then only a fraction of all radiations emitted from the source will be
detected by the detector. This fraction is determined by the solid angle sub-
tended by the detector on the source. The geometric efficiency,fg, is equal
to the number of radiations striking the detector divided by the total
number of radiations emitted by the source. Thus,
(8.5)
For a circular detector with radius r, it is equal to the area pr^2 of the detec-
tor divided by the total spherical area 4pR^2 , where Ris the distance between
a point source Sand the detector D(Fig. 8.9).
(8.6)
As the distance Rbetween the source and the detector increases, the fg
decreases, according to the inverse square law, that is,fg∝1/R^2 (Fig. 8.9A).
Thus the fgat 2Ris one fourth of the fgat R. The value of fgincreases with
the size of the detector. Also, the finite size of the radiation source affects
the fgvalues.
f
r
R
g=p
p2
4 2fg=
No. of radiations striking the detector
Total number of radiations emitted by the source98 8. Scintillation and Semiconductor Detectors
70 140 210 2801007550251.3 cm0.6 cmIntrinsic efficiency (%)Gamma ray energy (keV)NaI(Tl)
thicknessFig. 8.8. Dependence of intrinsic efficiency on photon energy and detector
thickness.