Low-cost LCD spatial light modulator with high optical quality

Wavefront correction plays significant role in some fields like astronomical observation, laser processing and medical imaging, etc. Liquid crystal spatial light modulator ( LC SLM) is an ideal device for high-resolution wavefront correction because of its low cost, low consumption, large number of pixels and independent programming control of each unit. It is researched experimentally that LC SLM is used as a wavefront correction device and corrects arbitrary wavefront aberration. Wavefront correction is performed based on phase conjugation and periodic phase modulation with modulo-2π. The experimental results show that the PV value of the irregular wavefront aberration is 1.56λ, RMS value is 0.25 and Strehl ratio is 0.08 before correction, but the PV value of the residual aberration is reduced to 0.26λ, RMS value is 0.02 and Strehl ratio is increased to 0.97 which is approximated diffraction limit after correction. It is proved to be feasible and effective that LC SLM is used to the high-precision and high-resolution wavefront correction.

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High optical quality long ultrafine ZnO nanowires by low-temperature oxidation of sputtered nanostructured Zn templates

International Journal of Modern Physics B ◽

10.1142/s0217979218502971 ◽

2018 ◽

Vol 32 (27) ◽

pp. 1850297 ◽

Cited By ~ 1

Author(s):

F. Abdolrezapour ◽

M. Moradi

Keyword(s):

Low Temperature ◽

Low Cost ◽

Optical Quality ◽

Zno Nanowires ◽

Low Temperature Oxidation ◽

Temperature Oxidation ◽

High Optical Quality ◽

Small Defect ◽

High Throughput Method ◽

Post Deposition

In this study, we show that by applying appropriate deposition conditions, Zn nanostructured templates for the growth of zinc oxide (ZnO) nanowires can be fabricated, from which ultrafine high optical quality nanowires can be grown by means of post-deposition low-temperature oxidation. By identifying and optimizing the appropriate parameters, we successfully fabricated long ultrafine ZnO nanowires up to 30 microns in length and 50 nm in diameter. Our report contradicts the commonly held paradigm that sputter deposition can only be used to fabricate thin films with no significant nanostructure morphology and provides a low cost, high throughput method of fabricating different ZnO nanostructures. The studies of photoluminescence (PL) of the nanowires showed their high optical quality with band edge dominated emission with small defect-related input.

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Wavefront shaping assisted design of spectral splitters and solar concentrators

Scientific Reports ◽

10.1038/s41598-021-82110-w ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Berk N. Gün ◽

Emre Yüce

Keyword(s):

Experimental Method ◽

Spatial Light Modulator ◽

Large Scale ◽

Low Cost ◽

Optical Element ◽

Light Modulator ◽

Solar Concentrators ◽

Spectral Splitting ◽

Wavefront Shaping ◽

First Time

AbstractSpectral splitters, as well as solar concentrators, are commonly designed and optimized using numerical methods. Here, we present an experimental method to spectrally split and concentrate broadband light (420–875 nm) via wavefront shaping. We manage to spatially control white light using a phase-only spatial light modulator. As a result, we are able to split and concentrate three frequency bands, namely red (560–875 nm), green (425–620 nm), and blue (420–535 nm), to two target spots with a total enhancement factor of 715%. Despite the significant overlap between the color channels, we obtain spectral splitting ratios as 52%, 57%, and 66% for red, green, and blue channels, respectively. We show that a higher number of adjustable superpixels ensures higher spectral splitting and concentration. We provide the methods to convert an optimized phase pattern into a diffractive optical element that can be fabricated at large scale and low cost. The experimental method that we introduce, for the first time, enables the optimization and design of SpliCons, which is $$\sim 300$$ ∼ 300 times faster compared to the computational methods.

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