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Electric-field driven director oscillations in a nematic liquid crystal: a NMR investigation

Electric-field driven director oscillations in a nematic liquid crystal: a NMR investigation
Electric-field driven director oscillations in a nematic liquid crystal: a NMR investigation
We have investigated the oscillatory behavior of the nematic director for 4-pentyl-4'-cyanobiphenyl (5CB) when it is subjected to a static magnetic field and a sinusoidal electric field. In these experiments the two fields were inclined at about 50degrees and the frequency of the electric field was varied from several hertz to approximate to1000 Hz. The director orientation was measured using time-resolved deuterium NMR spectroscopy since this has the advantage of being able to determine the state of director alignment in the sample. In fact, for all of the frequencies studied the director is found to remain uniformly aligned. Since the diamagnetic and dielectric anisotropies are both positive the director oscillates in the plane formed by the two fields. These oscillations were observed to continue for many cycles, indicating that the coherence in the director orientation was not lost during this motion. The maximum and minimum angles made by the director with the magnetic field were determined, as a function of frequency, from the NMR spectrum averaged over many thousand cycles of the oscillations. At low frequencies (several hertz) these limiting angles are essentially independent of frequency but as the frequency increases the two angles approach each other and become equal at high frequencies, typically 1000 Hz. Our results are well explained by a hydrodynamic theory in which the sinusoidal time dependence of the electric field is included in the torque-balance equation. This analysis also shows that, for a range of frequencies between the high and low limits, these NMR experiments can give dynamic as well as static information concerning the nematic phase.
reorientation, spectroscopy, mesophase, dynamics
0021-9606
1928-1937
Luckhurst, G.R.
7807d1c6-54a1-414f-9abe-22de4d9c30f7
Miyamoto, T.
bd635bfc-13ea-41bd-a687-e5466a9cdbd4
Sugimura, A.
ad404617-1e0f-445f-84d4-1f7efdf57909
Timimi, B.A.
74a91aee-4af5-4938-87e3-a9f9f8584300
Zimmermann, H.
559ddd30-a833-4cf0-a67e-b7b53bbfba17
Luckhurst, G.R.
7807d1c6-54a1-414f-9abe-22de4d9c30f7
Miyamoto, T.
bd635bfc-13ea-41bd-a687-e5466a9cdbd4
Sugimura, A.
ad404617-1e0f-445f-84d4-1f7efdf57909
Timimi, B.A.
74a91aee-4af5-4938-87e3-a9f9f8584300
Zimmermann, H.
559ddd30-a833-4cf0-a67e-b7b53bbfba17

Luckhurst, G.R., Miyamoto, T., Sugimura, A., Timimi, B.A. and Zimmermann, H. (2004) Electric-field driven director oscillations in a nematic liquid crystal: a NMR investigation. Journal of Chemical Physics, 121 (4), 1928-1937. (doi:10.1063/1.1764774).

Record type: Article

Abstract

We have investigated the oscillatory behavior of the nematic director for 4-pentyl-4'-cyanobiphenyl (5CB) when it is subjected to a static magnetic field and a sinusoidal electric field. In these experiments the two fields were inclined at about 50degrees and the frequency of the electric field was varied from several hertz to approximate to1000 Hz. The director orientation was measured using time-resolved deuterium NMR spectroscopy since this has the advantage of being able to determine the state of director alignment in the sample. In fact, for all of the frequencies studied the director is found to remain uniformly aligned. Since the diamagnetic and dielectric anisotropies are both positive the director oscillates in the plane formed by the two fields. These oscillations were observed to continue for many cycles, indicating that the coherence in the director orientation was not lost during this motion. The maximum and minimum angles made by the director with the magnetic field were determined, as a function of frequency, from the NMR spectrum averaged over many thousand cycles of the oscillations. At low frequencies (several hertz) these limiting angles are essentially independent of frequency but as the frequency increases the two angles approach each other and become equal at high frequencies, typically 1000 Hz. Our results are well explained by a hydrodynamic theory in which the sinusoidal time dependence of the electric field is included in the torque-balance equation. This analysis also shows that, for a range of frequencies between the high and low limits, these NMR experiments can give dynamic as well as static information concerning the nematic phase.

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More information

Published date: 22 July 2004
Keywords: reorientation, spectroscopy, mesophase, dynamics
Organisations: Chemistry

Identifiers

Local EPrints ID: 20280
URI: http://eprints.soton.ac.uk/id/eprint/20280
ISSN: 0021-9606
PURE UUID: 64767d2b-7509-410f-97f0-b35c4f0e3f07

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Date deposited: 20 Feb 2006
Last modified: 15 Mar 2024 06:23

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Contributors

Author: G.R. Luckhurst
Author: T. Miyamoto
Author: A. Sugimura
Author: B.A. Timimi
Author: H. Zimmermann

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