We have used high-resolution transmission electron microscopy to resolve the [0001] projected basal plane structure and chirality relationships in boron nitride nanotubes. Evidence for tube growth along both 〈101̄0〉 and 〈112̄0〉 is found. Our results suggest that the 〈112̄0〉 (armchair) tubes form first. Subsequent growth can take the form of a 〈101̄0〉 (zig-zag) tube or additional armchair tubes. In both cases, the additional walls can be accommodated without the need for defect formation for circumferential tube closure. These results suggest that real boron nitride tubes may, in practice, realize their inherently high modulus and display less variation of mechanical properties than tubes comprised of carbon.
Rupini Kamat, Aaron L. Sharpe, Mihir Pendharkar, Jenny Hu, Steven J. Tran, Gregory Zaborski, M. B. Hocking, Joe Finney, Kenji Watanabe, Takashi Taniguchi, M. A. Kastner, Andrew J. Mannix, Tony F. Heinz, David Goldhaber‐Gordon
Rupini Kamat, Aaron L. Sharpe, Mihir Pendharkar, Jenny Hu, Steven J. Tran, Gregory Zaborski, M. B. Hocking, Joe Finney, Kenji Watanabe, Takashi Taniguchi, M. A. Kastner, Andrew J. Mannix, Tony F. Heinz, David Goldhaber‐Gordon
A‐Rang Jang, Seokmo Hong, Chohee Hyun, Seong In Yoon, Gwangwoo Kim, Hu Young Jeong, Tae Joo Shin, Sung O Park, Kester Wong, Sang Kyu Kwak, Noejung Park, Kwangnam Yu, Eunjip Choi, Artem Mishchenko, Freddie Withers, Konstantin ‘kostya’ Novoselov, Hyunseob Lim, Hyeon Suk Shin
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