Decay chain

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In nuclear science, the decay chain refers to the radioactive decay of different discrete radiocative decay products as a chained series of transformations. Most radioactive substances do not decay directly to a stable state, but rather undergo a series of decays until eventually a stable isotope is reached.

Stages are referred to by their relationship to previous or subsequent stages. A parent isotope is one that undergoes decay to form a daughter isotope. The daughter isotope may be stable or it may decay to form a daughter isotope of its own. The daughter of a daughter isotope is sometimes called a granddaughter isotope.

The intermediate stages are often far more dangerous than the original radioisotope. For example, pure natural uranium metal is not dangerously radioactive, but many lumps of pitchblende, a uranium ore, are dangerously radioactive because of the radium and other daughter nuclei they contain. Radium itself is extremely dangerous for its radioactivity alone, but its chief danger is the gaseous radon it generates as the next stage in the decay chain.

1 Types
2 Thorium series
3 Radium series
4 Actinium series
5 Neptunium series
6 External links

[edit] Types

This diagram illustrates the four decay chains: thorium (in blue), radium (in red), actinium (in green), and neptunium (in purple).

The four most common modes of radioactive decay are: alpha decay, beta minus decay, beta plus decay (considered as both positron emission and electron capture) and isomeric transition. Of these decay processes, alpha decay changes the atomic mass number of the nucleus, and always decreases it by four. Because of this, almost any decay will result in a nucleus whose atomic mass number has the same residue mod 4, dividing all nuclides into four classes. The members of any possible decay chain must be drawn entirely from one of these classes.

Three main decay chains (or families) are observed in nature, commonly called the thorium series, the radium series (not uranium series), and the actinium series, representing three of these four classes, and ending in three different, stable isotopes of lead. The mass number of every isotope in these chains can be represented as A=4n, A=4n+2 and A=4n+3, respectively. The starting isotopes of these three have existed since the formation of the earth. The fourth chain, the neptunium series with A=4n+1, due to quite short half life time of its starting isotope ²³⁷Np, is already extinct, except for the final rate-limiting step. The ending isotope of this chain is ²⁰⁵Tl. Some older sources give the final isotope as ²⁰⁹Bi, but it was recently discovered that ²⁰⁹Bi is radioactive with half-life of 1.9×10¹⁹ years.

There are also many shorter chains, for example carbon-14. On the earth, most of the starting isotopes of these chains are generated by cosmic radiation.

In the tables below, the minor branches of decay (with the branching ratio of less than 0.0001%) are omitted. The energy release includes the total kinetic energy of all the emitted particles (electrons, alpha particles, gamma quanta, neutrinos, Auger electrons and X-rays) and the recoil nucleus.

[edit] Thorium series

The 4n chain of Th-232 is commonly called the "thorium series". In this chart, the letter 'a' represents a Julian year (365.25 days).

nuclide	decay mode	half life	energy released, MeV	product of decay
Th 232	α	1.405·10¹⁰ a	4.081	Ra 228
Ra 228	β^-	5.75 a	0.046	Ac 228
Ac 228	β^-	6.25 h	2.124	Th 228
Th 228	α	1.9116 a	5.520	Ra 224
Ra 224	α	3.6319 d	5.789	Rn 220
Rn 220	α	55.6 s	6.404	Po 216
Po 216	α	0.145 s	6.906	Pb 212
Pb 212	β^-	10.64 h	0.570	Bi 212
Bi 212	β^- 64.06% α 35.94%	60.55 min	2.252 6.208	Po 212 Tl 208
Po 212	α	299 ns	8.955	Pb 208
Tl 208	β^-	3.053 min	4.999	Pb 208
Pb 208	.	stable	.	.

[edit] Radium series

The 4n+2 chain of U-238 is commonly called the "radium series".

nuclide	decay mode	half life	MeV	product of decay
U 238	α	4.468·10⁹ a	4.270	Th 234
Th 234	β^-	24.10 d	0.273	Pa 234
Pa 234	β^-	6.70 h	2.197	U 234
U 234	α	245500 a	4.859	Th 230
Th 230	α	75380 a	4.770	Ra 226
Ra 226	α	1602 a	4.871	Rn 222
Rn 222	α	3.8235 d	5.590	Po 218
Po 218	α 99.98 % β^- 0.02 %	3.10 min	6.115 0.265	Pb 214 At 218
At 218	α 99.90 % β^- 0.10 %	1.5 s	6.874 2.883	Bi 214 Rn 218
Rn 218	α	35 ms	7.263	Po 214
Pb 214	β^-	26.8 min	1.024	Bi 214
Bi 214	β^- 99.98 % α 0.02 %	19.9 min	3.272 5.617	Po 214 Tl 210
Po 214	α	0.1643 ms	7.883	Pb 210
Tl 210	β^-	1.30 min	5.484	Pb 210
Pb 210	β^-	22.3 a	0.064	Bi 210
Bi 210	β^- 99.99987% α 0.00013%	5.013 d	1.426 5.982	Po 210 Tl 206
Po 210	α	138.376 d	5.407	Pb 206
Tl 206	β^-	4.199 min	1.533	Pb 206
Pb 206	.	stable	.	.

[edit] Actinium series

The 4n+3 chain of U-235 is commonly called the "actinium series".

nuclide	decay mode	half life	energy released, MeV	product of decay
Pu 239	α	2.41·10⁴ a	5.244	U 235
U 235	α	7.04·10⁸ a	4.678	Th 231
Th 231	β^-	25.52 h	0.391	Pa 231
Pa 231	α	32760 a	5.150	Ac 227
Ac 227	β^- 98.62% α 1.38%	21.772 a	0.045 5.042	Th 227 Fr 223
Th 227	α	18.68 d	6.147	Ra 223
Fr 223	β^-	22.00 min	1.149	Ra 223
Ra 223	α	11.43 d	5.979	Rn 219
Rn 219	α	3.96 s	6.946	Po 215
Po 215	α 99.99977% β^- 0.00023%	1.781 ms	7.527 0.715	Pb 211 At 215
At 215	α	0.1 ms	8.178	Bi 211
Pb 211	β^-	36.1 m	1.367	Bi 211
Bi 211	α 99.724% β^- 0.276%	2.14 min	6.751 0.575	Tl 207 Po 211
Po 211	α	516 ms	7.595	Pb 207
Tl 207	β^-	4.77 min	1.418	Pb 207
Pb 207	.	stable	.	.

[edit] Neptunium series

4n + 1 chain:

nuclide	decay mode	half life	energy released, MeV	product of decay
Pu 241	β^-	14.4 a	0.021	Am 241
Am 241	α	432.7 a	5.638	Np 237
Np 237	α	2.14·10⁶ a	4.959	Pa 233
Pa 233	β^-	27.0 d	0.571	U 233
U 233	α	1.592·10⁵ a	4.909	Th 229
Th 229	α	7.54·10⁴ a	5.168	Ra 225
Ra 225	β^-	14.9 d	0.36	Ac 225
Ac 225	α	10.0 d	5.935	Fr 221
Fr 221	α	4.8 m	6.3	At 217
At 217	α	32 ms	7.0	Bi 213
Bi 213	α	46.5 m	5.87	Tl 209
Tl 209	β^-	2.2 min	3.99	Pb 209
Pb 209	β^-	3.25 h	0.644	Bi 209
Bi 209	α	1.9·10¹⁹ a	3.14	Tl 205
Tl 205	.	stable	.	.