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| F (cm-2 s-1) = CBglg(1 - e-x/lg); | (1) |
reducing to:
| F » CBgx | (1a) |
for thin shields, where x is shield thickness in g cm-2 ( i.e. the activity is reduced by a factor x/lg compared with a thick slab). The attenuation length lg is of order 20-25 g cm-2 for a typical equilibrium photon cascade.
| 1cph cm-2 | ® | < 500 ppb U; or |
| ® | < 2000 ppb Th; or | |
| ® | < 60 Bq kg-1 ~ 3500 dpm kg-1 ~ 5 Mtru 210Pb |
(cph = counts per hour; ppb = parts per billion = parts in 109 ; dpm = disintegrations per minute; tru2 = disintegrations per day per kg).
| Ni = 527 t½; | (2) |
and the mass concentration to give one disintegration per day per kg is:
| C = 8.75 ´ 10-25 Ai t½. | (3) |
If the isotope is present in the natural element (mean atomic mass A) with an atomic fraction fi, then these become:
| N = 527 t½fi | (2a) |
| C = 8.75 ´ 10-25 Ai t½/fi; | (3a) |
for a chain of n decays (from Th or U), these must be divided by n. For Th, n = 10; for U, there is the added complication that 95.6% of primary decays are 238U (n = 14), and 4.4% 235U (n = 11), giving n = 13.87.
For materials external to the target, the short-range a, b particles have low probability of producing `events' - though bremsstrahlung from higher energy bs must be considered. Consequently, we are generally only concerned with the g activity, for which we have (X-rays not included):-
ng = 0.107(K), 2.65(Th), 2.20(U).
In the target itself, b activity is also relevant (a decays, being contained within the target apart from those within a few mm of the target surface, should be rejected by their ~ MeV energies), and we have:-
nb = 0.893(K), 4(Th), 5.91(U).
Hence:
| 1 ppm K | ® | 0.0309 Bq kg-1 | = | 1.86 dpm kg-1 | = | 2.67 ktru; |
| ® | 0.00331 Bq kg-1 | = | 0.199 dpm kg-1 | = | 0.286 ktru in g |
(ppm = parts per million);
alternatively,
1 Bq kg-1 of 40 K ® 32.3 ppm K; 1 Bq kg-1 in g ® 302 ppm K.
For disintegrations of the parent 232Th (or any daughter on a 100% branch), we have:
1 ppb Th ® 0.00406 Bq kg-1 ® 0.243 dpm kg-1 ® 351 tru;
and, in particular,
1 Bq kg-1 of 228Ac ® 246 ppb Th; 1 Bq kg-1 of 208Tl ® 685 ppb Th (36% branch).
If the decay chain (232Th ® 208Pb + 6a + 4b+ 2.65g) is in equilibrium, we also have, from the full chain,
| 1 ppb Th | ® | 0.0406 Bq kg-1 | = | 2.43 dpm kg-1 | = | 3.51 ktru | (a + b) |
| ® | 0.0108 Bq kg-1 | = | 0.645 dpm kg-1 | = | 0.929 ktru | (g) | |
| ® | 0.0162 Bq kg-1 | = | 0.974 dpm kg-1 | = | 1.40 ktru | (b). |
For `natural' (non-depleted) U, parent decays are:
| 1 ppb U | ® | 0.0123 Bq kg-1 | ® | 0.738 dpm kg-1 | ® | 1.06 ktru | from 238U |
+ |
5.7 ´ 10-4 Bq kg-1 | ® | 0.034 dpm kg-1 | ® | 49 tru | from 235U, | |
| ® | 0.0129 Bq kg-1 | ® | 0.772 dpm kg-1 | ® | 1.11 ktru | in all; |
and
1 Bq kg-1 of 226Ra or 214Bi ® 81.3 ppb U; 1Bq kg-1 of 235U ® 1.76 ppm U.
For decay chains in equilibrium (238U ® 206Pb + 8a + 6b+ 2.18g; 235U ® 207Pb + 7a + 4b+ 2.53g), we have, from the full chain,
| 1 ppb U | ® | 0.179 Bq kg-1 | = | 10.8 dpm kg-1 | = | 15.5 ktru | (a + b) |
| ® | 0.0284 Bq kg-1 | = | 1.70 dpm kg-1 | = | 2.46 ktru | (g) | |
| ® | 0.0752 Bq kg-1 | = | 4.51 dpm kg-1 | = | 6.50 ktru | (b). |
