Mid-infrared
laser in the 2–5 μm wavelength region
is in the atmospheric transmission window range, and hence, it has
important application prospects in the fields of optoelectronic countermeasures,
space communication, environmental remote sensing, and molecular spectroscopy.
One of the most promising technological approaches to achieve mid-infrared
laser output is based on direct lasing of transition-metal (TM)-doped
II–VI chalcogenide crystals. In this work, CdS
x
Se1‑x
and Cr:CdS0.8Se0.2 polycrystals were synthesized by a chemical
vapor synthesis method from a stoichiometric mixture of vacuum-sublimed
CdS and CdSe. The structure of the synthesized products was analyzed
by X-ray diffraction (XRD). Using these synthesized products, CdS
x
Se1–x
and
Cr:CdS0.8Se0.2 single crystals were grown by
the physical vapor transport (PVT) method. After annealing, the band
gap becomes smaller and the transmission range widens to 17 μm.
The composition of the single crystals was determined by energy-dispersive
spectrometry (EDS) mapping and XPS, and it was found to be uniform
throughout the ingot. In addition, the absorption peak maximum for
the Cr2+ ion in the Cr:CdS0.8Se0.2 crystal is at 1.84 μm.
The Bi/Sn-doped aluminosilicate glass samples were prepared using a melting–quenching method and their near-infrared (NIR) emission properties were studied. An ultra-broadband NIR emission ranging from 950 nm to 1600 nm was observed in all samples under 480 nm excitation, which covered the whole fiber low-loss window. The NIR emission spectrum showed that the maximum emission peak was about 1206 nm and the full width at half maximum (FWHM) was about 220 nm. Furthermore, the NIR emission intensity strongly depends on the composition of the glass, which can be optimized by modulating the glass composition. The Bi0 and Bi+ ions were the NIR luminescence source of the glass samples in this paper. The Bi/Sn-doped aluminosilicate glass has the potential to become a new type of core fiber material and to be applied to optical fiber amplifiers (OFAs), based on its excellent performance in ultra-broadband NIR emission.
First-principles calculations were used to simulate the aggregation of the peroxy chain defect POL and the oxygen vacancy defect ODC(I). Defect aggregation’s electronic structure and optical properties were investigated. The two defects were most likely to accumulate on a 6-membered ring in ortho-position. When the two defects are aggregated, it is discovered that 0.75 ev absorption peaks appear in the near-infrared band, which may be brought on by the addition of oxygen vacancy defect ODC(I). We can draw the conclusion that the absorption peak of the aggregation defect of ODC(I) defect and POL is more prominent in the near infrared region and visible light area than ODC(I) defect and POL defect.
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