How is cluster decay different from spontaneous fission? --Smack (talk) 02:47, 25 Jun 2005 (UTC)

SF happens as fission, where the daughter products are fairly random. You will never know if any single atom will decay into Tc-100 and Sb-124 or something else. In cluster decay there is always the same particle emitted. --metta, The Sunborn 18:28, 25 Jun 2005 (UTC)

Could someone add a definition for "decay percentage"?

Barium-114

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Although I found some references suggesting that 114Ba might cluster-decay, subsequent studies seem to rule it out. See, for example, [1] or [2]. I've commented it out of the table. -- Xerxes (talk) 22:03, 21 April 2008 (UTC)Reply

OE91Pa231?

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A cluster emission decay mode is not shown in my 15th edition isotopes chart. And other than that, the rest of the emitted nuclides are noted to be of even numbered element nuclei with possibly an odd number of neutrons. This brings up the possibility that the emitted particle is that of a structure that is an accumulation of a (2Z)times an integer nuclide which might be sheared off from the top of the original nucleus. This would be an indication of the existence of a shear strength fault in the structure due to the nature of their physical construction properties. This possibility is not apparent under the assumption of a spherical shape for the parent nucleus. However if the shape of the parent nucleus were 4 sided the possibility of a stressed nuclear corner condition becomes apparent.WFPM (talk) 18:28, 1 December 2012 (UTC)Reply

"24Ne" CD as decay mode - full set

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In current text:

Penetrability theory predicted eight decay modes: 14C, 24Ne, 28Mg, 32,34Si, 46Ar, and 48,50Ca from the following parent nuclei: 222,224Ra, 230,232Th, 236,238U, 244,246Pu, 248,250Cm, 250,252Cf, 252,254Fm, and 252,254No.

However, {{NUBASE2020}} has a different set (defined as "24Ne = heavy cluster decay"). Below is a table to gather & hunt the complete set. Technically, I am working in {{Isotopes/decay-mode/overview}} (content documentation), and this tech set. -DePiep (talk) 06:48, 11 February 2023 (UTC)Reply

developing table as of 06:48, 11 February 2023 (UTC)
to improve: source by examplary isotope from NUMBASE, enwiki?
decay source example note
14C NUBASE
20Ne NUBASE
24Ne NUBASE
25Ne NUBASE
26Ne NUBASE only as part of 24Ne+26Ne
24Ne+26Ne NUBASE 234U
28Mg NUBASE
30Mg NUBASE
32Si NUBASE
34Si 242Cm NUBASE
46Ar ? (enwiki)
48Ca ? (enwiki)
50Ca ? (enwiki)

DePiep (talk) 06:48, 11 February 2023 (UTC)Reply

The explanation re 34Si, 46Ar, 48Ca, and 50Ca is that those decay modes were predicted here, but have never been seen yet. Double sharp (talk) 15:21, 11 February 2023 (UTC)Reply

Theoretical calculation of cluster decay half-lives

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If the formula given here is also true for cluster decays, then to find the lowest stable cluster decay mode is to find the emission nuclide   with the smallest  , where   is the mass number of  ,   is the Q value of the decay mode, and   is respectively the charge number of the parent nuclide and  .

Although the nuclide ejected in cluster decays seems to be arbitrary, fortunately, the formula shows that it is enough to consider the following 10 cluster decay modes in addition to alpha decay: 12C, 14C, 16O, 24Ne, 26Mg, 30Si, 32Si, 36S, 46Ca and 48Ca.

Suppose that one wants to find the most stable nuclide that is energetically allowed to decay, and fission into at least three parts is ignored. That nuclide must have the lowest energy among its isobars, because cluster decays are neglegible compared to beta decays and double beta decays. Now suppose that the formula given in the above link also applies to cluster decays. For nuclides having the lowest energy among their isobars, there are several regions:

For mass numbers ≤ 92 (other than 5 and 8), no cluster decay can occur.

For mass numbers 93-142 (starting from 3 neucleons above 90Zr with semi-magic Z and magic N), 36S emission kicks in, but these nuclides are among the most stable ones, so only emission of relatively heavier nuclides can occur. The lowest stable cluster decay modes are among emission of 16O, 26Mg, 30Si, 32Si, 36S, 46Ca and 48Ca. But of course, such processes take long time beyond imagination.

Note that all isotopes of zirconium with N ≥ 50 (this includes all (almost) beta-stable ones), plus 100Mo, are still stable to 36S emission; this is somewhat like that all N = 82 isotones with Z ≤ 62 (includes all beta-stable ones) are stable to alpha decay. Still, none of 94Zr, 96Zr and 100Mo is stable to 48Ca emission (with a half-life greater than 102000 years, perhaps).

For mass numbers ≥ 143 (starting from 3 neucleons above 140Ce with semi-magic Z and magic N), alpha decay kicks in. Alpha half-lives for nuclides in this region are usually short enough (≤ Tα1/2(161Dy) ~ 10132.24 y), so cluster decays can be ignored. But still, 152Sm, 153Eu, 155,156,157,158Gd, 159Tb, 162,163,164Dy, 165Ho, 201,202Hg, and 205Tl have long enough alpha half-lives (≥ Tα1/2(153Eu) ~ 10144.69 y), so their main decay modes will be cluster decay. The least stable cluster decay modes are among emission of 12C, 14C or 24Ne.

In a nutshell, there's no need to consider cluster decay in general, unless the nuclide has the lowest anergy among its isobars, has mass number ≥ 93 and either is stable to alpha decay or has alpha decay half-life > Tα1/2(161Dy), or ≥ Tα1/2(153Eu).

In order not to make this comment too long, the theoretical calculations are posted in the following comments. 14.52.231.91 (talk) 03:25, 29 August 2024 (UTC)Reply

By the way, the nuclides with the longest half-life of following mass numbers are not the ones having the lowest energy among their isobars: 144 (144Sm > 144Nd), 146 (146Nd > 146Sm), 148 (148Nd > 148Sm), 176 (176Yb > 176Hf: 3.889×1021 years predicted here and (2.0-6.6)×1020 years here), and 186 (186W > 186Os). 129.104.241.89 (talk) 15:33, 12 November 2024 (UTC)Reply

Theoretical calculation of cluster decays for mass numbers 93-142

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Warning: I should have used nuclear masses to substitute   in the formula here, but actually I used atomic masses for all decay modes including alpha decay. I think it is OK because all are theoretical, so there's nothing serious.

The table lists common logarithm values of theoretical half-lives in years. Red means that the corresponding value is within 10000 times the minimal value.

Nuclide 16O 26Mg 30Si 32Si 36S 46Ca 48Ca Minimum Note
93Nb - - - - 1013.38 2334.79 - 1013.38
94Mo - - 473.29 564.63 461.86 666.06 - 461.86
95Mo - - 629.59 646.02 514.86 592.97 1040.10 514.86
96Mo - - 670.21 568.18 542.92 484.55 612.53 484.55
97Mo - - 1111.73 690.54 701.44 506.58 523.06 506.58
98Ru - 1058.78 346.68 418.49 331.29 385.35 521.24 331.29
99Ru - - 382.25 440.17 344.97 375.67 453.56 344.97
100Ru - 1251.32 402.36 413.00 345.32 374.78 392.77 345.32
101Ru - 2360.51 456.44 429.00 362.67 386.08 370.45 362.67
102Ru - - 480.00 429.08 369.91 408.29 361.65 361.65
103Rh 395.64 548.70 363.40 374.04 329.06 360.43 349.00 329.06
104Pd 238.64 405.10 311.92 353.30 317.97 329.50 343.45 238.64
105Pd 277.91 413.08 325.20 362.22 328.38 335.80 336.59 277.91
106Pd 542.66 392.56 - 344.60 334.62 345.44 330.87 330.87
107Ag 277.17 331.83 294.04 329.82 312.38 323.96 327.59 277.17
108Pd - 381.43 354.72 - 355.62 377.83 335.16 335.16
109Ag 1042.77 309.93 304.80 317.95 323.93 339.43 323.90 304.80
110Cd 377.02 277.43 274.45 301.75 305.05 314.81 315.99 274.45
111Cd 464.70 274.76 278.30 301.96 311.30 323.16 317.22 274.76
112Cd - 266.19 280.00 293.73 - 327.60 314.87 266.19
113In 520.08 236.16 255.91 282.95 297.55 316.57 315.63 236.16
114Sn 329.65 219.40 241.90 274.35 287.05 316.08 324.19 219.40
115Sn 652.09 232.08 245.88 - 292.96 325.06 328.36 232.08
116Sn - 254.67 243.17 264.62 289.38 328.12 323.01 243.17
117Sn - 273.03 257.11 262.85 291.85 338.46 326.88 257.11
118Sn - 314.78 284.08 257.49 292.37 342.79 327.80 257.49
119Sn - 348.37 307.41 267.49 299.47 352.85 333.48 267.49
120Sn - 450.41 360.03 292.36 304.26 362.61 335.43 292.36
121Sb - 314.42 291.54 260.75 273.60 333.00 322.03 260.75
122Te 648.32 259.82 251.33 238.86 253.11 - 311.92 238.86
123Sb - 516.79 383.61 302.59 316.56 352.77 328.88 302.59
124Te - 345.70 298.18 266.65 280.99 324.48 - 266.65
125Te - 419.70 333.40 279.88 295.82 331.06 - 279.88
126Te - 580.98 410.67 308.21 323.98 339.73 320.98 308.21
127I - 381.04 322.73 275.91 293.46 319.46 312.78 275.91
128Xe 521.12 297.57 277.80 253.86 269.03 303.48 303.99 253.86
129Xe - 326.27 305.49 264.83 280.65 309.95 305.15 264.83
130Xe - 374.21 341.40 292.79 300.69 313.52 305.03 292.79
131Xe - 434.39 374.98 318.27 322.98 327.22 309.53 309.53
132Xe - 577.85 448.68 349.93 361.01 348.30 311.04 311.04
133Cs - 366.52 341.73 307.38 317.03 325.55 300.10 300.10
134Ba 364.09 295.96 294.02 276.81 290.21 306.63 291.42 276.81
135Ba 686.30 327.24 317.17 291.00 309.86 318.09 298.13 291.00
136Ba - 374.20 351.18 308.80 330.99 334.36 308.30 308.30
137Ba - 455.69 401.00 332.50 353.58 354.57 319.05 319.05
138Ba - 570.63 472.18 359.72 384.84 377.61 331.59 331.59
139La 643.77 370.85 359.32 312.25 336.36 349.58 319.57 312.25
140Ce 256.65 300.21 304.28 283.12 307.33 325.89 307.72 256.65
141Pr 210.85 262.41 270.94 264.10 286.95 312.32 301.63 210.85
142Nd 185.32 234.57 249.11 249.10 270.65 301.90 297.73 185.32 12C = 188.35

14.52.231.91 (talk) 03:40, 29 August 2024 (UTC)Reply

Theoretical calculation of cluster decays for mass numbers 152-165, 201-205

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Nuclide α 12C 14C 24Ne Decay mode(s) Minimum Note
152Sm 164.24 115.84 111.23 187.96 14C to 138Ba 111.23
153Eu 144.69 108.55 110.99 186.92 12C to 141La or 14C to 139La 108.55
154Gd 54.37 101.00 109.65 185.24 α 54.37
155Gd 304.37 111.31 117.55 184.32 12C to 143Ce 111.31
156Gd - 127.89 130.31 182.19 12C to 144Ce or 14C to 142Ce 127.89
157Gd - 150.39 144.38 181.80 14C to 143Ce 144.38
158Gd - 175.63 159.36 178.65 14C to 144Ce 159.36
159Tb - 159.93 157.32 179.61 12C to 147Pr, 14C to 145Pr or 16O to 143La 157.32 16O = 157.48
160Dy 110.29 135.61 144.68 177.93 α 110.29
161Dy 132.24 156.10 160.63 175.85 α 132.24
162Dy 336.47 171.38 175.29 173.99 12C to 150Nd, 14C to 148Nd, 16O to 146Ce or 24Ne to 138Ba 171.00 16O = 171.00
163Dy - 193.71 202.49 181.18 24Ne to 139Ba 181.18
164Dy - 204.89 210.06 187.41 24Ne to 140Ba 187.41
165Ho 242.65 169.21 194.22 187.58 12C to 153Pm 169.21
201Hg 171.10 174.61 173.33 210.54 α, 12C to 189W or 14C to 187W 171.10
202Hg 305.64 188.90 186.02 215.28 12C to 190W or 14C to 188W 186.02
203Tl 80.46 166.47 176.50 214.19 α 80.46
204Pb 35.56 144.36 163.00 211.38 α 35.56
205Tl 283.07 201.02 201.97 226.19 12C to 193Re or 14C to 191Re 201.02

14.52.231.91 (talk) 03:55, 29 August 2024 (UTC)Reply

The CD half-lives are actually highly overestimated with that formula. For example, 223Ra partial CD half-life according to the formula is on the order of 1075 years, but it is only 107 years by experiment. Nucleus hydro elemon (talk) 04:28, 27 September 2024 (UTC)Reply
Interesting observation, thanks! :) 129.104.241.231 (talk) 17:46, 1 October 2024 (UTC)Reply
After some regressions I came out with this. By the formula, some decay processes like 154Gd(12C) have half-lives short enough to be observed. :) Nucleus hydro elemon (talk) 13:56, 4 October 2024 (UTC)Reply
A rather less optimistic prediction for 154Gd cluster decay (most probable cluster emitted 16O to get to the N = 82 closure in one step, but with predicted half-life 8.04×1050 s). Double sharp (talk) 07:39, 10 October 2024 (UTC)Reply
The problem is that in the table above, while having the shortest cluster decay half-lives, 154Gd has way "too short" alpha half-life. In comparison, 152Sm, 153Eu, and 155Gd would be more ideal to study cluster decay (well, theoretically). 129.104.241.83 (talk) 00:14, 12 November 2024 (UTC)Reply
Regardless of the actual half-life values, perhaps 205Tl would be the most stable nuclide with mass number at least 142, being nearly as stable as 141Pr. This is extremely counter-intuitive! 129.104.241.211 (talk) 02:46, 16 November 2024 (UTC)Reply

14C emission is the only known cluster decay mode to have short enough half-lives

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By "short enough half-lives", I mean that the 14C emission decay mode can be seen as a common decay mode like α, β+, β-, SF, IT, since some isotopes of Ra and Ac (perhaps also Fr, but its isotopes have far too short α/β half-lives) are known to have short 14C emission half-life.

In comparison, while there are other decay modes known, they are often seen as exotic and are often ignored. For example, the nuclide with shortest known 22Ne emission half-life is 230U with a half-life of 1.15×1012 years; the nuclide with shortest known 24Ne emission half-life is 232U with a half-life of 7.74×1012 years; the shortest known double beta decay half-life is 7.07×1018 years for 100Mo. 129.104.241.231 (talk) 17:46, 1 October 2024 (UTC)Reply