Gamma-ray dosimetry by spectrofluorimetry of phenylacetic acid solution

Aqueous solutions of phenylacetic acid have been evaluated for possible use in γ-ray dosimetry. When aerated aqueous phenylacetic acid solutions are irradiated, photoflourescent species are formed and identified as hydroxyphenylacetic acid. When excited by ultraviolet light at 280 nm, the radiation-induced product shows an emission spectrum with a maximum at 307 nm. The intensity of the emission peak at 307 nm (as well as the area under the peak from 290 to 350 nm) is a linear function of absorbed dose from 0.5 to 25 Gy. This aqueous dosimeter is about ten times more sensitive than that of the conventional ferrous sulfate solution (Fricke) dosimeter. The differences in response at dose rates in the range 0.0055–67 Gy/min are negligible. Conversely, at higher dose rates (170 Gy/min), although the response is linear with dose up to 135 Gy and with proper calibration can be used up to 350 Gy, the photofluorescence signal is somewhat greater than in the lower dose rate range. The estimated random uncertainty limits (1σ) of readings of absorbed dose by the dosimeter are approximately ±2% at a dose of 10 Gy. The fluorescence signal is very much affected by the hydrogen ion concentration of the solution and the intensity of the signal is greatest in the pH range 5–9.5. The radiation chemical yield of the fluorescing species is little influenced by moderate changes in the concentration of phenylacetic acid or by deaeration of the solution. The signal is stable up to at least four weeks, if the solution after irradiation is stored at low temperature (ca. 5°C). However, when stored at room temperature, and in room light, the signal is stable only up to about four days.