Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer

Michael R. Tuchband; Daniel A. Paterson; Mirosław Salamończyk; Victoria A. Norman; Alyssa N. Scarbrough; Ewan Forsyth; Edgardo Garcia; Cheng Wang; John M. Storey; David M. Walba; Samuel Sprunt; Antal Jákli; Chenhui Zhu; Corrie T. Imrie; Noel A. Clark

doi:10.1073/pnas.1821372116

Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer

Michael R. Tuchband^*, Daniel A. Paterson, Mirosław Salamończyk, Victoria A. Norman, Alyssa N. Scarbrough, Ewan Forsyth, Edgardo Garcia, Cheng Wang, John M. Storey, David M. Walba, Samuel Sprunt, Antal Jákli, Chenhui Zhu^*, Corrie T. Imrie, Noel A. Clark^*

^*Corresponding author for this work

School of Chemistry

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

Abstract

We synthesized the liquid crystal dimer and trimer members of a series of flexible linear oligomers and characterized their microscopic and nanoscopic properties using resonant soft X-ray scattering and a number of other experimental techniques. On the microscopic scale, the twist–bend phases of the dimer and trimer appear essentially identical. However, while the liquid crystal dimer exhibits a temperature-dependent variation of its twist–bend helical pitch varying from 100 to 170 Å on heating, the trimer exhibits an essentially temperature-independent pitch of 66 Å, significantly shorter than those reported for other twist–bend forming materials in the literature. We attribute this to a specific combination of intrinsic conformational bend of the trimer molecules and a sterically favorable intercalation of the trimers over a commensurate fraction (two-thirds) of the molecular length. We develop a geometric model of the twist–bend phase for these materials with the molecules arranging into helical chain structures, and we fully determine their respective geometric parameters.

Original language	English
Journal	Proceedings of the National Academy of Sciences (PNAS)
Early online date	14 May 2019
DOIs	https://doi.org/10.1073/pnas.1821372116
Publication status	Published - 28 May 2019

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Tuchband, M. R., Paterson, D. A., Salamończyk, M., Norman, V. A., Scarbrough, A. N., Forsyth, E., Garcia, E., Wang, C., Storey, J. M., Walba, D. M., Sprunt, S., Jákli, A., Zhu, C., Imrie, C. T., & Clark, N. A. (2019). Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer. Proceedings of the National Academy of Sciences (PNAS). https://doi.org/10.1073/pnas.1821372116

@article{e10d34ee32ce420c9cb950e1ce7874b6,

title = "Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer",

abstract = "We synthesized the liquid crystal dimer and trimer members of a series of flexible linear oligomers and characterized their microscopic and nanoscopic properties using resonant soft X-ray scattering and a number of other experimental techniques. On the microscopic scale, the twist–bend phases of the dimer and trimer appear essentially identical. However, while the liquid crystal dimer exhibits a temperature-dependent variation of its twist–bend helical pitch varying from 100 to 170 {\AA} on heating, the trimer exhibits an essentially temperature-independent pitch of 66 {\AA}, significantly shorter than those reported for other twist–bend forming materials in the literature. We attribute this to a specific combination of intrinsic conformational bend of the trimer molecules and a sterically favorable intercalation of the trimers over a commensurate fraction (two-thirds) of the molecular length. We develop a geometric model of the twist–bend phase for these materials with the molecules arranging into helical chain structures, and we fully determine their respective geometric parameters.",

author = "Tuchband, {Michael R.} and Paterson, {Daniel A.} and Miros{\l}aw Salamo{\'n}czyk and Norman, {Victoria A.} and Scarbrough, {Alyssa N.} and Ewan Forsyth and Edgardo Garcia and Cheng Wang and Storey, {John M.} and Walba, {David M.} and Samuel Sprunt and Antal J{\'a}kli and Chenhui Zhu and Imrie, {Corrie T.} and Clark, {Noel A.}",

year = "2019",

month = may,

day = "28",

doi = "10.1073/pnas.1821372116",

language = "English",

journal = "Proceedings of the National Academy of Sciences (PNAS)",

issn = "0027-8424",

publisher = "National Academy of Sciences",

}

Tuchband, MR, Paterson, DA, Salamończyk, M, Norman, VA, Scarbrough, AN, Forsyth, E, Garcia, E, Wang, C, Storey, JM, Walba, DM, Sprunt, S, Jákli, A, Zhu, C, Imrie, CT & Clark, NA 2019, 'Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer', Proceedings of the National Academy of Sciences (PNAS). https://doi.org/10.1073/pnas.1821372116

TY - JOUR

T1 - Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer

AU - Tuchband, Michael R.

AU - Paterson, Daniel A.

AU - Salamończyk, Mirosław

AU - Norman, Victoria A.

AU - Scarbrough, Alyssa N.

AU - Forsyth, Ewan

AU - Garcia, Edgardo

AU - Wang, Cheng

AU - Storey, John M.

AU - Walba, David M.

AU - Sprunt, Samuel

AU - Jákli, Antal

AU - Zhu, Chenhui

AU - Imrie, Corrie T.

AU - Clark, Noel A.

PY - 2019/5/28

Y1 - 2019/5/28

N2 - We synthesized the liquid crystal dimer and trimer members of a series of flexible linear oligomers and characterized their microscopic and nanoscopic properties using resonant soft X-ray scattering and a number of other experimental techniques. On the microscopic scale, the twist–bend phases of the dimer and trimer appear essentially identical. However, while the liquid crystal dimer exhibits a temperature-dependent variation of its twist–bend helical pitch varying from 100 to 170 Å on heating, the trimer exhibits an essentially temperature-independent pitch of 66 Å, significantly shorter than those reported for other twist–bend forming materials in the literature. We attribute this to a specific combination of intrinsic conformational bend of the trimer molecules and a sterically favorable intercalation of the trimers over a commensurate fraction (two-thirds) of the molecular length. We develop a geometric model of the twist–bend phase for these materials with the molecules arranging into helical chain structures, and we fully determine their respective geometric parameters.

AB - We synthesized the liquid crystal dimer and trimer members of a series of flexible linear oligomers and characterized their microscopic and nanoscopic properties using resonant soft X-ray scattering and a number of other experimental techniques. On the microscopic scale, the twist–bend phases of the dimer and trimer appear essentially identical. However, while the liquid crystal dimer exhibits a temperature-dependent variation of its twist–bend helical pitch varying from 100 to 170 Å on heating, the trimer exhibits an essentially temperature-independent pitch of 66 Å, significantly shorter than those reported for other twist–bend forming materials in the literature. We attribute this to a specific combination of intrinsic conformational bend of the trimer molecules and a sterically favorable intercalation of the trimers over a commensurate fraction (two-thirds) of the molecular length. We develop a geometric model of the twist–bend phase for these materials with the molecules arranging into helical chain structures, and we fully determine their respective geometric parameters.

UR - http://dx.doi.org/10.1073/pnas.1821372116

U2 - 10.1073/pnas.1821372116

DO - 10.1073/pnas.1821372116

M3 - Article

SN - 0027-8424

JO - Proceedings of the National Academy of Sciences (PNAS)

JF - Proceedings of the National Academy of Sciences (PNAS)

ER -

Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer

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