Spectroscopic properties of neodymium doped magnesium zinc sulfophosphate glass: Synergistic effects of titanium and silver nanoparticles embedment

“…This finding is in agreement with previous studies which show amplification of SPR band intensity that aligned with NPs size. There is no shift of SPR bands due to unchanged shape or dimensions [7][8].…”

“…The results elucidates that HT enhances PL through SPR intensification. The glass that was heat-treated for 6 hours shows declining in PL intensity due to high electron scattering or pure dephasing of the plasmon resonance [7]. The damping cause non-radiative channel and impact the phonon-photon density of the Nd 3+ ion.…”

“…Nevertheless, their small emission cross−section of Nd 3+ has limit them into practical application. Thus, inserting metal nanoparticles (NPs) into these glass has been proposed in order to enhance the luminescence intensity of Nd 3+ ions [7][8]. The emission gain of Nd 3+ likely to be improve by local surface plasmon resonance (SPR) effect through (i) enlargement of local electric field (LFE) and (ii) energy transfer (ET) [9].…”

“…Plasmon resonance bands of Ti NPs has shown able to improve luminescence chloroplasts in Bio-LEDs [10]. Thus in the current work, titanium nanoparticles (Ti NPs) were attempted to be grown within the glass and then heat-treated to oversee their effect on luminescence properties of REI doped glass [7]. As for now, no in-depth study has been conducted to oversee the impact of heat treatment (HT) on the optical properties of Nd 3+ doped magnesium zinc sulfophosphate glass when embedded in both pure titanium micro/nanoparticles (Ti NPs).…”

Titanium Nanoparticles Modified NIR Emission of Neodymium Doped Magnesium Zinc-Sulfophosphate Glass: Effect of Heat Treatment on Surface Plasmon Resonance Bands

“…This finding is in agreement with previous studies which show amplification of SPR band intensity that aligned with NPs size. There is no shift of SPR bands due to unchanged shape or dimensions [7][8].…”

“…The results elucidates that HT enhances PL through SPR intensification. The glass that was heat-treated for 6 hours shows declining in PL intensity due to high electron scattering or pure dephasing of the plasmon resonance [7]. The damping cause non-radiative channel and impact the phonon-photon density of the Nd 3+ ion.…”

“…Nevertheless, their small emission cross−section of Nd 3+ has limit them into practical application. Thus, inserting metal nanoparticles (NPs) into these glass has been proposed in order to enhance the luminescence intensity of Nd 3+ ions [7][8]. The emission gain of Nd 3+ likely to be improve by local surface plasmon resonance (SPR) effect through (i) enlargement of local electric field (LFE) and (ii) energy transfer (ET) [9].…”

“…Plasmon resonance bands of Ti NPs has shown able to improve luminescence chloroplasts in Bio-LEDs [10]. Thus in the current work, titanium nanoparticles (Ti NPs) were attempted to be grown within the glass and then heat-treated to oversee their effect on luminescence properties of REI doped glass [7]. As for now, no in-depth study has been conducted to oversee the impact of heat treatment (HT) on the optical properties of Nd 3+ doped magnesium zinc sulfophosphate glass when embedded in both pure titanium micro/nanoparticles (Ti NPs).…”

Titanium Nanoparticles Modified NIR Emission of Neodymium Doped Magnesium Zinc-Sulfophosphate Glass: Effect of Heat Treatment on Surface Plasmon Resonance Bands

“…Plasmonic nanoparticles (NPs) such as gold [1], silver [2], titanium [3] and titanium nitride [ [4], [5], [6]] exhibit unique optical properties by enhancing the local field proximity rare earth ions (REI) doped glass whenever their natural frequency matched with excitation frequency. This phenomenon is known as local surface plasmon resonance (LSPR).…”

Exploring the Impact of Plasmonic Nanoparticles on Photoluminescence of Er³⁺ - Doped Sodium Zinc Tellurite Glass for Solid-State Laser Applications

Spectrographic analysis of zinc-sulfate-magnesium-phosphate glass containing neodymium ions: Impact of silver–gold nanoparticles plasmonic coupling