Patent Number: 047449390
Section: claims

1. A method for correcting for burn-in in a fissionable neutron dosimeter employing a fissionable isotope (Z, A), comprising the steps of: (a) forming two solid state track recorders with fission deposits of the same fissionable material as the fissionable neutron disometer;  (b) exposing a first of the two solid state track recorders and the fissionable neutron dosimeter to a first neutron fluence, at least effectively with the same neutron flux-time history with respect to the location of one of them in the first neutron fluence, whereafter the fissionable neutron dosimeter indicates a total number of fissions F.sub.T which is to be corrected for the burn-in;  (c) irradiating the two solid state track recorders with a second neutron fluence;  (d) determining the amount of burn-in P.sub.Z', A' of a higher order isotope (Z', A'), wherein A'&gt;A, in the fission deposit of the first solid state track recorder from the difference between the absolute numbers of fissions per unit volume of the fission deposits in the two solid state track recorders;  (e) determining the number of fissions F.sub.Z', A' of the higher order isotope (Z', A') in the fissionable deposit of the first solid state track recorder during the exposure to the first neutron fluence; and  (f) using P.sub.Z', A' and F.sub.Z', A' to correct the total number of fissions F.sub.T indicated by the fissionable neutron dosimeter, to provide a value corresponding to the fission rate of the fissionable isotope that is corrected for the fissions due to the burn-in. 2. The method as recited in claim 1, wherein the first neutron fluence is time independent or a separable function of time and neutron energy. 3. The method as recited in claim 2, wherein the step (e) of determining the number of fissions F.sub.Z', A' of the higher order isotope (Z', A') further comprises the substep of exposing a further fission neutron dosimeter prepared for the higher order isotope (Z', A') to at least effectively the same neutron flux-time history at the same location in the first neutron fluence. 4. The method as recited in claim 2, wherein the fission neutron dosimeter for which the burn-in is to be corrected is selected from the group consisting of a radiometric fission dosimeter and a solid state track recorder fission dosimeter. 5. The method as recited in claim 3, wherein the further fission neutron dosimeter is selected from the group consisting of a radiometric fission dosimeter and a solid state track recorder fission dosimeter. 6. The method as recited in claim 2, wherein the step (b) further comprises the substep of exposing the first solid state track recorder fission deposit and the fissionable neutron dosimeter to be corrected for the burn-in at separate times but for corresponding periods and neutron fluxes at the same location. 7. The method of claim 1, further comprising the step of determining the value of the first neutron fluence based on the total number of fissions F.sub.T as corrected for the burn-in.