Preparation and Mid-infrared Luminescence Properties of Transition Metal Co2+ Doped ZnS Sulfide Nanocrystals

Chang-xiu WEN; Hua-wei SHI; Mei-ling CHEN; Xu-sheng XIAO; Hai-tao GUO; Xiao-xia CUI

doi:10.3788/gzxb20204902.0216001

[1] R KIM, J EDWARD. Fiber optic sensors for environmental monitoring. Journal of Lightwave Technology, 15, 1468-1488(1996).

[2] MCMANUS J B, ZAHNISER M S, NELSON D D, et al. Recent progress in high precision atmospheric trace gas instruments using infrared quantum cade lasers[C]. Lasers & Electrooptics, IEEE, 2013.

[3] BUREAU B, BOUSSARDPLEDEL C, TROLES J, et al. Development of optical fibers f infrared sensing: state of the art recent achievements[C]. Microstructured Specialty Optical Fibres IV, 2015, 9507 : 950702.

[4] C KIM, D V MARTYSHKIN, V V FEDOROV. Mid-infrared Cr²⁺:ZnSe random powder lasers. Optics Express, 16, 4952-4959(2008).

[5] W H KIM, V Q NGUYEN, L B SHAW. Recent progress in chalcogenide fiber technology at NRL. Journal of Non-Crystalline Solids, 431, 8-15(2016).

[7] L D DELOACH, R H PAGE, G D WILKE. Transition metal-doped zinc chalcogenides: spectroscopy and laser demonstration of a new class of gain media. IEEE Journal of Quantum Electronics, 32, 885-895(1996).

[8] S MIROV, V FEDOROV, I MOSKALEV. Frontiers of mid-infrared lasers based on transition metal doped Ⅱ-VI semiconductors. Journal of Luminescence, 133, 268-275(2013).

[9] S B MIROV, V V FEDOROV, D V MARTYSHKIN. Progress in mid-IR Cr²⁺ and Fe²⁺ doped Ⅱ-VI Materials and Lasers. Optical Materials Express, 1, 898-910(2011).

[10] E M GAVRISHCHUK, E V YASHINA. Zinc sulfide and zinc selenide optical elements for IR engineering. Journal of Optical Technology, 71, 822-827(2004).

[11] MAETYSHKIN D V, FEDOV V V, GOLDSTEIN J T, et al. IR lasing of Cr: ZnSeAs2S3: As2Se3 composite materials[C]. Solid State Lasers XX: Technology Devices, 2011, 7912 : 79121I.

[12] E V KARAKSINA, R A MIRONOV, R M SHAPOSHNIKOV. The composite materials on the basis of As₂S₃ glass containing crystals ZnS and ZnS doped with Cr(2+). Journal of Optoelectronics and Advanced Materials, 13, 1433-1436(2011).

[13] X S LU, Y D ZHANG, J REN. Chalcogenide glasses with embedded ZnS nanocrystals: potential mid-infrared laser host for divalent transition metal ions. Journal of the American Ceramic Society, 101, 666-673(2018).

[14] A YANG, J QIU, J REN. 1.8-2.7 μm emission from As-S-Se chalcogenide glasses containing ZnSe:Cr²⁺ particles. Journal of Non-Crystalline Solids, 508, 21-25(2019).

[15] X S LU, Z Q LAI, R ZHANG. Ultrabroadband mid-infrared emission from Cr²⁺-doped infrared transparent chalcogenide glass ceramics embedded with thermally grown ZnS nanorods. Journal of the European Ceramic Society, 39, 3373-3379(2019).

[16] F VERGER, T PAIN, V NAZABAL. Surface enhanced infrared absorption (SEIRA) spectroscopy using gold nanoparticles on As₂S₃ glass. Sensors and Actuators B: Chemical, 175, 142-148(2012).

[17] GAO J L, LIU P, ZHANG J, et al. Fabrication of high dense ZnSe ceramic by spark plasma sintering: the effect of the powder process method[C]. Solid State Phenomena, Trans Tech Publications, 2018, 281 : 661666.

[18] C YANG, G FENG, S DAI. Femtosecond pulsed laser ablation in microfluidics for synthesis of photoluminescent ZnSe quantum dots. Applied Surface Science, 414, 205-211(2017).

[19] A SOBHANI, M SALAVATI-NIASARI. Optimized synthesis of ZnSe nanocrystals by hydrothermal method. Journal of Materials Science: Materials in Electronics, 27, 293-303(2016).

[20] N MYOUNG, J S PARK, A MARTINEZ. Mid-IR spectroscopy of Fe:ZnSe quantum dots. Optics Express, 24, 5366-5375(2016).

[21] U HOLZWARTH, N GIBSON. The Scherrer equation versus the 'Debye-Scherrer equation'. Nature Nanotechnology, 6, 534-534(2011).

CLP Journals