Deep and persistent spectral holes in Tm-doped yttrium orthosilicate for imaging applications

With their optical wavelength in the near infrared (790-800nm) and their unique spectroscopic properties at cryogenic temperatures, thulium-doped crystals are at the center of many architectures linked to classical signal processing and quantum information. In this work, we focus on Tm-doped YSO, a...

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Published in:arXiv.org 2019-02
Main Authors: Venet, Caroline, Car, Benjamin, Veissier, Lucile, Ramaz, François, Louchet-Chauvet, Anne
Format: Article
Language:English
Subjects:
Broadband
Cryogenic temperature
Domains
Doped crystals
Garnets
Hole burning
Medical imaging
Optical properties
Quantum phenomena
Radio frequency
Signal processing
Spectra
Thulium
Yttrium
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Car, Benjamin
Veissier, Lucile
Ramaz, François
Louchet-Chauvet, Anne
description With their optical wavelength in the near infrared (790-800nm) and their unique spectroscopic properties at cryogenic temperatures, thulium-doped crystals are at the center of many architectures linked to classical signal processing and quantum information. In this work, we focus on Tm-doped YSO, a compound that was left aside in the mid-1990s due to its rather short optical coherence lifetime. By means of time-resolved hole-burning spectroscopy, we investigate the anisotropic enhanced nuclear Zeeman effect and demonstrate deep, sub-MHz, persistent spectral hole burning under specific magnetic field orientation and magnitude. By estimating the experimental parameters corresponding to a real-scale ultrasound optical tomography setup using Tm:YSO as a spectral filter, we validate Tm:YSO as a promising compound for medical imaging in the human body.
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subjects Broadband
Cryogenic temperature
Domains
Doped crystals
Garnets
Hole burning
Medical imaging
Optical properties
Quantum phenomena
Radio frequency
Signal processing
Spectra
Thulium
Yttrium
title Deep and persistent spectral holes in Tm-doped yttrium orthosilicate for imaging applications
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