Robust Structured Light Pattern for Use with a Spatial Light Modulator in 3-D Endoscopy

Self-propelled colloidal objects, such as motile bacteria or synthetic microswimmers, have microscopically irreversible individual dynamics—a feature they share with all living systems. The incoherent behavior of individual swimmers can be harnessed (or “rectified”) by microfluidic devices that create systematic motions that are impossible in equilibrium. We present a computational proof-of-concept study showing that such active rectification devices could be created directly from an unstructured “primordial soup” of light-controlled motile particles, solely by using spatially modulated illumination to control their local propulsion speed. Alongside both microscopic irreversibility and speed modulation, our mechanism requires spatial symmetry breaking, such as a chevron light pattern, and strong interactions between particles, such as volume exclusion, which cause a collisional slowdown at high density. Together, we show how these four factors create a novel, many-body rectification mechanism. Our work suggests that standard spatial light modulator technology might allow the programmable, light-induced self-assembly of active rectification devices from an unstructured particle bath.

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A novel method for generating axial cosine structured light using spatial light modulator

Laser Beam Shaping XX ◽

10.1117/12.2566296 ◽

2020 ◽

Author(s):

Xianlin Song ◽

Jianshuang Wei ◽

Lingfang Song

Keyword(s):

Spatial Light Modulator ◽

Structured Light ◽

Light Modulator ◽

Novel Method

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Spatial light modulator aided noninvasive imaging through scattering layers

Scientific Reports ◽

10.1038/s41598-019-54048-7 ◽

2019 ◽

Vol 9 (1) ◽

Cited By ~ 2

Author(s):

Saswata Mukherjee ◽

A. Vijayakumar ◽

Joseph Rosen

Keyword(s):

Spatial Light Modulator ◽

Phase Retrieval ◽

Imaging System ◽

Digital Camera ◽

Retrieval Algorithm ◽

Light Modulator ◽

Incoherent Light ◽

Light Pattern ◽

Spread Function ◽

Phase Retrieval Algorithm

AbstractWe propose and demonstrate a new imaging technique to noninvasively see through scattering layers with the aid of a spatial light modulator (SLM). A relay system projects the incoherent light pattern emitting from the scattering layer onto the SLM. Two coded phase masks are displayed, one after another, on the SLM to modulate the projected scattered field and the two corresponding intensity patterns are recorded by a digital camera. The above procedure helps to achieve two goals. Firstly, since the coded phase masks are digitally synthesized, the point spread function of the imaging system can be engineered such that the image retrieval becomes more reliable. Secondly, the two recorded intensity patterns are subtracted one from the other and by that the background noise of the recovered image is minimized. The above two advantages along with a modified phase retrieval algorithm enable a relatively easier and accurate convergence to the image of the covered object.

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Reconfigurable terahertz metasurfaces coherently controlled by wavelength-scale-structured light

Nanophotonics ◽

10.1515/nanoph-2021-0501 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Kamalesh Jana ◽

Emmanuel Okocha ◽

Søren H. Møller ◽

Yonghao Mi ◽

Shawn Sederberg ◽

...

Keyword(s):

Terahertz Radiation ◽

Spatial Light Modulator ◽

Coherent Control ◽

Structured Light ◽

Electric Polarization ◽

Light Modulator ◽

Structured Materials ◽

Optical Metamaterials ◽

Wavelength Scale ◽

Transfer Structure

Abstract Structuring light–matter interaction at a deeply subwavelength scale is fundamental to optical metamaterials and metasurfaces. Conventionally, the operation of a metasurface is determined by the collective electric polarization response of its lithographically defined structures. The inseparability of electric polarization and current density provides the opportunity to construct metasurfaces from current elements instead of nanostructures. Here, we realize metasurfaces using structured light rather than structured materials. Using coherent control, we transfer structure from light to transient currents in a semiconductor, which act as a source for terahertz radiation. A spatial light modulator is used to control the spatial structure of the currents and the resulting terahertz radiation with a resolution of 5.6 ± 0.8 μm $5.6\pm 0.8\mathrm{\,\mu m}$ , or approximately λ / 54 $\lambda /54$ at a frequency of 1 THz. The independence of the currents from any predefined structures and the maturity of spatial light modulator technology enable this metasurface to be reconfigured with unprecedented flexibility.

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