An investigation of the dosimetric and kinetic properties of sand using ESR and TL techniques

• Reporting of new additional results about the use of ESR and TL spectroscopy on irradiated sand sample.
• Detailed kinetic and dosimetric study on irradiated sand sample by using ESR and TL techniques.
• Calculation of sand sample kinetic parameters using various heating rates and deconvolution.
• Estimation of sand sample ESR activation energy using isothermal decay measurements.

In this research, the general dosimetric and kinetic properties of sand from a beach in southern Turkey were investigated using electron spin resonance (ESR) and thermoluminescence (TL) techniques. The ESR dose response curve presents linear behaviour in the dose range of 250–1000 Gy followed by sublinear behaviour in the dose range of 2–8 kGy. Kinetic behaviors and activation energy of the free radical were also calculated using the data obtained from annealing studies performed at four different temperatures (220, 240, 260 and 280 °C). The activation energy value was calculated as 1.47 eV. The long-term fading of the ESR signal at room temperature turned out to be best described by a second-order kinetic decay function. The presence of measurable ESR signal intensity even after a storage period of 90 days was considered as providing an opportunity in the dose estimation of irradiated sand sample. Although the TL glow curve of the natural (unirradiated) sand sample only has a single broad peak at 317 °C, the glow curve of the irradiated sample has four glow peaks located at ~115 °C, ~156 °C, ~231 °C and ~308 °C and their intensity tends to be increased with absorbed dose.Tmax−Tstopand glow curve fitting results showed that presence of at least five peaks located at ∼116 °C, 149 °C, 228 °C, 306 °C and 360 °C. This result suggests that the apparently single glow peak D may consist of two or more overlapping glow peaks. According to the thermal fading of the sand sample at room temperature, the TL signal intensities (23 °C and 308 °C) were found to be quite large after 30 days of storage this allows a more accurate measurement of the glow peak intensity. The additive dose method, variable heating rate method (VHRM), Tmax−Tstop and glow curve fitting method were used to number of peaks, dosimetric properties and kinetic parameters. This study shows that ESR and TL techniques could be successfully used to investigate the kinetics and dosimetric properties of sand sample. Furthermore, the results in this study plus the previous work done by the authors suggest that sand could, by using the ESR and TL techniques, be a suitable material for alternative dose measurement.