Japanese Journal of Medical Physics (Igakubutsuri) Volume 31, Issue 2

Evaluating Photonuclear Activation for Clearance of Decommissioned Medical Linear Accelerators

In a linear accelerator (linac) that operates at greater than an accelerating energy of 10 MV, neutrons are generated by a photonuclear reaction and the head section of the linac becomes radioactive. The purpose of this research is to obtain data for ensuring the safety of linac decommissioning and upgrading.
The decommissioned linac investigated in this study was a Clinac 2100 C/D (Varian) installed in April 1999. Its total time of use was 2757.7 h (equivalent to 496,386 Gy). The dosage for its last three months of use was 7213.67 Gy. After being allowed to sit for a 7-day cooling period, the apparatus was disassembled and the parts of the gantry head portion were removed. The ambient dose equivalent rates, H*(10), (μSv/h) from the removed parts were measured in air, at a location with low background, by using a gamma ray scintillation survey meter. The target was also analyzed with an HP-Ge semiconductor detector, in order to identify the nuclides responsible for the observed radiation.
On day 7 after the last use of the linac, the ambient dose equivalent rates, H*(10), (μSv/h) in air at the surface of all parts, except the target and the beryllium window, were within the limit of normal background radiation. The measured value (μSv/h) for the beryllium window decreased to within the background limit on day 10. The measured value (μSv/h) of the target decreased to about 1.5 times the background on day 19. At a distance of 10 cm, all the parts were within the background limit after the initial 7-day cooling period. In the analysis of the target with the HP-Ge semiconductor detector, peaks at 125, 333, 352, 356, 426, 511, 583, 609, 689, 811, 835, 911, 969, 1091, 1099, 1120, 1173, 1238, 1292, 1333, 1461 and 1764 keV were detected on day 23. Seven months after the linac was last used, peaks were detected at 352, 511, 583, 609, 835, 911, 969, 1120, 1173, 1238, 1333, 1461 and 1764 keV. From these results, the natural radioactive nuclides can be assigned as ⁴⁰K, ²⁰⁸Tl, ²¹⁴Pb, ²¹⁴Bi and ²²⁸Ac; the short half-life nuclides can be assigned as ⁵⁹Fe, ⁵⁸Co, ¹⁸⁵W and ¹⁹⁶Au; and the long half-life nuclides can be assigned as ⁵⁴Mn and ⁶⁰Co.
These results show that photonuclear activation of parts is important in regard to clearance. Currently, there are no regulations that specify criteria for evaluating radioactivation. Such criteria are needed to establish suitable protocols for the clearance of radioactivated materials.