Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts

Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts

Divalent thulium has been doped into CsCaI₃, CsCaBr₃, CsCaCl₃ and RbCaI₃- a series of AMX₃ salts. Using previously published optical spectra, a series of parameterised energy level calculations have been performed. The calculated energy levels, optimised crystal field parameters and simulated optica...

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Main Author: Koster, Sophie Amelia
Language:en
Published: University of Canterbury. Physics and Astronomy 2014
Subjects:
Divalent thulium
thulium
Tm2+
Lanthanide
multiphonon
lifetime
emission
phonon
Energy level calculations
Online Access:http://hdl.handle.net/10092/9643
id ndltd-canterbury.ac.nz-oai-ir.canterbury.ac.nz-10092-9643
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spelling ndltd-canterbury.ac.nz-oai-ir.canterbury.ac.nz-10092-96432015-03-30T15:31:39ZEnergy Levels and Dynamics of Tm²⁺ Doped into AMX₃ SaltsKoster, Sophie AmeliaDivalent thuliumthuliumTm2+LanthanidemultiphononlifetimeemissionphononEnergy level calculationsDivalent thulium has been doped into CsCaI₃, CsCaBr₃, CsCaCl₃ and RbCaI₃- a series of AMX₃ salts. Using previously published optical spectra, a series of parameterised energy level calculations have been performed. The calculated energy levels, optimised crystal field parameters and simulated optical absorption spectra are presented. Theoretical predictions yield excellent approximation to the experimental data. Temperature dependent fluorescent lifetimes from the (³F₄,t₂g) and (³H₆,t₂g) excited (emitting) states have been measured using a pulsed dye laser. For CsCaBr₃ and RbCaI₃ doped with Tm²⁺, visible emission for the (³F₄,t₂g) state yields 10 K and 28 K lifetimes of 1.7 μs and 0.40 μs respectively. In both cases no emission is observed at room temperature. Considering direct multiphonon relaxation to the lower lying (³H₆,t₂g) levels, a simple energy gap law well accounts for the measured data with effective phonon energies in the range 100-200 cm⁻¹ - consistent with the phonon density of states in these low phonon energy hosts. Monitoring infrared emission from the (³H₆,t₂g) states, 14 K and 10 K lifetimes of 301 μs and 250 μs are found for CsCaBr₃ and CsCaCl₃ respectively. For CsCaBr₃ this value reduces to 270 μs at 200 K and is not quenched until 300 K, whilst for CsCaCl₃ emission is quenched by 170 K. This temperature dependent behavior is interpreted in terms of internal conversion via configurational crossing between the excited and ground state potential energy surfaces. Fitting the fluorescence lifetime data to a modified Mott equation, it is inferred that the potential barrier for non-radiative relaxation is five times larger in CsCaBr₃ compared to CsCaCl₃. This explains the fact that emission is still observable in the bromide host at room temperature.University of Canterbury. Physics and Astronomy2014-09-26T23:12:45Z2014-09-26T23:12:45Z2014Electronic thesis or dissertationTexthttp://hdl.handle.net/10092/9643enNZCUCopyright Sophie Amelia Kosterhttp://library.canterbury.ac.nz/thesis/etheses_copyright.shtml
collection NDLTD
language en
sources NDLTD
topic Divalent thulium
thulium
Tm2+
Lanthanide
multiphonon
lifetime
emission
phonon
Energy level calculations
spellingShingle Divalent thulium
thulium
Tm2+
Lanthanide
multiphonon
lifetime
emission
phonon
Energy level calculations
Koster, Sophie Amelia
Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts
description Divalent thulium has been doped into CsCaI₃, CsCaBr₃, CsCaCl₃ and RbCaI₃- a series of AMX₃ salts. Using previously published optical spectra, a series of parameterised energy level calculations have been performed. The calculated energy levels, optimised crystal field parameters and simulated optical absorption spectra are presented. Theoretical predictions yield excellent approximation to the experimental data. Temperature dependent fluorescent lifetimes from the (³F₄,t₂g) and (³H₆,t₂g) excited (emitting) states have been measured using a pulsed dye laser. For CsCaBr₃ and RbCaI₃ doped with Tm²⁺, visible emission for the (³F₄,t₂g) state yields 10 K and 28 K lifetimes of 1.7 μs and 0.40 μs respectively. In both cases no emission is observed at room temperature. Considering direct multiphonon relaxation to the lower lying (³H₆,t₂g) levels, a simple energy gap law well accounts for the measured data with effective phonon energies in the range 100-200 cm⁻¹ - consistent with the phonon density of states in these low phonon energy hosts. Monitoring infrared emission from the (³H₆,t₂g) states, 14 K and 10 K lifetimes of 301 μs and 250 μs are found for CsCaBr₃ and CsCaCl₃ respectively. For CsCaBr₃ this value reduces to 270 μs at 200 K and is not quenched until 300 K, whilst for CsCaCl₃ emission is quenched by 170 K. This temperature dependent behavior is interpreted in terms of internal conversion via configurational crossing between the excited and ground state potential energy surfaces. Fitting the fluorescence lifetime data to a modified Mott equation, it is inferred that the potential barrier for non-radiative relaxation is five times larger in CsCaBr₃ compared to CsCaCl₃. This explains the fact that emission is still observable in the bromide host at room temperature.
author Koster, Sophie Amelia
author_facet Koster, Sophie Amelia
author_sort Koster, Sophie Amelia
title Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts
title_short Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts
title_full Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts
title_fullStr Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts
title_full_unstemmed Energy Levels and Dynamics of Tm²⁺ Doped into AMX₃ Salts
title_sort energy levels and dynamics of tm²⁺ doped into amx₃ salts
publisher University of Canterbury. Physics and Astronomy
publishDate 2014
url http://hdl.handle.net/10092/9643
work_keys_str_mv AT kostersophieamelia energylevelsanddynamicsoftm2dopedintoamx3salts
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