An optimized method for neutron dose evaluation based on Na-24 activity distribution in the human body

The neutron dose resulting from external irradiation can be evaluated by measuring the counts of characteristic gamma rays produced by Na-24 in the human body. The detection geometry with the highest detection efficiency for measuring the whole-body Na-24 activity has not been studied. In this work, the MCNP code is used to calculate the spatial distribution of Na-24 in the human body irradiated by neutrons with different energies in different irradiation geometries. The fluence distribution of Na-24 characteristic gamma rays on the body surface is calculated. The counts of Na-24 characteristic gamma rays induced by monochromatic neutron irradiation are simulated to fit the scenarios of neutron irradiation by a continuous energy spectrum neutron. When the spontaneous neutrons from Cf-252 with 1Gy dose irradiate the human body, (3.63-4.35) x 10(10 24)Na atoms are produced. The lower detection limit for the neutron absorption dose is reduced from similar to 100 to less than 1 mGy when the radiation detector is placed over the back of the human body close to the liver. The relative error between the measured counts of Na-24 characteristic gamma rays caused by Cf-252 neutron irradiation and the counts fitted by monochromatic neutron irradiation data is less than 5.7%. The neutron dose received from a continuous energy spectrum neutron can be acquired quickly and accurately by weighted summing of the data for monochromatic neutron irradiations calculated in this paper, which is more convenient and practical than the previous method.