Lehmann effect in compensated cholesteric liquid crystals

Dequidt, Alain; Oswald, P.

doi:10.1209/0295-5075/80/26001

Cited by 28 publications

(37 citation statements)

References 19 publications

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“…In previous works [7,8], we showed that q changes linearly with temperature around T c within an excellent approximation. This allowed us to write that (7) where dq dT is a constant.…”

Section: -P2supporting

confidence: 55%

“…In our experiment, d =25μm and the maximum temperature gradient used was G ≈ 6 × 10 4 • C/m. Knowing that K 2 ≈ 3 × 10 −12 N [7,8] at T c ,w ee s t i m a t et h a t ξ<3 × 10 −12 kg m K −1 s −2 in our CC-8OCB mixture. This conclusion is not incompatible with a previous estimate of a similar coefficient in the liquid crystal 5CB (pentylcyanobiphenyl) in which ξ ∼ 10 −12 kg m K −1 s −2 [17].…”

Section: -P2mentioning

confidence: 80%

“…Recently, we reported the first preliminary observation of the continuous Lehmann rotation of the cholesteric helix under the action of a temperature gradient [7,8]. This experiment was made possible thanks to the development of a new surface treatment allowing for planar and sliding anchoring of the molecules at the glass plates limiting the sample [9].…”

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confidence: 99%

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Direct measurement of the thermomechanical Lehmann coefficient in a compensated cholesteric liquid crystal

Oswald

Dequidt

2008

Europhys. Lett.

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The thermomechanical Lehmann coefficient ν is directly measured as a function of temperature in a compensated cholesteric liquid crystal. The method consists of observing the continuous rotation of the director in samples treated for planar sliding anchoring when a temperature gradient is applied perpendicularly to the director. The main result is that there is no relationship between the Lehmann coefficient and the equilibrium twist q. In particular, we confirm that ν does not vanish at the compensation temperature at which q = 0, in agreement with previous static measurements of Éber and Jánossy (Mol. Cryst. Liq. Cryst., 72 (1982) 233) and of ourselves (Europhys. Lett., 80 (2007) 26001). In addition, the sign of the Lehmann coefficient is determined by observing between crossed polarizers the sense of rotation of the extinction branches of the disclination lines.

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“…In previous works [7,8], we showed that q changes linearly with temperature around T c within an excellent approximation. This allowed us to write that (7) where dq dT is a constant.…”

Section: -P2supporting

confidence: 55%

Section: -P2mentioning

confidence: 80%

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Direct measurement of the thermomechanical Lehmann coefficient in a compensated cholesteric liquid crystal

Oswald

Dequidt

2008

Europhys. Lett.

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“…Although this result was conform to theoretical predictions of Pleiner and Brand [19,20], it seemed to contradict previous experiments ofÉber and Jánossy [21], who found that the "classical" thermomechanical Lehmann coefficient was different from 0 at the compensation temperature. Intrigued by these contradictions, we recently redid the experiment ofÉber and Jánossy and confirmed their results [22,23]. Being thus in disagreement with Pleiner and Brand predictions and with Padmini and Madhusudana findings, we felt it was important to also redo and reanalyze the experiment of Padmini and Madhusudana, while extending it to another geometry.…”

Section: Introductionmentioning

confidence: 65%

“…From these measurements and others described in refs. [22,23], we calculated the dielectric anisotropy ε a = ε − ε ⊥ = 4.8 ± 0.3. We recall that the subscripts and ⊥ refer to the director orientation.…”

Section: Useful Materials Constantsmentioning

confidence: 99%

Does the electric Lehmann effect exist in cholesteric liquid crystals?

Dequidt

Oswald

2007

Eur. Phys. J. E

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Abstract. Experiments have shown that cholesteric droplets or cholesteric fingers may be put into motion by the action of an electric field. The former rotate whereas the latter drift perpendicularly to their axes. In all cases, the texture moves without visible material transport. The electric Lehmann effect was initially used to interpret these observations but, recently, alternative explanations were found, based on electrohydrodynamics. Another experiment in this area was that of Padmini and Madhusudana (Liq. Cryst. 14, 497 (1993)). Performed in 1993 with a compensated cholesteric liquid crystal under fixed planar boundary conditions, it was also explained in terms of electric Lehmann effect. We conducted the same experiment and extended it to a π-twisted planar geometry. Although our experimental results agree with those of Padmini and Madhusudana, we demonstrate that they are incompatible with an electric Lehmann effect. By contrast, an explanation based on flexoelectricity allows us to interpret the whole data set obtained in both geometries. The consequence is that there is at the moment no clear experimental evidence of the electric Lehmann effect.PACS. 61.30.Gd Orientational order of liquid crystals; electric and magnetic field effects on order -77.65.-j Piezoelectricity and electromechanical effects -42.70.Df Liquid crystals

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