Giant-block twist grain boundary smectic phases

J. Fernsler; L. Hough; R. F. Shao; J. E. Maclennan; L. Navailles; M. Brunet; N. V. Madhusudana; O. Mondain-Monval; C. Boyer; J. Zasadzinski; J. A. Rego; D. M. Walba; N. A. Clark

doi:10.1073/pnas.0500664102

Giant-block twist grain boundary smectic phases

J. Fernsler, L. Hough, R. F. Shao, J. E. Maclennan, L. Navailles, M. Brunet, N. V. Madhusudana, O. Mondain-Monval, C. Boyer, J. Zasadzinski, J. A. Rego, D. M. Walba, N. A. Clark

Chemical Engineering and Materials Science

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Abstract

Study of a diverse set of chiral smectic materials, each of which has twist grain boundary (TGB) phases over a broad temperature range and exhibits grid patterns in the Grandjean textures of the TGB helix, shows that these features arise from a common structure: "giant" smectic blocks of planar layers of thickness I_b > 200 nm terminated by GBs that are sharp, mediating large angular jumps in layer orientation between blocks (60° < Δ ;< 90°), and lubricating the thermal contraction of the smectic layers within the blocks. This phenomenology is well described by basic theoretical models applicable in the limit that the ratio of molecular tilt penetration length-to-layer coherence length is large, and featuring GBs in which smectic ordering is weak, approaching thin, melted (nematic-like) walls. In this limit the energy cost of change of the block size is small, leading to a wide variation of block dimension, depending on preparation conditions. The models also account for the temperature dependence of the TGB helix pitch.

Original language	English (US)
Pages (from-to)	14191-14196
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	102
Issue number	40
DOIs	https://doi.org/10.1073/pnas.0500664102
State	Published - Oct 4 2005

Keywords

Chirality
Helix
Liquid crystal
Screw dislocation

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Fernsler, J., Hough, L., Shao, R. F., Maclennan, J. E., Navailles, L., Brunet, M., Madhusudana, N. V., Mondain-Monval, O., Boyer, C., Zasadzinski, J., Rego, J. A., Walba, D. M., & Clark, N. A. (2005). Giant-block twist grain boundary smectic phases. Proceedings of the National Academy of Sciences of the United States of America, 102(40), 14191-14196. https://doi.org/10.1073/pnas.0500664102

Fernsler, J, Hough, L, Shao, RF, Maclennan, JE, Navailles, L, Brunet, M, Madhusudana, NV, Mondain-Monval, O, Boyer, C, Zasadzinski, J, Rego, JA, Walba, DM & Clark, NA 2005, 'Giant-block twist grain boundary smectic phases', Proceedings of the National Academy of Sciences of the United States of America, vol. 102, no. 40, pp. 14191-14196. https://doi.org/10.1073/pnas.0500664102

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AU - Brunet, M.

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AB - Study of a diverse set of chiral smectic materials, each of which has twist grain boundary (TGB) phases over a broad temperature range and exhibits grid patterns in the Grandjean textures of the TGB helix, shows that these features arise from a common structure: "giant" smectic blocks of planar layers of thickness Ib > 200 nm terminated by GBs that are sharp, mediating large angular jumps in layer orientation between blocks (60° < Δ ;< 90°), and lubricating the thermal contraction of the smectic layers within the blocks. This phenomenology is well described by basic theoretical models applicable in the limit that the ratio of molecular tilt penetration length-to-layer coherence length is large, and featuring GBs in which smectic ordering is weak, approaching thin, melted (nematic-like) walls. In this limit the energy cost of change of the block size is small, leading to a wide variation of block dimension, depending on preparation conditions. The models also account for the temperature dependence of the TGB helix pitch.

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Giant-block twist grain boundary smectic phases

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