Kinetic model for the annealing of fission tracks in minerals and its application to apatite

Kinetic model for the annealing of fission tracks in minerals and its application to apatite

Fission tracks are formed in apatite and other minerals after the passage of fission fragments, which deliver locally intense amounts of energy to the crystal lattice. It is well known that the observable mean track lengths are reduced due to thermal treatment. If the annealing kinetics are known, i...

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Bibliographic Details
Published in:Radiation measurements Vol. 41; no. 4; pp. 392 - 398
Main Authors: Guedes, S., Hadler N, J.C., Oliveira, K.M.G., Moreira, P.A.F.P., Iunes, P.J., Tello S, C.A.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-04-2006
Elsevier
Subjects:
Annealing
Apatite
Earth sciences
Earth, ocean, space
Exact sciences and technology
Fission track
Geochronology
Isotope geochemistry. Geochronology
Potential barrier
Annealing
Potential barrier
Model
Apatite
61.82.Ms
61.85. + p
29.40.Gx
93.85. + q
Fission track
thermal history
models
crystals
fission tracks
etching
annealing
apatite
correlation
phosphates
lattice
fission
temperature
geometry
kinetics
61.85.+p
93.85.+q Apatite
energy
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Summary:Fission tracks are formed in apatite and other minerals after the passage of fission fragments, which deliver locally intense amounts of energy to the crystal lattice. It is well known that the observable mean track lengths are reduced due to thermal treatment. If the annealing kinetics are known, it is sometimes possible to infer the thermal history a given sample experienced. Given the present lack of appropriate information on track formation, annealing and etching, researchers have used empirical models fitted to laboratory data on annealing to describe the annealing kinetics. In this work, a kinetic model is presented to describe the annealing process. It is based upon some experimental evidence. Instead of furnishing a complete and detailed description, it is intended to relate the observable quantities, namely, etched confined fission tracks, time and temperature based on simple hypotheses using a simplified view of the track. A kinetic model equation for the reduced mean track length, L / L 0 , as a function of temperature, T, and heating duration, t, which fits quite well the available literature, has been derived and is given by ( L / L 0 ) = exp { - n exp [ - w ′ ( U 0 - A 1 ln ( t ) + A 2 ln 2 ( t ) - k B T ) 1 / 2 ] } in which n is a parameter related to etching and track geometry, w ′ and U 0 are the width and the energy of a newly hypothesized potential barrier, respectively. A 1 and A 2 account for the dependence of the energy barrier on the duration of heating. Correlations with cell parameters of compositionally different apatites show that the barrier energy is the principal model descriptor for annealing.
ISSN:1350-4487
1879-0925
DOI:10.1016/j.radmeas.2005.06.040