Ultra‐High Temperature Calcination of Crystalline α‐Fe2O3 and Its Nonlinear Optical Properties for Ultrafast Photonics

Ultra‐High Temperature Calcination of Crystalline α‐Fe2O3 and Its Nonlinear Optical Properties for Ultrafast Photonics

Abstract As a typical transition metal oxide, α‐Fe2O3 has garnered significant attention due to its advantages in nonlinear optical applications, such as strong third‐order nonlinearity and fast carrier recovery time. To delve into the nonlinear optical properties of α‐Fe2O3, crystalline α‐Fe2O3 mat...

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Bibliographic Details
Main Authors: Qingxi Zhao, Qingling Tang, Hongwei Chu, Zhongben Pan, Han Pan, Shengzhi Zhao, Dechun Li
Format: Article
Language:English
Published: Wiley 2025-05-01
Series:Advanced Science
Subjects:
mode‐locking
nonlinear optical properties
phase transition
ultra‐high temperature
α‐Fe2O3
Online Access:https://doi.org/10.1002/advs.202500896
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Summary:Abstract As a typical transition metal oxide, α‐Fe2O3 has garnered significant attention due to its advantages in nonlinear optical applications, such as strong third‐order nonlinearity and fast carrier recovery time. To delve into the nonlinear optical properties of α‐Fe2O3, crystalline α‐Fe2O3 materials with different microstructures are prepared. The nonlinear optical features of α‐Fe2O3 calcined at the previously unexplored ultra‐high temperature of >1100°C are emphasized. It is found that α‐Fe2O3 exposed to ultra‐high temperatures undergoes the phase transition, leading to the formation of Fe3O4. Subsequently, the nonlinear absorption coefficient is measured as −0.6280 cm GW−1 at 1.5 µm. The modulation depth and saturation intensity for the Fe2O3‐based saturable absorber at 1.5 µm are 4.20% and 13.94 MW cm−2, respectively. Ultimately, the incorporation of the Fe2O3‐based saturable absorber into an Er‐doped fiber laser cavity resulted in the achievement of both conventional soliton mode‐locking operation with a central wavelength of 1560.3 nm and a pulse duration of 1.13 ps, as well as the dissipative soliton resonance mode‐locking operation with a central wavelength near 1564.0 nm. Overall, the phase transition and the nonlinear optical features in iron oxides under ultra‐high temperatures are revealed, indicating the great potential in advanced ultrafast photonic applications.
ISSN:2198-3844

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