Electrically switchable structural patterns and diffractions in a dual frequency nematic liquid crystal

Zhenpeng Song; Ziyang Li; Xiaohu Shang; Chaoyi Li; Lingling Ma; Yanqing Lu; Bingxiang Li

doi:10.3788/COL202321.010501

Journals >Chinese Optics Letters >Volume 21 >Issue 1 >Page 010501 > Article

Chinese Optics Letters
Vol. 21, Issue 1, 010501 (2023)

Electrically switchable structural patterns and diffractions in a dual frequency nematic liquid crystal

Zhenpeng Song¹, Ziyang Li¹, Xiaohu Shang¹, Chaoyi Li², Lingling Ma^2、*, Yanqing Lu², and Bingxiang Li^1、2、**

Author Affiliations

¹College of Electronic and Optical Engineering & College of Flexible Electronics (Future Technology), Nanjing University of Posts and Telecommunications, Nanjing 210023, China

²National Laboratory of Solid State Microstructures, Key Laboratory of Intelligent Optical Sensing and Manipulation, College of Engineering and Applied Sciences, and Collaborative Innovation Center of Advanced Microstructures, Nanjing University, Nanjing 210023, China

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DOI: 10.3788/COL202321.010501 Cite this Article Set citation alerts

Zhenpeng Song, Ziyang Li, Xiaohu Shang, Chaoyi Li, Lingling Ma, Yanqing Lu, Bingxiang Li. Electrically switchable structural patterns and diffractions in a dual frequency nematic liquid crystal[J]. Chinese Optics Letters, 2023, 21(1): 010501 Copy Citation Text

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$(a) Frequency dependence of dielectric constants (ε∥ and ε⊥) of the DFNLC DP002-026 at various temperatures: 26°C (blue filled circle), 28°C (orange open square), 30°C (green filled rhombus), 32°C (red open triangle), 34°C (purple filled inverted triangle), 36°C (brown open circle), and 38°C (blue filled square). (b) Schematic illustration of the experimental setup for diffraction characterization. A cell is equipped in the hot stage and probed with a linearly polarized laser beam.$

Fig. 1. (a) Frequency dependence of dielectric constants (ε_∥ and ε_⊥) of the DFNLC DP002-026 at various temperatures: 26°C (blue filled circle), 28°C (orange open square), 30°C (green filled rhombus), 32°C (red open triangle), 34°C (purple filled inverted triangle), 36°C (brown open circle), and 38°C (blue filled square). (b) Schematic illustration of the experimental setup for diffraction characterization. A cell is equipped in the hot stage and probed with a linearly polarized laser beam.

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POM images and the corresponding phase diagram of pattern formation for the DFNLC DP002-026. (a) Pattern generation as the field frequency varies from 28 kHz to 40 kHz at the voltage U = 16.1 V, the cell thickness d = 8 µm, and T = 30°C. (b) Pattern generation as the field frequency varies from 25 V to 0 V at the frequency f = 40 kHz, the cell thickness d = 8 µm, 0 V, and T = 30°C. (c) The corresponding phase diagram of pattern formation during voltage decrease for the DFNLC DP002-026 in the cell of thickness d = 8 µm and T = 30°C. The patterns are recorded using crossed polarizers and a quarter waveplate placed at 45° with respect to P. The initial nematic director aligns horizontally.

Fig. 2. POM images and the corresponding phase diagram of pattern formation for the DFNLC DP002-026. (a) Pattern generation as the field frequency varies from 28 kHz to 40 kHz at the voltage U = 16.1 V, the cell thickness d = 8 µm, and T = 30°C. (b) Pattern generation as the field frequency varies from 25 V to 0 V at the frequency f = 40 kHz, the cell thickness d = 8 µm, 0 V, and T = 30°C. (c) The corresponding phase diagram of pattern formation during voltage decrease for the DFNLC DP002-026 in the cell of thickness d = 8 µm and T = 30°C. The patterns are recorded using crossed polarizers and a quarter waveplate placed at 45° with respect to P. The initial nematic director aligns horizontally.

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$Dependences of lateral rolls on the voltage and the dielectric anisotropy of the DFNLC DP002-026. Lateral rolls and corresponding diffraction phenomena at the voltages of amplitude (a) U = 7.5 V, (b) U = 11 V, (c) U = 15 V, and (d) transmitted light intensity versus x. (e) The voltage dependence of the lattice period Px. (f) Px (blue filled circles) and Lx (red open circles) as a function of the voltage frequency. (g) Px as a function of Δε. T = 30°C, d = 8.0 µm, and the initial direction of the director is horizontal.$

Fig. 3. Dependences of lateral rolls on the voltage and the dielectric anisotropy of the DFNLC DP002-026. Lateral rolls and corresponding diffraction phenomena at the voltages of amplitude (a) U = 7.5 V, (b) U = 11 V, (c) U = 15 V, and (d) transmitted light intensity versus x. (e) The voltage dependence of the lattice period P_x. (f) P_x (blue filled circles) and L_x (red open circles) as a function of the voltage frequency. (g) P_x as a function of Δε. T = 30°C, d = 8.0 µm, and the initial direction of the director is horizontal.

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$Dependences of longitudinal rolls on the voltage and the dielectric anisotropy of the DFNLC DP002-026. Longitudinal rolls and corresponding diffraction phenomena at the voltage of amplitudes (a) U = 14 V, (b) U = 17 V, (c) U = 20.5 V, and (d) transmitted light intensity versus y. (e) The voltage dependence of the lattice period Py. (f) Py (orange filled circles) and Ly (green open circles) as a function of the voltage frequency. (g) Py as a function of Δε. T = 30°C, d = 8.0 µm, and the initial direction of the director is horizontal.$

Fig. 4. Dependences of longitudinal rolls on the voltage and the dielectric anisotropy of the DFNLC DP002-026. Longitudinal rolls and corresponding diffraction phenomena at the voltage of amplitudes (a) U = 14 V, (b) U = 17 V, (c) U = 20.5 V, and (d) transmitted light intensity versus y. (e) The voltage dependence of the lattice period P_y. (f) P_y (orange filled circles) and L_y (green open circles) as a function of the voltage frequency. (g) P_y as a function of Δε. T = 30°C, d = 8.0 µm, and the initial direction of the director is horizontal.

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$Dependences of square-grid patterns on the voltage and the dielectric anisotropy of the DFNLC DP002-026. The patterns and corresponding diffraction at the voltages of amplitude (a) U = 17 V, (b) U = 20 V, (c) U = 25 V, and (d) transmitted light intensity versus y. (e) The voltage dependence of the lattice period Px and Py. (f) Px, Py, and Lx, Ly as functions of the voltage frequency. (g) Py as a function of Δε. T = 30°C, d = 8.0 µm, and the initial direction of the director is horizontal.$

Fig. 5. Dependences of square-grid patterns on the voltage and the dielectric anisotropy of the DFNLC DP002-026. The patterns and corresponding diffraction at the voltages of amplitude (a) U = 17 V, (b) U = 20 V, (c) U = 25 V, and (d) transmitted light intensity versus y. (e) The voltage dependence of the lattice period P_x and P_y. (f) P_x, P_y, and L_x, L_y as functions of the voltage frequency. (g) P_y as a function of Δε. T = 30°C, d = 8.0 µm, and the initial direction of the director is horizontal.

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