OAM light propagation through tissue

AbstractA major challenge in use of the optical spectrum for communication and imaging applications is the scattering of light as it passes through diffuse media. Recent studies indicate that light beams with orbital angular momentum (OAM) can penetrate deeper through diffuse media than simple Gaussian beams. To the best knowledge of the authors, in this paper we describe for the first time an experiment examining transmission of OAM beams through biological tissue with thickness of up to a few centimeters, and for OAM modes reaching up to 20. Our results indicate that OAM beams do indeed show a higher transmittance relative to Gaussian beams, and that the greater the OAM, the higher the transmittance also up to 20, Our results extend measured results to highly multi scattering media and indicate that at 2.6 cm tissue thickness for OAM of order 20, we measure nearly 30% more power in comparison to a Gaussian beam. In addition, we develop a mathematical model describing the improved permeability. This work shows that OAM beams can be a valuable contribution to optical wireless communication (OWC) for medical implants, optical biological imaging, as well as recent innovative applications of medical diagnosis.

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Investigation of the Scattering Noise in Underwater Optical Wireless Communications

Sci ◽

10.3390/sci3020027 ◽

2021 ◽

Vol 3 (2) ◽

pp. 27

Author(s):

Behnaz Majlesein ◽

Asghar Gholami ◽

Zabih Ghassemlooy

Keyword(s):

Wireless Communications ◽

Optical Wireless ◽

Clear Water ◽

Optical Wireless Communications ◽

Channel Bandwidth ◽

Phase Variations ◽

Transmission Link ◽

Channel Dependent ◽

First Time ◽

Scattering Noise

In underwater optical wireless communications (UOWC), scattering of the propagating light beam results in both intensity and phase variations, which limit the transmission link range and channel bandwidth, respectively. Scattering of photons while propagating through the channel is a random process, which results in the channel-dependent scattering noise. In this work, we introduce for the first time an analytical model for this noise and investigate its effect on the bit error rate performance of the UOWC system for three types of waters and a range of transmission link spans. We show that, for a short range of un-clear water or a longer range of clear water, the number of photons experiencing scattering is high, thus leading to the increased scattering noise. The results demonstrate that the FEC limit of 3×10−3 and considering the scattering noise, the maximum link spans are 51.5, 20, and 4.6 m for the clear, coastal, and harbor waters, respectively.

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Light Confinement with Structured Beams in Gold Nanoparticle Suspensions

Photonics ◽

10.3390/photonics8060221 ◽

2021 ◽

Vol 8 (6) ◽

pp. 221

Author(s):

Argelia Balbuena Balbuena Ortega ◽

Felix E. Torres-González ◽

Valentin López López Gayou ◽

Raul Delgado Delgado Macuil ◽

Gaetano Assanto ◽

...

Keyword(s):

Colloidal Suspension ◽

Laser Wavelength ◽

Gaussian Beams ◽

Optical Vortices ◽

Complex Structures ◽

Plasmonic Resonance ◽

Dark Solitons ◽

Experimental Campaign ◽

Nanoparticle Suspensions ◽

Light Beams

We carry out an experimental campaign to investigate the nonlinear self-defocusing propagation of singular light beams with various complex structures of phase and intensity in a colloidal suspension of gold nanoparticles with a plasmonic resonance near the laser wavelength (532nm). Studying optical vortices embedded in Gaussian beams, Bessel vortices and Bessel-cosine (necklace) beams, we gather evidence that while intense vortices turn into two-dimensional dark solitons, all structured wavepackets are able to guide a weak Gaussian probe of different wavelength (632.8 nm) along the dark core. The probe confinement also depends on the topological charge of the singular pump.

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