&lt;title&gt;High-resolution wavefront control using liquid crystal spatial light modulators&lt;/title&gt;

Olivier, Scot S.; Kartz, Michael W.; Bauman, Brian; Brase, James M.; Brown, C.; Cooke, Jeffrey; Pennington, D. M.; Silva, Dennis A.

doi:10.1117/12.367602

Cited by 4 publications

(2 citation statements)

References 3 publications

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“…The pixel layout and the system configuration of the LCSLM wavefront control report in this work are shown in Figure 1. Operation of LC wavefront controllers has already been demonstrated at low optical power density [1][2][3][4][5][6][7][8]. In this work we addressed the needs of high-energy laser applications.…”

Section: Introductionmentioning

confidence: 96%

Wavefront control with a spatial light modulator containing dual-frequency liquid crystal

Winker

Bing

et al. 2004

SPIE Proceedings

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A versatile, scalable wavefront control approach based upon proven liquid crystal (LC) spatial light modulator (SLM) technology was extended for potential use in high-energy near-infrared laser applications. The reflective LC SLM module demonstrated has a two-inch diameter active aperture with 812 pixels. Using an ultra-low absorption transparent conductor in the LC SLM, a high laser damage threshold was demonstrated. Novel dual frequency liquid crystal materials and addressing schemes were implemented to achieve fast switching speed (<1ms at λ=1.31 µm). Combining this LCSLM with a novel wavefront sensing method, a closed loop wavefront controller is being demonstrated. Compared to conventional deformable mirrors, this non-mechanical wavefront control approach offers substantial improvements in speed (bandwidth), resolution, power consumption and system weight/volume.

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Section: Introductionmentioning

confidence: 96%

Wavefront control with a spatial light modulator containing dual-frequency liquid crystal

Winker

Bing

et al. 2004

SPIE Proceedings

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“…Recent work indicated that liquid crystal light modulator (LCSLM) could be used to replace the deformable mirror to correct wavefront distortions [1][2][3][4][5][6][7][8][9][10][11]. The reflective LC SLM module reported here has a two-inch diameter active aperture with 812 pixels.…”

Section: Introductionmentioning

confidence: 99%

Calibration of a spatial light modulator containing dual frequency liquid crystal

Winker

Bing

et al. 2005

SPIE Proceedings

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Characterization and calibration process for a liquid crystal (LC) spatial light modulator (SLM) containing dual frequency liquid crystal is described. Special care was taken when dealing with LC cell gap non-uniformity and defect pixels. The calibration results were fed into a closed loop control algorithm to demonstrate correction of wavefront distortions. The performance characteristics of the device were reported. Substantial improvements were made in speed (bandwidth), resolution, power consumption and system weight/volume.

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Reversible suppression of second harmonic generation in dye-doped liquid crystal by light-induced thermal phase transition on sub-micrometer scale

Zhuo

Chen

Lai

et al. 2015

Journal of Applied Physics

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Optically controllable signals are fundamental to various applications from communication to super-resolution imaging. However, literature on non-fluorescent, nonlinear optical signals that can be reversibly turned on/off on a sub-micrometer scale is scant. In this work, we experimentally demonstrate a scheme for the reversible suppression of second harmonic generation (SHG) based on dye-doped nematic liquid crystal molecules. Under a pump (suppressing SHG) and probe (generating SHG) setup with a tightly focusing microscope and a time-gated detection, outstanding modulation depth (>80%) has been realized. Surprisingly, the mechanism of liquid crystal SHG switch on a sub-micrometer scale was found to be light-induced thermal phase transition as against optical Frederick's transition. Quantitative analysis of the optical nonlinearity χ(2) versus local heating shows an excellent agreement of SHG signal suppression as well as its dependence on the liquid crystal molecular order and phase change. Our work provides an innovative example of applying nonlinear optical properties of soft materials, and can be further optimized for all-optical modulation applications.

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<title>High-resolution wavefront control using liquid crystal spatial light modulators</title>

Cited by 4 publications

References 3 publications

Wavefront control with a spatial light modulator containing dual-frequency liquid crystal

Wavefront control with a spatial light modulator containing dual-frequency liquid crystal

Calibration of a spatial light modulator containing dual frequency liquid crystal

Reversible suppression of second harmonic generation in dye-doped liquid crystal by light-induced thermal phase transition on sub-micrometer scale

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