Aufsatz in einer Fachzeitschrift
Continuous Optical Phase Modulation in a Copolymer Network Nematic Liquid Crystal



Details zur Publikation
Autor(inn)en:
Lorenz, A.; Braun, L.; Kolosova, V.
Verlag:
AMER CHEMICAL SOC
Publikationsjahr:
2016
Zeitschrift:
ACS Photonics
Seitenbereich:
1188-1193
Jahrgang/Band:
3
Heftnummer:
7
Erste Seite:
1188
Letzte Seite:
1193
Seitenumfang:
6
ISSN:
2330-4022

Zusammenfassung, Abstract
A nematic liquid crystal (LC) was doped with a reactive mixture of a mesogenic diacrylate monomer, a monofunctional acrylate monomer, and photoinitiator. This mixture was filled in transparent test cells with planar electrodes and uniform director alignment. Photopolymerization of the monomers was excited by exposure with ultraviolet light. After photoexposure, the test cells were electrically addressed and their electro-optic response properties were studied by polarized optical microscopy. The voltage dependence of the optical retardation was investigated with a Berek tilting compensator. By applying voltages in the range 4-20 V, the optical retardation was continuously tuned. Importantly, the induced optical phase shift had a smooth onset, which is desirable in electro-optic modulators. Low driving voltages of <15 V were sufficient to induce a half-wavelength retardation throughout the visible spectral range. The time dependence of the transmittance was investigated with monochromatized light and converted to optical phase shift data. Square wave signals (2 kHz) of various amplitudes were switched on and subsequently switched off, respectively. The response times were extracted from the measured data, and sums (t(on) + t(off)) < 3 ms were found at driving voltages of 12-20 V. The copolymer network LC was suitable for 500 Hz modulations. The electro-optic properties of samples with and without added acrylate monomer were compared.


Schlagwörter
liquid crystal, phase modulation, photonics, polymer, polymer network liquid crystal


Autor(inn)en / Herausgeber(innen)

Zuletzt aktualisiert 2019-25-07 um 19:34