Preparation, spectroscopic characterization and energy transfer investigation of iron-chromium diffusion co-doped ZnSe for mid-IR laser applications

•Cr,Fe:ZnSe polycrystalline was first prepared by controlled thermal diffusion method.•The spectroscopic characterization and energy transfer mechanism of Cr,Fe:ZnSe were reported.•The transfer rate is much faster than the photoluminescence decay.•Laser operation at 3.7–4.5μm via Cr2+→Fe2+ energy tr...

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Bibliographic Details
Published in:Optical materials 2016-04, Vol.54, p.234-237
Main Authors: Wang, XiangYong, Chen, Zhe, Zhang, Lianhan, Jiang, Benxue, Xu, Min, Hong, Jiaqi, Wang, Yaqi, Zhang, Peixiong, Zhang, Long, Hang, Yin
Format: Article
Language:English
Subjects:
Band spectra
Cr,Fe:ZnSe
Cr-Fe energy transfer
Energy transfer
Infrared absorption
Laser applications
Lasers
Mid-IR laser materials
Photoluminescence
Spectroscopy
Thermal diffusion
Zinc selenides
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Summary:•Cr,Fe:ZnSe polycrystalline was first prepared by controlled thermal diffusion method.•The spectroscopic characterization and energy transfer mechanism of Cr,Fe:ZnSe were reported.•The transfer rate is much faster than the photoluminescence decay.•Laser operation at 3.7–4.5μm via Cr2+→Fe2+ energy transfer is feasible. The spectroscopic characterization and energy transfer mechanism of iron-chromium co-doped ZnSe polycrystalline (Cr,Fe:ZnSe) were reported with dimension of 15mm×15mm×2mm obtained by controlled post-growth thermal diffusion method. The infrared absorption is characterized by a strong broad-band centered at 1770nm which can be attributed to the only spin-allowed transition 5T2→5E within the 3d4 shell of Cr2+ ions. Photoluminescence spectrum shows a relatively strong broad emission band centered at 4.1μm with a width of 0.8μm (FWHM) under 1770nm excitation at room temperature and reveals effective Cr2+→Fe2+ energy transfer process. Room temperature photoluminescence decay about 8μs was measured. All the results indicate that Cr,Fe:ZnSe could achieve laser operation at 3.7–4.5μm via Cr2+→Fe2+ energy transfer using a more convenient laser pump source in the near IR region.
ISSN:0925-3467
1873-1252
DOI:10.1016/j.optmat.2016.02.002