Depth identification accuracy of a three layer phoswich PET detector module

We describe a PET detector module that provides three levels of depth-of-in teraction (DOI) information. The detector is a 9 x 9 array of 2 mm x 2 mm x 12 mm deep phoswich crystal elements, each consisting of 4 mm long LSO (en trance layer), GSO (middle layer) and EGO (exit layer) crystals joined opti cally together end-to-end. The EGO exit layer is directly coupled to a mini ature position-sensitive photomultiplier tube (PSPMT). Delayed charge integ ration, a method that exploits differences in the light decay times of thes e scintillators, is used to determine the layer-of-interaction. DOI accurac y, measured by scanning a slit source of 511 keV radiation along the length of the module was 86% for the LSO layer, 80% for the GSO layer and 84% for the EGO layer. Energy resolution at 511 keV was 19% for LSO, 21% for GSO a nd 40% for EGO. Apparent gain differed between layers in the ratios 2.7:1.9 :1.0 (LSO:GSO:BGO). Crystal separation was good between crystals in the LSO layer, acceptable between crystals in the GSO layer and poor between cryst als in the EGO layer due, primarily, to the pronounced spatial non-linearit y of the PSPMT. The delayed charge integration method, however, does appear suitable for obtaining multi-level depth information when DOI effects are particularly significant, e.g. in very small ring diameter PET scanners for small animal imaging.