Energy transfer between dyes on glass surfaces and ions in glasses

LaF3 In which manganese may replace all the zinc, and neodymium some lanthanum, Is studkd by dynamic and static methods. Both methods arrive at the same results Indicating Iinear dependence of transfer probability on &nor concentration. These results also demonstrate energy storage in the manganese-

Lead zinc gallium fluoride glass containing 2 mole% TmFS is shown to luminesce from 'Is (35200 cm-'), 'D, (28000), 'G, (2 1500) and 'Hq ( 12800) to several lower J levels. When the 24 mole% ZnF, is replaced by MnF, in the absence of thulium, the (broad band) quartet-to-sextet (ground state) emission

Energy transfer rates between Nd(II1) and Yb(II1) in glasses of the basic composition 36 PbFz:24 ZnFz:35 CaFs:2 AlF3:3 YF3:4 LaFs were calculated from donor decay curves, and applied for construction of acceptor luminescence curves. The transfer rates are time dependent and the energy loss by Nd(II1

Energy-transfer efficiencies between C?+ and Nd3+ various concentrations of Cr3+ and Nd'+. were measured in lithium-lanthanum-phosphate glasses doped by The transfer efficiencies obtained by decrease of donor lifetimes revealed different bekvior from those calculated directly from the increase of Nd