Lead Chalcogenide Quantum Dot‐Doped Glasses for Photonic Devices

Liu, Chao; Heo, Jong

doi:10.1111/ijag.12032

Cited by 34 publications

(19 citation statements)

References 51 publications

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“…Similar broadened spectra were also reported in other RE‐doped glass containing QDs. For example, Liu and Heo investigated the effects of different Tm 2 O 3 concentrations on the formation of PbS QDs. The results show that their superimposed emission range is approximately 1100‐2100 nm, which is much narrower and shorter than the present work (1400‐2600 nm).…”

Section: Resultsmentioning

confidence: 99%

“…In addition to the RE ions, transition metals and noble metals, is there any other possible methods to tailor the MIR luminescence of RE‐doped glass? Over the past decade, the quantum dots (QDs) precipitated glass and optical fiber with NIR and MIR emissions have drawn increasing attention . Compared with RE ions, the QDs with narrow bandgaps were widely investigated for various optoelectronics fields.…”

Section: Introductionmentioning

confidence: 99%

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Quantum‐dots‐precipitated rare‐earth‐doped glass for ultra‐broadband mid‐infrared emissions

et al. 2018

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Mid‐infrared (MIR) fiber lasers have wide application prospects and great commercial value in the fields of medical operation, remote sensing and military weapon, etc. At present, Tm3+‐doped glass can obtain broadband luminescence at 2 μm, the introduction of Ho3+ or Er3+ ions also shows a tunable MIR emission but with limited success. Herein, the rare‐earth (RE) doped glass with quantum dots (QDs) precipitation is proposed for achieving ultra‐broadband MIR emissions. The types and sizes of QDs are determined by the XRD and TEM, and their optical properties are further characterized by the absorption and emission spectra as well as the lifetime decay curves. It is found that the diameter of the QDs is gradually increased from 1.7 to 5.1 nm by increasing the heat‐treated temperature from 490°C to 530°C, respectively. Interestingly, an ultra‐broadband emission covering 1400‐2600 nm is achieved from the heat‐treated glass upon the excitation of 808 nm laser diode as a result of an overlapped emission from Tm3+ and PbS. All results suggest that these QDs‐precipitated RE‐doped glasses have important application prospects in ultra‐broadband MIR laser glass, glass fiber, and fiber lasers.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quantum‐dots‐precipitated rare‐earth‐doped glass for ultra‐broadband mid‐infrared emissions

et al. 2018

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“…Additionally, the maximum Ln 3+ concentration that can be obtained in these NCs is limited by the limited solubility of Ln 3+ ions [61][62][63], their short-distance diffusion in glass [64][65][66] and the large volume fractions of 25%-35% of the in-situ grown NCs (NCs/glass vol/vol) [67,68]. Furthermore, the continued growth of in-situ-grown NCs, which could occur during a post-annealing or during a reheating process, such as fiber drawing, inhibits the application of glass ceramics [69]. The continued growth of NCs can increase the light scattering and so the optical loss in the resulting glass/fiber.…”

Section: Nanoparticle-doped Glasses and Fibersmentioning

confidence: 99%

Glass and Process Development for the Next Generation of Optical Fibers: A Review

Ballato

Ebendorff‐Heidepriem

Zhao

et al. 2017

Fibers

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Applications involving optical fibers have grown considerably in recent years with intense levels of research having been focused on the development of not only new generations of optical fiber materials and designs, but also on new processes for their preparation. In this paper, we review the latest developments in advanced materials for optical fibers ranging from silica, to semi-conductors, to particle-containing glasses, to chalcogenides and also in process-related innovations.

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“…Recently, all‐solid‐state PbS QD‐doped glass fibers which can be used as gain media for fiber lasers and fiber amplifiers were fabricated through “melt‐in‐tube” method by our group . However, previous investigations of QD‐doped glasses were mainly concentrated on fabrication and controllable PL …”

Section: Introductionmentioning

confidence: 99%

Energy transfer process and temperature‐dependent photoluminescence of PbS quantum dot‐doped glasses

et al. 2018

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PbS quantum dot (QD)‐doped glasses were fabricated through melt‐quenching method. After heat treatment schedule, uniform QDs were precipitated in the glasses and near‐infrared emission covering 900‐1700 nm was obtained under excitation. From photoluminescence (PL) spectra and lifetime decay curves, the whole emission band of QD‐doped glasses consisted of emission from the 1S‐1S state and the trap state. While using excitation with higher energy, the full width at half maximum (FWHM) of QD‐doped glasses broadened because smaller QDs were excited. Energy transfer process among QDs was revealed by measuring the lifetime of different emission bands in PL spectrum and the energy transferred from smaller QDs with broader bandgap to bigger QDs with narrow bandgap. Temperature‐dependent PL and the corresponding lifetime decay curves of PbS QD‐doped glasses were analyzed. Temperature‐dependent bandgap structure of PbS QDs was obtained by using density functional theory (DFT) calculations. The results here give deep insight into optical properties of PbS QD‐doped glasses and it is beneficial to design and develop high‐performance QD‐based optoelectronic devices in theory.

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Lead Chalcogenide Quantum Dot‐Doped Glasses for Photonic Devices

Cited by 34 publications

References 51 publications

Quantum‐dots‐precipitated rare‐earth‐doped glass for ultra‐broadband mid‐infrared emissions

Quantum‐dots‐precipitated rare‐earth‐doped glass for ultra‐broadband mid‐infrared emissions

Glass and Process Development for the Next Generation of Optical Fibers: A Review

Energy transfer process and temperature‐dependent photoluminescence of PbS quantum dot‐doped glasses

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