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Reversible Single‐Pulse Laser‐Induced Phase Change of Sb2S3 Thin Films: Multi‐Physics Modeling and Experimental Demonstrations.

Authors :
Laprais, Capucine
Zrounba, Clément
Bouvier, Julien
Blanchard, Nicholas
Bugnet, Matthieu
Gassenq, Alban
Gutiérrez, Yael
Vazquez‐Miranda, Saul
Espinoza, Shirly
Thiesen, Peter
Bourrellier, Romain
Benamrouche, Aziz
Baboux, Nicolas
Saint‐Girons, Guillaume
Berguiga, Lotfi
Cueff, Sébastien
Source :
Advanced Optical Materials; Oct2024, Vol. 12 Issue 28, p1-13, 13p
Publication Year :
2024

Abstract

Phase change materials (PCMs) have gained a tremendous interest as a means to actively tune nanophotonic devices through the large optical modulation produced by their amorphous to crystalline reversible transition. Recently, materials such as Sb2S3 emerged as particularly promising low loss PCMs, with both large refractive index modulations and transparency in the visible and near‐infrared. Controlling the local and reversible phase transition in this material is of major importance for future applications, and an appealing method to do so is to exploit pulsed lasers. Yet, the physics and limits involved in the optical switching of Sb2S3 are not yet well understood. Here, the reversible laser‐induced phase transition of Sb2S3 is investigated, focusing specifically on the mechanisms that drive the optically induced amorphization, with multi‐physics considerations including the optical and thermal properties of the PCM and its environment. The laser energy threshold for reversibly changing the phase of the PCM is determined through both theoretical analysis and experimental investigation, not only between fully amorphous and crystalline states but also between partially recrystallized states. Then, the non‐negligible impact of the material's polycrystallinity and anisotropy on the power thresholds for optical switching is revealed. Finally, the challenges related to laser amorphization of thick Sb2S3 layers are addressed, as well as strategies to overcome them. These results enable a qualitative and quantitative understanding of the physics behind the optically‐induced reversible change of phase in Sb2S3 layers. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
21951071
Volume :
12
Issue :
28
Database :
Complementary Index
Journal :
Advanced Optical Materials
Publication Type :
Academic Journal
Accession number :
180109834
Full Text :
https://doi.org/10.1002/adom.202401214