Optimising the Eu2O3 concentration and tuning the photoluminescence attributes of Eu2O3 doped borate glasses by Co-doping with silver nanoparticles

Efficacy of silver nanoparticles on photoluminescence properties on optimized Eu2O3 doped borate glasses has been studied and discussed in detail. The presence of homogeneously distributed and spherically shaped Ag nanoparticles was confirmed by electron microscopic images. With increase of AgNO3 concentration the photoluminescence intensity of Eu3+ transitions improved up to 0.6 mol% and subsequently quenched at 0.8 mol% of AgNO3. The enhancement in photoluminescence properties observed as the AgNO3 concentration raised to higher level was ascribed to local field effect and transmit of energy from Ag nanoparticles to the tri-positive europium ions. While the reduction in photoluminescence properties at higher doping level of AgNO3 was attributed to reverse transmit of energy from tri-valent europium ions to Ag nanoparticles. Other mechanisms liable for the attenuation in photoluminescence properties are also highlighted. The energy transfer from Eu3+ ions to Ag-0 nanoparticles was responsible for the reduction in radiative lifetime magnitudes. The studies suggest the glass sample containing 0.6 mol% of AgNO3 (i.e. SNBEuAg0.6) beneficial for optoelectronic and photonic applications.

Automated summary

The study investigated the effect of silver nanoparticles on the photoluminescence properties of optimized Eu2O3 doped borate glasses. It was found that the photoluminescence intensity of Eu3+ transitions improved up to 0.6 mol% of AgNO3, but subsequent quenched at 0.8 mol%. The enhancement was attributed to local field effect and energy transfer, while the reduction was due to reverse energy transfer.