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Main Authors: Lee, Chih-Yu, Huang, Yi-Siou, Adams, Felix, Lian, Chuanyu, Sun, Hongyi, Zhao, Jie, Ye, Zichao, Youngblood, Nathan, Hu, Juejun, Allen, Leslie H, Mo, Yifei, Takeuchi, Ichiro, Ocampo, Carlos A Rios
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.14990
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author Lee, Chih-Yu
Huang, Yi-Siou
Adams, Felix
Lian, Chuanyu
Sun, Hongyi
Zhao, Jie
Ye, Zichao
Youngblood, Nathan
Hu, Juejun
Allen, Leslie H
Mo, Yifei
Takeuchi, Ichiro
Ocampo, Carlos A Rios
author_facet Lee, Chih-Yu
Huang, Yi-Siou
Adams, Felix
Lian, Chuanyu
Sun, Hongyi
Zhao, Jie
Ye, Zichao
Youngblood, Nathan
Hu, Juejun
Allen, Leslie H
Mo, Yifei
Takeuchi, Ichiro
Ocampo, Carlos A Rios
contents Chalcogenide-based optical phase change materials (OPCMs) exhibit a large contrast in refractive index when reversibly switched between their stable amorphous and crystalline states. OPCMs have rapidly gained attention due to their versatility as nonvolatile amplitude or phase modulators in various photonic devices. However, open challenges remain, such as achieving reliable response and transparency spanning into the visible spectrum, a combination of properties in which current broadband OPCMs (e.g., Ge2Sb2Se4Te1, Sb2Se3, or Sb2S3) fall short. Discovering novel materials or engineering existing ones is, therefore, crucial in extending the application scope of OPCMs. Here, we use magnetron co-sputtering to study the effects of Si doping into Sb2Se3. We employ ellipsometry, X-ray diffraction, Raman spectroscopy, and scanning and transmission electron microscopy to investigate the effects of Si doping on the optical properties and crystal structure and compare these results with those from first principles calculations. Moreover, we study the crystallization and melt-quenching of thin films via nano-differential scanning calorimetry (NanoDSC). Our experiments demonstrate that 20% Si doping increases the transparency window in both states, specifically to 800 nm (1.55 eV) in the amorphous phase, while reducing power consumption by lowering the melting temperature. However, this reduction comes at the cost of reducing the refractive index contrast between states and slowing the kinetics of the phase transition.
format Preprint
id arxiv_https___arxiv_org_abs_2510_14990
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Incorporating Si into Sb2Se3: Tailoring Optical Phase Change Materials via Nanocomposites
Lee, Chih-Yu
Huang, Yi-Siou
Adams, Felix
Lian, Chuanyu
Sun, Hongyi
Zhao, Jie
Ye, Zichao
Youngblood, Nathan
Hu, Juejun
Allen, Leslie H
Mo, Yifei
Takeuchi, Ichiro
Ocampo, Carlos A Rios
Materials Science
Applied Physics
Chalcogenide-based optical phase change materials (OPCMs) exhibit a large contrast in refractive index when reversibly switched between their stable amorphous and crystalline states. OPCMs have rapidly gained attention due to their versatility as nonvolatile amplitude or phase modulators in various photonic devices. However, open challenges remain, such as achieving reliable response and transparency spanning into the visible spectrum, a combination of properties in which current broadband OPCMs (e.g., Ge2Sb2Se4Te1, Sb2Se3, or Sb2S3) fall short. Discovering novel materials or engineering existing ones is, therefore, crucial in extending the application scope of OPCMs. Here, we use magnetron co-sputtering to study the effects of Si doping into Sb2Se3. We employ ellipsometry, X-ray diffraction, Raman spectroscopy, and scanning and transmission electron microscopy to investigate the effects of Si doping on the optical properties and crystal structure and compare these results with those from first principles calculations. Moreover, we study the crystallization and melt-quenching of thin films via nano-differential scanning calorimetry (NanoDSC). Our experiments demonstrate that 20% Si doping increases the transparency window in both states, specifically to 800 nm (1.55 eV) in the amorphous phase, while reducing power consumption by lowering the melting temperature. However, this reduction comes at the cost of reducing the refractive index contrast between states and slowing the kinetics of the phase transition.
title Incorporating Si into Sb2Se3: Tailoring Optical Phase Change Materials via Nanocomposites
topic Materials Science
Applied Physics
url https://arxiv.org/abs/2510.14990