Propagation of hollow higher-order cosh-Gaussian beam in human upper dermis

Bayraktar, Mert; Elmabruk, Kholoud; Duncan, Juan Carlos Merlano; Chatzinotas, Symeon

doi:10.1088/1402-4896/ad0340

“…Understanding the dynamics governing the interaction of light with biological mediums is crucial for the development of bio-optical disease detection and treatment technology. Several studies have analyzed the intensity profile and beam spreading of different beams for soft tissue mediums, including impact partially coherent circularly flattened Gaussian vortex beam (Ni et al 2019), Hermite-Gaussian rectangular vortex beam (Li et al, 2022) Hermite Gaussian correlated Schell-model beams (Zhang et al 2021), hollow higher order cosh-Gaussian beam (Bayraktar et al 2023), Gaussian-Schell model vortex beams (Duan et al 2020), partially coherent chirped optical coherence vortex lattices (Cheng et al, 2022), partially coherent beam (Chib et al 2023), partially coherent hyperbolic sinusoidal beam (Bayraktar, 2021c) and pulsed chirped Generalized Hermite cosh-Gaussian beams ). We chose pulsed cLhchGB due to it includes several parts such as chirped factor, Laguerre polynomial, and higher-order cosh function.…”

Section: Introductionmentioning

confidence: 99%

Evolution behavior of pulsed chirped Laguerre higher-order cosh-Gaussian beam propagating through liver tissue

Benzehoua,

Saad,

Bayraktar

et al. 2024

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0

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We perform an analytical study on the propagation properties of a pulsed chirped Laguerre higher-order cosh-Gaussian beam (cLhchGB) passing through liver tissue, utilizing the power spectrum refractive index, the extended Huygens-Fresnel integral, and the Fourier Transform method. Our investigation includes numerical simulations based on the derived formula, illustrating how varying beam parameter configurations within liver tissue impact the properties of the beam. Additionally, we thoroughly discuss the influence of both optical parameters and biological tissue characteristics on the spectral modifier, while also evaluating the impact of pulse duration and chirp parameter on spectral intensity at various observation positions. Our observations indicate that the pulsed cLhchGB undergoes changes in its shape as it traverses a considerable distance through this medium. The results presented in this paper hold significant importance for their potential applications in determining the deterioration or disruption of biological tissue, as well as in the fields of medical imaging and medical diagnosis.

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“…More recently, ) have scrutinized the development of spectral intensity profiles in pulsed chirped Generalized Hermite cosh Gaussian beams within turbulent biological tissues. Additionally, the propagation of hollow higher-order cosh-Gaussian beam in the human upper dermis has been explored (Bayraktar et al 2023).…”

Section: Introductionmentioning

confidence: 99%

Analysis on the propagation characteristics of a Generalized Hermite cosh-Gaussian beam through human upper dermis tissue

Saad,

Benzehoua,

Belafhal

2023

Preprint

0

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Based on the extended Huygens-Fresnel principle, the analytical formula for a Generalized Hermite cosh-Gaussian beam (GHchGB) propagating through human upper dermis tissue is derived in this paper. From the derived formula, numerical illustrative examples are performed to illustrate the propagation properties of the considered beam in human upper dermis tissue. Results show that the evolution of the intensity pattern of GHchGB depends strongly on the source beam parameters such as Gaussian beam waists, decentered cosh parameter, hollowness parameter, beam orders and wavelength. It is found that the GHchGB with a smaller parameter in the human upper dermis evolves into the Gaussian beam faster as the propagation distance increases. This observation suggests that the resistance of the GHchGB against turbulence increases as the source parameter increases. The significance of the obtained results has the potential application in the development of bio-optical disease detection and treatment technology.

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Analysis on the propagation characteristics of a Generalized Hermite cosh-Gaussian beam through human upper dermis tissue

Saad,

Benzehoua,

Belafhal

2024

Opt Quant Electron

4

0

View full text Add to dashboard Cite

Based on the extended Huygens-Fresnel principle, the analytical formula for a Generalized Hermite cosh-Gaussian beam (GHchGB) propagating through human upper dermis tissue is derived in this paper. From the derived formula, numerical illustrative examples are performed to illustrate the propagation properties of the considered beam in human upper dermis tissue. Results show that the evolution of the intensity pattern of GHchGB depends strongly on the source beam parameters such as Gaussian beam waists, decentered cosh parameter, hollowness parameter, beam orders and wavelength. It is found that the GHchGB with a smaller parameter in the human upper dermis evolves into the Gaussian beam faster as the propagation distance increases. This observation suggests that the resistance of the GHchGB against turbulence increases as the source parameter increases. The significance of the obtained results has the potential application in the development of bio-optical disease detection and treatment technology.

show abstract

Propagation of hollow higher-order cosh-Gaussian beam in human upper dermis

Cited by 10 publications

References 25 publications

Evolution behavior of pulsed chirped Laguerre higher-order cosh-Gaussian beam propagating through liver tissue

Evolution behavior of pulsed chirped Laguerre higher-order cosh-Gaussian beam propagating through liver tissue

Analysis on the propagation characteristics of a Generalized Hermite cosh-Gaussian beam through human upper dermis tissue

Analysis on the propagation characteristics of a Generalized Hermite cosh-Gaussian beam through human upper dermis tissue

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