11.2. Quantities Related to Dosimetry 613
Combining all of the above, we can reach at the following relation for the exposure
from a radiation source.
X ∝
λdNt
r^2
=Γ
λdNt
r^2, (11.2.14)
wheretis the exposure time and Γ is generally known as thegamma constant.
Gamma constant is specific to the type of radioisotope and its values for most
isotopes are available in literature (see Table 11.2.3). The usual quoted units of Γ
areRcm^2 /M BqhandRcm^2 /mCih.
Table 11.2.3: Gamma constants and predominant decay modes other thanγ-decays
of some radioisotopes (4). All values are given inRcm^2 mCi−^1 h−^1.
Isotope (mode) Γ Isotope (mode) Γ Isotope (mode) Γ227
89 Ac(β) 2.2198
79 Au(β) 2.3228
88 Ra(β) 5.1
124
51 Sb(β) 9.8181
72 Hf(β) 3.1106
44 Ru(β) 1.7
72
33 As(γ, e+) 10.1 124
53 I(EC) 7.2
46
21 Sc(β)) 10.9
140
56 Ba(β) 12.4
130
53 I(β) 12.2
75
34 Se(EC) 2.0
7
4 Be(EC) 0.3
132
53 I(β) 11.8
110
47 Ag(EC, β) 14.3
47
20 Ca(β) 5.7
192
77 Ir(β) 4.8
22
11 Na(EC) 12.0
11
6 C(EC) 5.9
59
26 Fe(β) 6.4
24
11 Na(β) 18.4
134
55 Cs(EC, β) 8.7
140
57 La(β) 11.3
85
38 Sr(EC) 3.0
137
55 Cs(β) 3.3
28
12 Mg(β) 15.7
182
73 Ta(β) 6.8
38
17 Cl(β) 8.852
25 Mn(EC) 18.6121
52 Te(EC) 3.3
57
27 Co(EC) 0.965
28 Ni(β) 3.1187
74 W (β) 3.0
60
27 Co(β) 13.295
41 Nb(β) 4.288
39 Y(EC) 14.1
154
63 Eu(EC, β) 6.242
19 K(β) 1.465
30 Zn(EC) 2.7
72
31 Ga(β) 11.6
226
88 Ra(α) 8.25
95
40 Zr(β) 4.1