Alkali borate glasses doped with ra

Alkali borate glasses doped with rare-earth ions have numerous practical applications in phosphors, solar energy converters and in a number of electronic devices. These glasses are relatively moisture resistant and possess high mechanical strengths when compared with the pure borate glasses. Extensive studies on optical properties of various borate glasses doped with different rare earth metal ions are available [1–6]. Among the three modifier oxides chosen to mix in the present glass system, viz., CaO, ZnO and CdO, ZnO is expected to shorten the time taken for solidification of glasses during the quenching process. Both ZnO and CdO are thermally stable and appreciably covalent in character [7]. Addition of alkaline-earth oxide CaO into these glass matrices is expected to increase the resistance of the glasses to the moisture [8]. The glass containing Li2O as network modifier was seen to be bubble free, highly stable and moisture resistant, suitable for a systematic optical analysis [9]. The matrix of these glasses offers a highly suitable chemical environment for lasing ions like Pr3þ, since this ion can be easily incorporated homogeneously into these glasses. Praseodymium doped glasses find variety of applications such as UV–vis–NIR
optical amplifiers, up-converters and other electro optic devices [10–12]. Among various rare earth ions, Pr3þ ion has a number of strong absorption bands where the pumping sources are easily available. Among various transitions, 3H4-3F4, 3P2, and 1D2 are found to be hypersensitive; the transition 3H4-3F4 is hypersensitive due to quadrupole selection rules whereas the hypersensitiveness of the other two transitions, 3H4-3P2, 1D2 is due to the influence of ligand environments [13]. The emission spectrum exhibits many fluorescent lines, blue and green in the visible region. The emission spectrum of Pr3þ ion is also well studied in a number of glasses like tellurite tungstate, tellurofluoro phosphate glasses, etc., [14,15]. Among various emission transitions the two transitions 3P0-3H5, 3F3 are found to exhibit significant intensities due to J–J mixing. Further, when these glasses are mixed with different network modifying ions, we may expect the structural modifications and local field variations around Pr3þ ion; such changes may have strong bearing on various luminescence transitions of Pr3þ ions in Li2O–MO–B2O3 glasses (where MO stands for ZnO, CaO and CdO).