Irradiation effects on Ce3+thermoluminescence centres of mineral Caf2

Abstract

Trivalent rare-earth trace impurities are the emitters of thermoluminescence (TL) in the fluorite mineral. In this paper the cerium associated part of the TL spectrum is explained as originating from three types of Ce³⁺ centres: (1) compensated locally by substitutional O²⁻ impurity in the adjacent lattice position, (2) associated with interstitial F⁻ in the tetragonal or trigonal symmetry, (3) unassociated with other impurities. At smaller radiation doses (< 100 Gy) the emission is predominantly from O²⁻ compensated Ce³⁺ centres. The spectrum at high doses (≳100 Gy) originates from Ce³⁺ centres without O²⁻ compensators in the immediate vicinity. It is hypothesized that at low doses an electron is captured in the Ce³⁺ -O²⁻ impurity centre leading to the conversion of Ce³⁺ to Ce²⁺. At high doses, a hole also is captured, with the result that this Ce³⁺-O²⁻ centre then gets converted to Ce²⁺-O⁻. This changed configuration is stable up to 500°C. As a result of this, at high doses the glow peaks appearing below 300°C produce emission mainly from Ce³⁺ centres without O²⁻ compensators, whereas at lower doses the spectra are of O²⁻ compensated centres. The glow peaks of 75 and 150°C are attributed to perturbed V_k centres and that of 500°C is attributed to Ce³⁺-O²⁻ centre in which electron-hole exchange may take place locally.