Title :
Resonant energy transfer in praseodymium-thulium codoped ZBLAN fibre
Author :
Tessarin, S. ; Lynch, M. ; Donegan, J.F. ; Mazé, G.
Author_Institution :
Semicond. Photonics Group, Trinity Coll., Dublin, Ireland
fDate :
4/26/2004 12:00:00 AM
Abstract :
The authors have designed a thulium and praseodymium codoped ZBLAN fluoride fibre to investigate energy transfer processes between Tm3+ (donor) and Pr3+ (acceptor) ions. The concentrations (3000 ppm Tm3+ and 500 ppm Pr3+) were selected to maximise the absorption of the Tm3+ and energy transfer while minimising self-quenching. To characterise the codoped system, they measured the visible fluorescence emissions and their radiative lifetimes at 540 nm in both preform and fibre materials and compared the values obtained with those expected from single dopants. The energy-transfer processes have been further investigated by comparison with a rate equation model. The transfer rate obtained from the measurements is 300 s-1, and the predicted and observed fluorescence from the fibre are in good agreement.
Keywords :
aluminium compounds; barium compounds; fluorescence; lanthanum compounds; optical fibres; praseodymium; radiation quenching; radiative lifetimes; sodium compounds; thulium; zirconium compounds; 540 nm; ZBLAN:Pr,Tm; ZrF4-BaF2-LaF3-AlF3-NaF:Pr,Tm; codoped system; fibre materials; praseodymium-thulium codoped ZBLAN fibre; radiative lifetimes; rate equation model; resonant energy transfer; self-quenching; single dopants; visible fluorescence emissions;
Journal_Title :
Optoelectronics, IEE Proceedings -
DOI :
10.1049/ip-opt:20040286
