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Hauptverfasser: Kaniolakis-Kaloudis, Emmanouil, Papadogiannis, Nektarios, Orphanos, Yannis, Bakarezos, Makis, Kaleris, Konstantinos
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2512.19268
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author Kaniolakis-Kaloudis, Emmanouil
Papadogiannis, Nektarios
Orphanos, Yannis
Bakarezos, Makis
Kaleris, Konstantinos
author_facet Kaniolakis-Kaloudis, Emmanouil
Papadogiannis, Nektarios
Orphanos, Yannis
Bakarezos, Makis
Kaleris, Konstantinos
contents This work presents a complete methodology for the precise characterization of the acoustic field inside crystal-based devices driven by high-frequency ultrasounds towards the generation of tunable narrowband and directional gamma radiation via undulation of ultra-relativistic charged particles. Such gamma-ray sources have long been anticipated by the scientific community, as they promise new powerful tools for the study of high-energy physical phenomena and the development of novel nuclear technologies. In such devices, a piezoelectric transducer induces tens of MHz harmonic waves inside a silicon monocrystal. Ultra-relativistic charged particles traversing the crystal get trapped within the channels formed by the extremely strong electric fields of the acoustically modulated lattice planes, undergoing undulation and emitting gamma radiation. Precise characterization of the acoustic field in the crystal is crucial for the determination of the expected characteristics of the secondarily generated gamma rays. For this purpose, fast laser refraction imaging is used here to image the acoustic waves by exploiting the spatial redistribution of a laser beam optical intensity caused by the acoustic field. A dedicated computational model is developed for the estimation of the spatial distribution of the pressure and lattice deformation inside the crystal. This methodology provides a framework for future novel gamma-ray sources in high-energy facilities.
format Preprint
id arxiv_https___arxiv_org_abs_2512_19268
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Precise control of high-frequency ultrasounds in thin crystals for the development of tunable narrowband and directional gamma-ray sources
Kaniolakis-Kaloudis, Emmanouil
Papadogiannis, Nektarios
Orphanos, Yannis
Bakarezos, Makis
Kaleris, Konstantinos
Accelerator Physics
Applied Physics
Optics
This work presents a complete methodology for the precise characterization of the acoustic field inside crystal-based devices driven by high-frequency ultrasounds towards the generation of tunable narrowband and directional gamma radiation via undulation of ultra-relativistic charged particles. Such gamma-ray sources have long been anticipated by the scientific community, as they promise new powerful tools for the study of high-energy physical phenomena and the development of novel nuclear technologies. In such devices, a piezoelectric transducer induces tens of MHz harmonic waves inside a silicon monocrystal. Ultra-relativistic charged particles traversing the crystal get trapped within the channels formed by the extremely strong electric fields of the acoustically modulated lattice planes, undergoing undulation and emitting gamma radiation. Precise characterization of the acoustic field in the crystal is crucial for the determination of the expected characteristics of the secondarily generated gamma rays. For this purpose, fast laser refraction imaging is used here to image the acoustic waves by exploiting the spatial redistribution of a laser beam optical intensity caused by the acoustic field. A dedicated computational model is developed for the estimation of the spatial distribution of the pressure and lattice deformation inside the crystal. This methodology provides a framework for future novel gamma-ray sources in high-energy facilities.
title Precise control of high-frequency ultrasounds in thin crystals for the development of tunable narrowband and directional gamma-ray sources
topic Accelerator Physics
Applied Physics
Optics
url https://arxiv.org/abs/2512.19268