^a,b   Hart, A John ^a  

^a UNIVERSITY OF MICHIGAN   (United States)

^b IMEC   (Belgium)

Author keywords

[No Author keywords available]

Indexed keywords

CATALYTIC BEHAVIOR; CATALYTIC LIFETIME; DEACTIVATION KINETICS; EX SITU; FOREST HEIGHT; GOMPERTZ MODEL; MASS-ATTENUATION; MECHANICAL COUPLING; POPULATION GROWTH; RELATIVE SLIP; S-SHAPED; SELF-SIMILAR; STRUCTURAL DEFECT; SYNCHROTRON X-RAY SCATTERING; VERTICALLY ALIGNED CARBON NANOTUBE;

CARBON NANOTUBES; CHEMICAL REACTIONS; CHEMICAL VAPOR DEPOSITION; FORESTRY; KINETICS; MECHANICAL PROPERTIES; POPULATION STATISTICS; VAN DER WAALS FORCES;

GROWTH KINETICS;

ACTIVATION ENERGY; BIOLOGICAL POPULATIONS; CARBON FIBERS; CHEMICAL REACTIONS; DEPOSITION; FORESTRY; MECHANICAL PROPERTIES;

EID: 84865491202     PISSN: 00086223     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.carbon.2012.06.051     Document Type: Article

References (74)

1. C.T. Campbell, S.C. Parker, and D.E. Starr The effect of size-dependent nanoparticle energetics on catalyst sintering Science 298 5594 2002 811 814 (Pubitemid 35231530)
2. R.M. Rioux, H. Song, J.D. Hoefelmeyer, P. Yang, and G.A. Somorjai High-surface-area catalyst design: synthesis, characterization, and reaction studies of platinum nanoparticles in mesoporous SBA-15 silica J Phys Chem B 109 6 2005 2192 2202
3. G. Jones, J.G. Jakobsen, S.S. Shim, J. Kleis, M.P. Andersson, and J. Rossmeisl First principles calculations and experimental insight into methane steam reforming over transition metal catalysts J Catal 259 1 2008 147 160
4. A. Moisala, A.G. Nasibulin, and E.I. Kauppinen The role of metal nanoparticles in the catalytic production of single-walled carbon nanotubes - a review J Phys-Condens Matter 15 42 2003 S3011-35
5. V. Schmidt, J.V. Wittemann, S. Senz, and U. Goesele Silicon nanowires: a review on aspects of their growth and their electrical properties Adv Mater 21 25-26 2009 2681 2702
6. Y.Y. Wu, R. Fan, and P.D. Yang Block-by-block growth of single-crystalline Si/SiGe superlattice nanowires Nano Lett 2 2 2002 83 86 (Pubitemid 135706268)
7. J. Kikkawa, Y.Ohno, and S. Takeda Growth rate of silicon nanowires Appl Phys Lett 86 12 2005 123109 123113
8. S.M. Kim, C.L. Pint, P.B. Amama, D.N. Zakharov, R.H. Hauge, and B. Maruyama Evolution in catalyst morphology leads to carbon nanotube growth termination J Phys Chem Lett 1 6 2010 918 922
9. Meshot ER, Verploegen EA, Bedewy M, Tawfick S, Woll AR, Green K, et al. High-speed in situ X-ray scattering of carbon nanotube film nucleation and self-organization, Acs Nano 2012;6(6):5091-5101. doi:10.1021/nn300758f.
10. P.B. Amama, C.L. Pint, L. McJilton, S.M. Kim, E.A. Stach, and P.T. Murray Role of water in super growth of single-walled carbon nanotube carpets Nano Lett 9 1 2009 Jan 44 49
11. Hasegawa K, Noda S. Diameter increase in millimeter-tall vertically aligned single-walled carbon nanotubes during growth. Appl Phys Expr 2010;3(4):045103-3.
12. K. Hasegawa, and S. Noda Millimeter-tall single-walled carbon nanotubes rapidly grown with and without water Acs Nano 5 2 2011 975 984
13. Bedewy M, Meshot ER, Reinker MJ, Hart AJ. Population growth dynamics of carbon nanotubes. Acs Nano 2011;5(11):8974-89.
14. D.B. Geohegan, A.A. Puretzky, J.J. Jackson, C.M. Rouleau, G. Eres, and K.L. More Flux-dependent growth kinetics and diameter selectivity in single-wall carbon nanotube arrays Acs Nano 5 10 2011 Oct 8311 8321
15. V. Sazonova, Y. Yaish, H. Ustunel, D. Roundy, T.A. Arias, and P.L. McEuen A tunable carbon nanotube electromechanical oscillator Nature 431 7006 2004 Sep 284 287 (Pubitemid 39265658)
16. Majumder M, Chopra N, Andrews R, Hinds BJ. Nanoscale hydrodynamics - Enhanced flow in carbon nanotubes. Nature 2005;438(7064):44-1.
17. K. Jensen, J. Weldon, H. Garcia, and A. Zettl Nanotube radio Nano Lett 7 11 2007 3508 3511 (Pubitemid 350216054)
18. C. Rutherglen, and P. Burke Carbon nanotube radio Nano Lett 7 2007 3296 3299 (Pubitemid 350216019)
19. S. Tawfick, K. O'Brien, and A.J. Hart Flexible high-conductivity carbon-nanotube interconnects made by rolling and printing Small 5 21 2009 Nov 2467 2473
20. B.Q. Wei, R. Vajtai, and P.M. Ajayan Reliability and current carrying capacity of carbon nanotubes Appl Phys Lett 79 8 2001 1172 1174 (Pubitemid 33596872)
21. S. Berber, Y.K. Kwon, and D. Tomanek Unusually high thermal conductivity of carbon nanotubes Phys Rev Lett 84 20 2000 4613 4616
22. N. Halonen, A. Rautio, A.R. Leino, T. Kyllonen, G. Toth, and J. Lappalainen Three-dimensional carbon nanotube scaffolds as particulate filters and catalyst support membranes Acs Nano 4 4 2010 2003 2008
23. 2 gas detection based on carbon nanotube thin films Appl Phys Lett 82 6 2003 Feb 961 963
24. J. Li, Y.J. Lu, Q. Ye, M. Cinke, J. Han, and M. Meyyappan Carbon nanotube sensors for gas and organic vapor detection Nano Lett 3 7 2003 929 933 (Pubitemid 37161874)
25. A. Modi, N. Koratkar, E. Lass, B.Q. Wei, and P.M. Ajayan Miniaturized gas ionization sensors using carbon nanotubes Nature 424 6945 2003 Jul 171 174 (Pubitemid 36858681)
26. D.W.H. Fam, A. Palaniappan, A.I.Y. Tok, B. Liedberg, and S.M. Moochhala A review on technological aspects influencing commercialization of carbon nanotube sensors Sens Actuat B-Chem 157 1 2011 Sep 1 7
27. H. Qian, E.S. Greenhalgh, M.S.P. Shaffer, and A. Bismarck Carbon nanotube-based hierarchical composites: a review J Mater Chem 20 23 2010 4751 4762
28. M. Zhang, S.L. Fang, A.A. Zakhidov, S.B. Lee, A.E. Aliev, and C.D. Williams Strong, transparent, multifunctional, carbon nanotube sheets Science 309 5738 2005 1215 1219 (Pubitemid 41170909)
29. M. Zhang, K.R. Atkinson, and R.H. Baughman Multifunctional carbon nanotube yarns by downsizing an ancient technology Science 306 5700 2004 1358 1361 (Pubitemid 39532509)
30. A.A. Kuznetsov, A.F. Fonseca, R.H. Baughman, and A.A. Zakhidov Structural model for dry-drawing of sheets and yarns from carbon nanotube forests Acs Nano 5 2 2011 985 993
31. F. Cervantes-Sodi, T.P. McNicholas, J.G. Simmons, J. Liu, G. Csanyi, and A.C. Ferrari Viscous state effect on the activity of Fe nanocatalysts Acs Nano 4 11 2010 6950 6956
32. E.R. Meshot, D.L. Plata, S. Tawfick, Y.Y. Zhang, E.A. Verploegen, and A.J. Hart Engineering vertically aligned carbon nanotube growth by decoupled thermal treatment of precursor and catalyst Acs Nano 3 9 2009 2477 2486
33. R. Rao, D. Liptak, T. Cherukuri, B.I. Yakobson, and B. Maruyama In situ evidence for chirality-dependent growth rates of individual carbon nanotubes Nat Mater 11 3 2012 213 216
34. D.H. Kim, H.S. Jang, C.D. Kim, D.S. Cho, H.S. Yang, and H.D. Kang Dynamic growth rate behavior of a carbon nanotube forest characterized by in situ optical growth monitoring Nano Lett 3 6 2003 863 865
35. Dell'Acqua-Bellavitis L, Ballard J, Ajayan P, Siegel R. Kinetics for the synthesis reaction of aligned carbon nanotubes: a study based on in situ diffractography. Nano Lett 2004;4(9):1613-20. (Pubitemid 39297433)
36. A.A. Puretzky, D.B. Geohegan, S. Jesse, I.N. Ivanov, and G. Eres In situ measurements and modeling of carbon nanotube array growth kinetics during chemical vapor deposition Appl Phys A-Mater Sci Process 81 2 2005 223 240 (Pubitemid 40683694)
37. A.J. Hart, L. van Laake, and A.H. Slocum Desktop growth of carbon-nanotube monoliths with in situ optical imaging Small 3 5 2007 May 772 777 (Pubitemid 46750426)
38. Puretzky AA, Eres G, Rouleau CM, Ivanov IN, Geohegan DB. Real-time imaging of vertically aligned carbon nanotube array growth kinetics. Nanotechnology 2008;19(5):055605-5.
39. Meshot ER, Hart AJ. Abrupt self-termination of vertically aligned carbon nanotube growth. Appl Phys Lett 2008;92(11):113107-3.
40. M. Lin, J.P.Y. Tan, C. Boothroyd, K.P. Loh, E.S. Tok, and Y.L. Foo Direct observation of single-walled carbon nanotube growth at the atomistic scale Nano Lett 6 3 2006 Mar 449 452
41. M. Picher, E. Anglaret, R. Arenal, and V. Jourdain Self-deactivation of single-walled carbon nanotube growth studied by in situ raman measurements Nano Lett 9 2 2009 542 547
42. Chiashi S, Kohno M, Takata Y, Maruyama S. Localized synthesis of single-walled carbon nanotubes on silicon substrates by a laser heating catalytic CVD. In: Hess WP, Herman PR, Bauerle D, Koinuma H, editors. Cola'05: 8th international conference on laser ablation, 2007, p. 155-8.
43. A. Li-Pook-Than, J. Lefebvre, and P. Finnie Phases of carbon nanotube growth and population evolution from in situ raman spectroscopy during chemical vapor deposition J Phys Chem C 114 25 2010 11018 11025
44. N. Latorre, E. Romeo, F. Cazana, T. Ubieto, C. Royo, and J.J. Villacampa Carbon nanotube growth by catalytic chemical vapor deposition: a phenomenological kinetic model J Phys Chem C 114 11 2010 4773 4782
45. M.S. Dresselhaus, G. Dresselhaus, R. Saito, and A. Jorio Raman spectroscopy of carbon nanotubes Phys Rep-Rev Section Phys Lett 409 2 2005 47 99 (Pubitemid 40317386)
46. F. Ding, A.R. Harutyunyan, and B.I. Yakobson Dislocation theory of chirality-controlled nanotube growth Proc Natl Acad Sci USA 106 8 2009 2506 2509
47. B.N. Wang, R.D. Bennett, E. Verploegen, A.J. Hart, and R.E. Cohen Quantitative characterization of the morphology of multiwall carbon nanotube films by small-angle X-ray scattering J Phys Chem C 111 16 2007 5859 5865 (Pubitemid 46759250)
48. Bedewy M, Meshot E, Guo H, Verploegen E, Lu W, Hart A. Collective mechanism for the evolution and self-termination of vertically aligned carbon nanotube growth. J Phys Chem C 2009;113(48):20576-82.
49. Meshot E, Bedewy M, Lyons K, Woll A, Juggernauth K, Tawfick S, et al. Measuring the lengthening kinetics of aligned nanostructures by spatiotemporal correlation of height and orientation. Nanoscale 2010;2(6):896-900.
50. Hubbell JH, Seltzer SM. Tables of X-ray mass attenuation coefficients and mass energy-absorption coefficients from 1 keV to 20 MeV for elements Z = 1 to 92 and 48 additional substances of dosimetric interest. NIST Standard Reference, Database 126 2004.
51. C.P. Winsor The Gompertz curve as a growth curve Proc Natl Acad Sci USA 18 1932 1 8
52. N. Lopez, T.V.W. Janssens, B.S. Clausen, Y. Xu, M. Mavrikakis, and T. Bligaard On the origin of the catalytic activity of gold nanoparticles for low-temperature CO oxidation J Catal 223 1 2004 Apr 1 232 235
53. M.C. Saint-Lager, I. Laoufi, A. Bailly, O. Robach, S. Garaudee, and P. Dolle Catalytic properties of supported gold nanoparticles: new insights into the size-activity relationship gained from in operando measurements Faraday Discuss 152 2011 253 265
54. C. Langhammer, V.P. Zhdanov, I. Zoric, and B. Kasemo Size-dependent kinetics of hydriding and dehydriding of Pd nanoparticles Phys Rev Lett 104 13 2010 Apr 1355024
55. S. Helveg, C. Lopez-Cartes, J. Sehested, P.L. Hansen, B.S. Clausen, and J.R. Rostrup-Nielsen Atomic-scale imaging of carbon nanofibre growth Nature 427 6973 2004 426 429 (Pubitemid 38168491)
56. F. Ding, K. Bolton, and A. Rosen Nucleation and growth of single-walled carbon nanotubes: a molecular dynamics study J Phys Chem B 108 45 2004 17369 17377
57. Raty JY, Gygi F, Galli G. Growth of carbon nanotubes on metal nanoparticles: a microscopic mechanism from ab initio molecular dynamics simulations. Phys Rev Lett 2005;95(9):096103-4.
58. H.W. Zhu, K. Suenaga, A. Hashimoto, K. Urita, K. Hata, and S. Iijima Atomic-resolution imaging of the nucleation points of single-walled carbon nanotubes Small 1 12 2005 1180 1183 (Pubitemid 43951826)
59. Futaba DN, Hata K, Yamada T, Mizuno K, Yumura M, Iijima S. Kinetics of water-assisted single-walled carbon nanotube synthesis revealed by a time-evolution analysis. Phys Rev Lett. 2005;95(5):056104-4.
60. Harutyunyan AR, Mora E, Tokune T, Bolton K, Rosen A, Jiang A, et al. Hidden features of the catalyst nanoparticles favorable for single-walled carbon nanotube growth. Appl Phys Lett 2007; 90(16):163120-3.
61. M. Stadermann, S.P. Sherlock, J.-B. In, F. Fornasiero, H.G. Park, and A.B. Artyukhin Mechanism and kinetics of growth termination in controlled chemical vapor deposition growth of multiwall carbon nanotube arrays Nano Lett 9 2 2009 738 744
62. J.H. Han, R.A. Graff, B. Welch, C.P. Marsh, R. Franks, and M.S. Strano A mechanochemical model of growth termination in vertical carbon nanotube forests Acs Nano 2 1 2008 53 60 (Pubitemid 351585764)
63. J.N. Israelachvili Intermolecular and surface forces 1992 Academic Press Second ed
64. De Volder MFL, Vidaud DO, Meshot ER, Tawfick S, Hart AJ. Self-similar organization of arrays of individual carbon nanotubes and carbon nanotube micropillars. Microelectron Eng 2010;87(5-8):1233-8.
65. Y.V. Shtogun, and L.M. Woods Many-body van der Waals interactions between graphitic nanostructures J Phys Chem Lett 1 9 2010 1356 1362
66. Li CX, Liu YL, Yao XF, Ito M, Noguchi T, Zheng QS. Interfacial shear strengths between carbon nanotubes. Nanotechnology 2010; 21(11):115704-5.
67. B. Bhushan, and X. Ling Adhesion and friction between individual carbon nanotubes measured using force-versus-distance curves in atomic force microscopy Phys Rev B 78 4 2008 045429-9
68. A.J. Hart, and A.H. Slocum Force output, control of film structure, and microscale shape transfer by carbon nanotube growth under mechanical pressure Nano Lett 6 6 2006 Jun 1254 1260 (Pubitemid 44013491)
69. Einarsson E, Shiozawa H, Kramberger C, Rümmeli MH, Grüneis A, Pichler T, et al. Revealing the small-bundle internal structure of vertically aligned single-walled carbon nanotube films. J Phys Chem C 2007;111(48):17861-4. (Pubitemid 350279921)
70. E. Verploegen, A.J. Hart, M. De Volder, S. Tawfick, K.-K. Chia, and R.E. Cohen Non-destructive characterization of structural hierarchy within aligned carbon nanotube assemblies J Appl Phys 109 9 2011 094316-5
71. Zhang RF, Wen Q, Qian WZ, Su DS, Zhang Q, Wei F. Superstrong ultra long carbon nanotubes for mechanical energy storage. Adv Mater 2011;23(30):3387-3391.
72. Akoshima M, Hata K, Futaba D, Mizuno K, Baba T, Yumura M. Thermal diffusivity of single-walled carbon nanotube forest measured by laser flash method. Jpn J Appl Phys 2009;48:05EC07-6.
73. Duong H, Yamamoto N, Papavassiliou D, Maruyama S, Wardle B. Inter-carbon nanotube contact in thermal transport of controlled-morphology polymer nanocomposites. Nanotechnology 2009;20(15):155702-10.
74. T. Tong, Y. Zhao, L. Delzeit, A. Kashani, M. Meyyappan, and A. Majumdar Dense, vertically aligned multiwalled carbon nanotube arrays as thermal interface materials IEEE Trans Comp Packaging Technol 30 1 2007 92 100 (Pubitemid 46591058)