Local structural analysis of erbium-doped tellurite modified silica glass with x-ray photoelectron spectroscopy

• Main Authors: Ahmad Kamil, S. (Author), Chandrappan, J. (Author), Jose, G. (Author), Portoles, J. (Author), Steenson, P. (Author)
• Format: Article
• Language: English
• Published: Institute of Physics Publishing 2019
• Subjects: Blending; Device application; Doped glass; Er3+doped glasses; Erbium compounds; Experimental techniques; Films; Glass; laser ablation; Laser ablation; Laser produced plasmas; Metal nanoparticles; Nanoparticle formation; Non-bridging oxygen; optical materials; Optical materials; Oxygen; Oxygen gas pressure; Phase separation; Photoelectrons; Photonic devices; Photons; Plasma interactions; Preparation conditions; Refractive index; Semiconductor doping; Silica; Silicates; Target materials; Tellurium compounds; ultrafast lasers; Ultrafast lasers; X ray photoelectron spectroscopy; x-ray photoelectron spectroscopy
• Online Access: View Fulltext in Publisher; View in Scopus
• ISBN: 20531591 (ISSN)
• ISSN: 20531591 (ISSN)
• DOI: 10.1088/2053-1591/ab28eb

Ultrafast laser plasma doping (ULPD) is a recently developed technique that enables the blending of femtosecond laser produced plasma from a TeO2 (target) based glass with a SiO2 (substrate) without or minimum phase separation to form a silicate glass. The background oxygen gas pressure plays a major role in ULPD as it directly impacts the plasma plume characteristics, resulting in lower erbium doped tellurite modified silica (EDTS) thickness and refractive index at higher process gas pressure. X-ray photoelectron spectroscopy (XPS) used in this study to analyse the formation of EDTS and local bonding environment of its constituents. This report confirms the presence of both target materials and SiO2 in the resulting EDTS films. XPS of O 1 s core, confirms that bridging oxygen (BO) is more dominant compared to non-bridging oxygen (NBO) in the EDTS glass network, and the amount of BO is more stand out for higher gas pressures when the glass modifiers are relatively smaller in concentration. Our study revealed the nucleation Te and Er to form metal nanoparticles in glass under certain preparation conditions/doping concentration which were previously undetected using other experimental techniques. It is important to control this nanoparticle formation in engineering EDTS for photonic device applications. © 2019 IOP Publishing Ltd.