ELUCIDATING THE EFFECTS OF NEODYMIUM NANOPARTICLES ON JUDD-OFELT AND OPTICAL PARAMETERS OF ZINCTELLURITE GLASS FOR FIBER LASERS

• Published in: PROCESSES OF PETROCHEMISTRY AND OIL REFINING
• Main Authors: Azlan, Muhammad N.; Suriani, Abu B.; Al-Hada, Naif Mohammed; Umar, Saad A.; Kenzhaliyev, Boqdaulet K.; Dametken, Fischer; Zaid, Mohd Hafiz M.; Hisam, Rosdiyana; Iskandar, Syeed M.; Yusof, Nur N.
• Format: Article; Proceedings Paper
• Language: English
• Published: Y H MAMMADALIYEV INST PETROCHEMICAL PROC, NATL ACAD SCI, BAKU, AZERBAIJAN 2024
• Subjects: Engineering
• Online Access: https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-recordWOS:001373768200002

The Judd-Ofelt analysis of neodymium nanoparticles doped zinctellurite glass were performed to determine their spectral parameters. A glass sample of neodymium nanoparticles doped zinc-tellurite with chemical composition of 0.47TeO2 2 + 0.2B2O3 2 O 3 + 0.29ZnO + 0.05Nd2O3 2 O 3 was synthesized by using conventional melt quenching method. We select 0.05 mol fraction of neodymium nanoparticles in tellurite glass as it gives the optimum results for glass stability and spectral intensities. The Judd-Ofelt parameters were determined by using least-square fitting method. It was found that the observed that neodymium nanoparticles doped zinctellurite glass exhibit judd-ofelt parameters as follows; 522 2 = 2.623, 524 4 = 0.174, 526 6 = 0.837 and found in the following 522 2 < 524 4 <526 6 trend. The hypersensitive transition was highly related to the 522 2 parameter. Furthermore, the hypersensitive at 4 I 9/2 -> 4 G 5/2 transition affect the value of 522 2 which satisfies the selection rule Delta s=0, Delta l <= 2 <= 2 and Delta J <= 2. <= 2. The 524 4 parameter was related mainly to the bulk properties of the host matrix meanwhile the 526 6 parameter was related to the rigidity of the glass matrix. The extinction coefficient and fermi energy of the glass system were determine using least-square fitting method. It was revealed that the studied glass system exhibit reduction in extinction coefficient due to the change of wavelength. It was found that the Fermi energy decreases along with neodymium nanoparticles concentration. The decreasing trend of Fermi energy, EF F indicates the enhancement of semiconducting properties. Therefore, the studied glass system have an excellent potential to be utilized in semiconducting materials. Therefore, the investigated glass materials may provide a good material for fiber lasers.