List of elements by stability of isotopes

This is a list of chemical elements by the stability of their isotopes. Of the first 82 elements in the periodic table, 80 have isotopes considered to be stable.^[1] Overall, there are 251 known stable isotopes in total.

Background

Atomic nuclei consist of protons and neutrons, which attract each other through the nuclear force, while protons repel each other via the electric force due to their positive charge. These two forces compete, leading to some combinations of neutrons and protons being more stable than others. Neutrons stabilize the nucleus, because they attract protons, which helps offset the electrical repulsion between protons. As a result, as the number of protons increases, an increasing ratio of neutrons to protons is needed to form a stable nucleus; if too many or too few neutrons are present with regard to the optimum ratio, the nucleus becomes unstable and subject to certain types of nuclear decay. Unstable isotopes decay through various radioactive decay pathways, most commonly alpha decay, beta decay, or electron capture. Many rare types of decay, such as spontaneous fission or cluster decay, are known. (See Radioactive decay for details.)^{[citation needed]}

Of the first 82 elements in the periodic table, 80 have isotopes considered to be stable.^[1] The 83rd element, bismuth, was traditionally regarded as having the heaviest stable isotope, bismuth-209, but in 2003 researchers in Orsay, France, measured the half-life of ²⁰⁹
Bi
to be 1.9×10¹⁹ years.^[2]^[3] Technetium and promethium (atomic numbers 43 and 61, respectively^[a]) and all the elements with an atomic number over 82 only have isotopes that are known to decompose through radioactive decay. No undiscovered elements are expected to be stable; therefore, lead is considered the heaviest stable element. However, it is possible that some isotopes that are now considered stable will be revealed to decay with extremely long half-lives (as with ²⁰⁹
Bi
). This list depicts what is agreed upon by the consensus of the scientific community as of 2023.^[1]

For each of the 80 stable elements, the number of the stable isotopes is given. Only 90 isotopes are expected to be perfectly stable, and an additional 161 are energetically unstable,^{[citation needed]} but have never been observed to decay. Thus, 251 isotopes (nuclides) are stable by definition (including tantalum-180m, for which no decay has yet been observed). Those that may in the future be found to be radioactive are expected to have half-lives longer than 10²² years (for example, xenon-134).^{[citation needed]}

In April 2019 it was announced that the half-life of xenon-124 had been measured to 1.8 × 10²² years. This is the longest half-life directly measured for any unstable isotope;^[4] only the half-life of tellurium-128 is longer.^{[citation needed]}

Of the chemical elements, only 1 element (tin) has 10 such stable isotopes, 5 have 7 stable isotopes, 7 have 6 stable isotopes, 11 have 5 stable isotopes, 9 have 4 stable isotopes, 5 have 3 stable isotopes, 16 have 2 stable isotopes, and 26 have 1 stable isotope.^[1]

Additionally, about 31 nuclides of the naturally occurring elements have unstable isotopes with a half-life larger than the age of the Solar System (~10⁹ years or more).^[b] An additional four nuclides have half-lives longer than 100 million years, which is far less than the age of the Solar System, but long enough for some of them to have survived. These 35 radioactive naturally occurring nuclides comprise the radioactive primordial nuclides. The total number of primordial nuclides is then 251 (the stable nuclides) plus the 35 radioactive primordial nuclides, for a total of 286 primordial nuclides. This number is subject to change if new shorter-lived primordials are identified on Earth.^{[citation needed]}

One of the primordial nuclides is tantalum-180m, which is predicted to have a half-life in excess of 10¹⁵ years, but has never been observed to decay. The even-longer half-life of 2.2 × 10²⁴ years of tellurium-128 was measured by a unique method of detecting its radiogenic daughter xenon-128 and is the longest known experimentally measured half-life.^[5] Another notable example is the only naturally occurring isotope of bismuth, bismuth-209, which has been predicted to be unstable with a very long half-life, but has been observed to decay. Because of their long half-lives, such isotopes are still found on Earth in various quantities, and together with the stable isotopes they are called primordial isotopes. All the primordial isotopes are given in order of their decreasing abundance on Earth.^[c] For a list of primordial nuclides in order of half-life, see List of nuclides.^{[citation needed]}

118 chemical elements are known to exist. All elements to element 94 are found in nature, and the remainder of the discovered elements are artificially produced, with isotopes all known to be highly radioactive with relatively short half-lives (see below). The elements in this list are ordered according to the lifetime of their most stable isotope.^[1] Of these, three elements (bismuth, thorium, and uranium) are primordial because they have half-lives long enough to still be found on the Earth,^[d] while all the others are produced either by radioactive decay or are synthesized in laboratories and nuclear reactors. Only 13 of the 38 known-but-unstable elements have isotopes with a half-life of at least 100 years. Every known isotope of the remaining 25 elements is highly radioactive; these are used in academic research and sometimes in industry and medicine.^[e] Some of the heavier elements in the periodic table may be revealed to have yet-undiscovered isotopes with longer lifetimes than those listed here.^[f]

About 338 nuclides are found naturally on Earth. These comprise 251 stable isotopes, and with the addition of the 35 long-lived radioisotopes with half-lives longer than 100 million years, a total of 286 primordial nuclides, as noted above. The nuclides found naturally comprise not only the 286 primordials, but also include about 52 more short-lived isotopes (defined by a half-life less than 100 million years, too short to have survived from the formation of the Earth) that are daughters of primordial isotopes (such as radium from uranium); or else are made by energetic natural processes, such as carbon-14 made from atmospheric nitrogen by bombardment from cosmic rays.^{[citation needed]}

Elements by number of primordial isotopes

An even number of protons or neutrons is more stable (higher binding energy) because of pairing effects, so even–even nuclides are much more stable than odd–odd. One effect is that there are few stable odd–odd nuclides: in fact only five are stable, with another four having half-lives longer than a billion years.^{[citation needed]}

Another effect is to prevent beta decay of many even–even nuclides into another even–even nuclide of the same mass number but lower energy, because decay proceeding one step at a time would have to pass through an odd–odd nuclide of higher energy. (Double beta decay directly from even–even to even–even, skipping over an odd-odd nuclide, is only occasionally possible, and is a process so strongly hindered that it has a half-life greater than a billion times the age of the universe.) This makes for a larger number of stable even–even nuclides, up to three for some mass numbers, and up to seven for some atomic (proton) numbers and at least four for all stable even-Z elements beyond iron (except strontium and lead).^{[citation needed]}

Since a nucleus with an odd number of protons is relatively less stable, odd-numbered elements tend to have fewer stable isotopes. Of the 26 "monoisotopic" elements that have only a single stable isotope, all but one have an odd atomic number—the single exception being beryllium. In addition, no odd-numbered element has more than two stable isotopes, while every even-numbered element with stable isotopes, except for helium, beryllium, and carbon, has at least three. Only a single odd-numbered element, potassium, has three primordial isotopes; none have more than three.^{[citation needed]}

Tables

The following tables give the elements with primordial nuclides, which means that the element may still be identified on Earth from natural sources, having been present since the Earth was formed out of the solar nebula. Thus, none are shorter-lived daughters of longer-lived parental primordials. Two nuclides which have half-lives long enough to be primordial, but have not yet been conclusively observed as such (²⁴⁴Pu and ¹⁴⁶Sm), have been excluded.^{[citation needed]}

The tables of elements are sorted in order of decreasing number of nuclides associated with each element. (For a list sorted entirely in terms of half-lives of nuclides, with mixing of elements, see List of nuclides.) Stable and unstable (marked decays) nuclides are given, with symbols for unstable (radioactive) nuclides in italics. Note that the sorting does not quite give the elements purely in order of stable nuclides, since some elements have a larger number of long-lived unstable nuclides, which place them ahead of elements with a larger number of stable nuclides. By convention, nuclides are counted as "stable" if they have never been observed to decay by experiment or from observation of decay products (extremely long-lived nuclides unstable only in theory, such as tantalum-180m, are counted as stable).^{[citation needed]}

The first table is for even-atomic numbered elements, which tend to have far more primordial nuclides, due to the stability conferred by proton-proton pairing. A second separate table is given for odd-atomic numbered elements, which tend to have far fewer stable and long-lived (primordial) unstable nuclides.^{[citation needed]}

Primordial isotopes (in order of decreasing abundance on Earth^[c]) of even-Z elements
Z	Element	Stable ^[1]	Decays ^[b]^[1]	unstable in bold^[b] odd neutron number in pink
50	tin	10	—	¹²⁰ Sn	¹¹⁸ Sn	¹¹⁶ Sn	¹¹⁹ Sn	¹¹⁷ Sn	¹²⁴ Sn	¹²² Sn	¹¹² Sn	¹¹⁴ Sn	¹¹⁵ Sn
54	xenon	7	2	¹³² Xe	¹²⁹ Xe	¹³¹ Xe	¹³⁴ Xe	¹³⁶ Xe	¹³⁰ Xe	¹²⁸ Xe	¹²⁴ Xe	¹²⁶ Xe
48	cadmium	6	2	¹¹⁴ Cd	¹¹² Cd	¹¹¹ Cd	¹¹⁰ Cd	¹¹³ Cd	¹¹⁶ Cd	¹⁰⁶ Cd	¹⁰⁸ Cd
52	tellurium	6	2	¹³⁰ Te	¹²⁸ Te	¹²⁶ Te	¹²⁵ Te	¹²⁴ Te	¹²² Te	¹²³ Te	¹²⁰ Te
44	ruthenium	7	—	¹⁰² Ru	¹⁰⁴ Ru	¹⁰¹ Ru	⁹⁹ Ru	¹⁰⁰ Ru	⁹⁶ Ru	⁹⁸ Ru
66	dysprosium	7	—	¹⁶⁴ Dy	¹⁶² Dy	¹⁶³ Dy	¹⁶¹ Dy	¹⁶⁰ Dy	¹⁵⁸ Dy	¹⁵⁶ Dy
70	ytterbium	7	—	¹⁷⁴ Yb	¹⁷² Yb	¹⁷³ Yb	¹⁷¹ Yb	¹⁷⁶ Yb	¹⁷⁰ Yb	¹⁶⁸ Yb
80	mercury	7	—	²⁰² Hg	²⁰⁰ Hg	¹⁹⁹ Hg	²⁰¹ Hg	¹⁹⁸ Hg	²⁰⁴ Hg	¹⁹⁶ Hg
42	molybdenum	6	1	⁹⁸ Mo	⁹⁶ Mo	⁹⁵ Mo	⁹² Mo	¹⁰⁰ Mo	⁹⁷ Mo	⁹⁴ Mo
56	barium	6	1	¹³⁸ Ba	¹³⁷ Ba	¹³⁶ Ba	¹³⁵ Ba	¹³⁴ Ba	¹³² Ba	¹³⁰ Ba
64	gadolinium	6	1	¹⁵⁸ Gd	¹⁶⁰ Gd	¹⁵⁶ Gd	¹⁵⁷ Gd	¹⁵⁵ Gd	¹⁵⁴ Gd	¹⁵² Gd
60	neodymium	5	2	¹⁴² Nd	¹⁴⁴ Nd	¹⁴⁶ Nd	¹⁴³ Nd	¹⁴⁵ Nd	¹⁴⁸ Nd	¹⁵⁰ Nd
62	samarium	5	2	¹⁵² Sm	¹⁵⁴ Sm	¹⁴⁷ Sm	¹⁴⁹ Sm	¹⁴⁸ Sm	¹⁵⁰ Sm	¹⁴⁴ Sm
76	osmium	5	2	¹⁹² Os	¹⁹⁰ Os	¹⁸⁹ Os	¹⁸⁸ Os	¹⁸⁷ Os	¹⁸⁶ Os	¹⁸⁴ Os
46	palladium	6	—	¹⁰⁶ Pd	¹⁰⁸ Pd	¹⁰⁵ Pd	¹¹⁰ Pd	¹⁰⁴ Pd	¹⁰² Pd
68	erbium	6	—	¹⁶⁶ Er	¹⁶⁸ Er	¹⁶⁷ Er	¹⁷⁰ Er	¹⁶⁴ Er	¹⁶² Er
20	calcium	5	1	⁴⁰ Ca	⁴⁴ Ca	⁴² Ca	⁴⁸ Ca	⁴³ Ca	⁴⁶ Ca
34	selenium	5	1	⁸⁰ Se	⁷⁸ Se	⁷⁶ Se	⁸² Se	⁷⁷ Se	⁷⁴ Se
36	krypton	5	1	⁸⁴ Kr	⁸⁶ Kr	⁸² Kr	⁸³ Kr	⁸⁰ Kr	⁷⁸ Kr
72	hafnium	5	1	¹⁸⁰ Hf	¹⁷⁸ Hf	¹⁷⁷ Hf	¹⁷⁹ Hf	¹⁷⁶ Hf	¹⁷⁴ Hf
78	platinum	5	1	¹⁹⁵ Pt	¹⁹⁴ Pt	¹⁹⁶ Pt	¹⁹⁸ Pt	¹⁹² Pt	¹⁹⁰ Pt
22	titanium	5	—	⁴⁸ Ti	⁴⁶ Ti	⁴⁷ Ti	⁴⁹ Ti	⁵⁰ Ti
28	nickel	5	—	⁵⁸ Ni	⁶⁰ Ni	⁶² Ni	⁶¹ Ni	⁶⁴ Ni
30	zinc	5	—	⁶⁴ Zn	⁶⁶ Zn	⁶⁸ Zn	⁶⁷ Zn	⁷⁰ Zn
32	germanium	4	1	⁷⁴ Ge	⁷² Ge	⁷⁰ Ge	⁷³ Ge	⁷⁶ Ge
40	zirconium	4	1	⁹⁰ Zr	⁹⁴ Zr	⁹² Zr	⁹¹ Zr	⁹⁶ Zr
74	tungsten	4	1	¹⁸⁴ W	¹⁸⁶ W	¹⁸² W	¹⁸³ W	¹⁸⁰ W
16	sulfur	4	—	³² S	³⁴ S	³³ S	³⁶ S
24	chromium	4	—	⁵² Cr	⁵³ Cr	⁵⁰ Cr	⁵⁴ Cr
26	iron	4	—	⁵⁶ Fe	⁵⁴ Fe	⁵⁷ Fe	⁵⁸ Fe
38	strontium	4	—	⁸⁸ Sr	⁸⁶ Sr	⁸⁷ Sr	⁸⁴ Sr
58	cerium	4	—	¹⁴⁰ Ce	¹⁴² Ce	¹³⁸ Ce	¹³⁶ Ce
82	lead	4	—	²⁰⁸ Pb	²⁰⁶ Pb	²⁰⁷ Pb	²⁰⁴ Pb
8	oxygen	3	—	¹⁶ O	¹⁸ O	¹⁷ O
10	neon	3	—	²⁰ Ne	²² Ne	²¹ Ne
12	magnesium	3	—	²⁴ Mg	²⁶ Mg	²⁵ Mg
14	silicon	3	—	²⁸ Si	²⁹ Si	³⁰ Si
18	argon	3	—	⁴⁰ Ar	³⁶ Ar	³⁸ Ar
2	helium	2	—	⁴ He	³ He
6	carbon	2	—	¹² C	¹³ C
92	uranium	0	2	²³⁸ U ^[d]	²³⁵ U
4	beryllium	1	—	⁹ Be
90	thorium	0	1	²³² Th ^[d]

Primordial isotopes of odd-Z elements
Z	Element	Stab	Dec	unstable: bold odd N in pink
19	potassium	2	1	³⁹ K	⁴¹ K	⁴⁰ K
1	hydrogen	2	—	¹ H	² H
3	lithium	2	—	⁷ Li	⁶ Li
5	boron	2	—	¹¹ B	¹⁰ B
7	nitrogen	2	—	¹⁴ N	¹⁵ N
17	chlorine	2	—	³⁵ Cl	³⁷ Cl
29	copper	2	—	⁶³ Cu	⁶⁵ Cu
31	gallium	2	—	⁶⁹ Ga	⁷¹ Ga
35	bromine	2	—	⁷⁹ Br	⁸¹ Br
47	silver	2	—	¹⁰⁷ Ag	¹⁰⁹ Ag
51	antimony	2	—	¹²¹ Sb	¹²³ Sb
73	tantalum	2	—	¹⁸¹ Ta	^180m Ta
77	iridium	2	—	¹⁹³ Ir	¹⁹¹ Ir
81	thallium	2	—	²⁰⁵ Tl	²⁰³ Tl
23	vanadium	1	1	⁵¹ V	⁵⁰ V
37	rubidium	1	1	⁸⁵ Rb	⁸⁷ Rb
49	indium	1	1	¹¹⁵ In	¹¹³ In
57	lanthanum	1	1	¹³⁹ La	¹³⁸ La
63	europium	1	1	¹⁵³ Eu	¹⁵¹ Eu
71	lutetium	1	1	¹⁷⁵ Lu	¹⁷⁶ Lu
75	rhenium	1	1	¹⁸⁷ Re	¹⁸⁵ Re
9	fluorine	1	—	¹⁹ F
11	sodium	1	—	²³ Na
13	aluminium	1	—	²⁷ Al
15	phosphorus	1	—	³¹ P
21	scandium	1	—	⁴⁵ Sc
25	manganese	1	—	⁵⁵ Mn
27	cobalt	1	—	⁵⁹ Co
33	arsenic	1	—	⁷⁵ As
39	yttrium	1	—	⁸⁹ Y
41	niobium	1	—	⁹³ Nb
45	rhodium	1	—	¹⁰³ Rh
53	iodine	1	—	¹²⁷ I
55	caesium	1	—	¹³³ Cs
59	praseodymium	1	—	¹⁴¹ Pr
65	terbium	1	—	¹⁵⁹ Tb
67	holmium	1	—	¹⁶⁵ Ho
69	thulium	1	—	¹⁶⁹ Tm
79	gold	1	—	¹⁹⁷ Au
83	bismuth	0	1	²⁰⁹ Bi

Elements with no primordial isotopes

No primordial isotopes
Longest-lived isotope > 1 day
Z	Element	t^1⁄2^[g]^[1]	Longest- lived isotope
94	plutonium	8.08×10⁷ yr	²⁴⁴ Pu
96	curium	1.56×10⁷ yr	²⁴⁷ Cm
43	technetium	4.21×10⁶ yr	⁹⁷ Tc ^[a]
93	neptunium	2.14×10⁶ yr	²³⁷ Np
91	protactinium	32,760 yr	²³¹ Pa
95	americium	7,370 yr	²⁴³ Am
88	radium	1,600 yr	²²⁶ Ra
97	berkelium	1,380 yr	²⁴⁷ Bk
98	californium	900 yr	²⁵¹ Cf
84	polonium	125 yr	²⁰⁹ Po
89	actinium	21.772 yr	²²⁷ Ac
61	promethium	17.7 yr	¹⁴⁵ Pm ^[a]
99	einsteinium	1.293 yr	²⁵² Es ^[f]
100	fermium	100.5 d	²⁵⁷ Fm ^[f]
101	mendelevium	51.3 d	²⁵⁸ Md ^[f]
86	radon	3.823 d	²²² Rn

No primordial isotopes
Longest-lived isotope < 1 day
Z	Element	t^1⁄2^[g]^[1]	Longest- lived isotope
105	dubnium	16 h	²⁶⁸ Db ^[f]
103	lawrencium	11 h	²⁶⁶ Lr ^[f]
85	astatine	8.1 h	²¹⁰ At
102	nobelium	58 min	²⁵⁹ No ^[f]
104	rutherfordium	48 min	²⁶⁷ Rf ^[f]
87	francium	22 min	²²³ Fr
106	seaborgium	14 min	²⁶⁹ Sg ^[f]
107	bohrium	2.4 min	²⁷⁰ Bh ^[f]
111	roentgenium	1.7 min	²⁸² Rg ^[f]
112	copernicium	28 s	²⁸⁵ Cn ^[f]
108	hassium	16 s	²⁶⁹ Hs ^[f]
110	darmstadtium	12.7 s	²⁸¹ Ds ^[f]
113	nihonium	9.5 s	²⁸⁶ Nh ^[f]
109	meitnerium	4.5 s	²⁷⁸ Mt ^[f]
114	flerovium	1.9 s	²⁸⁹ Fl ^[f]
115	moscovium	650 ms	²⁹⁰ Mc ^[f]
116	livermorium	57 ms	²⁹³ Lv ^[f]
117	tennessine	51 ms	²⁹⁴ Ts ^[f]
118	oganesson	690 μs	²⁹⁴ Og ^[f]

Footnotes

^ ^a ^b ^c See Stability of technetium isotopes and Stability of promethium isotopes for a detailed discussion as to why technetium and promethium have no stable isotopes.
^ ^a ^b ^c Isotopes that have a half-life of more than about 10⁸ yr may still be found on Earth, but only those with half-lives above 7×10⁸ yr (as of ²³⁵U) are found in appreciable quantities. The present list neglects a few isotopes with half-lives about 10⁸ yr because they have been measured in tiny quantities on Earth. Uranium-234 with its half-life of 246,000 yr and natural isotopic abundance 0.0055% is a special case: it is a decay product of uranium-238 rather than a primordial nuclide.
^ ^a ^b There are unstable isotopes with extremely long half-lives that are also found on Earth, and some of them are even more abundant than all the stable isotopes of a given element (for example, beta-active ¹⁸⁷Re is twice as abundant as stable ¹⁸⁵Re). Also, a bigger natural abundance of an isotope just implies that its formation was favored by the stellar nucleosynthesis process that produced the matter now constituting the Earth (and, of course, the rest of the Solar System) (see also Formation and evolution of the Solar System). In the case of argon the cosmically rarer ⁴⁰
Ar dominates on Earth over ³⁶
Ar as argon is too volatile to have been retained in the early proto-atmosphere of Earth while ⁴⁰
Ar is a decay product of long-lived and non-volatile ⁴⁰
K. Most argon in Earth's atmosphere is a product of potassium-40 decay. Most argon in the universe is not. At the present time 0.012% (120 ppm) of potassium on Earth is ⁴⁰
K. Taking the age of Earth and the half life of ⁴⁰
K (~1.25 billion years), this ratio was approximately an order of magnitude higher when the planet first formed. About 10.72% of that since-decayed ⁴⁰
K produced ⁴⁰
Ar, the rest having decayed to ⁴⁰
Ca.
^ ^a ^b ^c While bismuth has only one primordial isotope, uranium has three isotopes that are found in nature in significant amounts (²³⁸
U
, ²³⁵
U
, and ²³⁴
U
; the first two are primordial, while ²³⁴U is radiogenic), and thorium has two (primordial ²³²
Th
and radiogenic ²³⁰
Th
).
^ See many different industrial and medical applications of radioactive elements in Radionuclide, Nuclear medicine, Common beta emitters, Commonly used gamma-emitting isotopes, Fluorine-18, Cobalt-60, Strontium-90, Technetium-99m, Iodine-123, Iodine-124, Promethium-147, Iridium-192, etc.
^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j ^k ^l ^m ⁿ ^o ^p ^q ^r ^s ^t ^u For elements with a higher atomic number than californium (with Z>98), there might exist undiscovered isotopes that are more stable than the known ones.
^ ^a ^b Legend: yr=year, d=day, h=hour, min=minute, s=second.

References

^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Sonzogni, Alejandro. "Interactive Chart of Nuclides". National Nuclear Data Center: Brookhaven National Laboratory. Retrieved 2019-08-30.
^ Marcillac, Pierre de; Noël Coron; Gérard Dambier; Jacques Leblanc & Jean-Pierre Moalic (2003). "Experimental detection of α-particles from the radioactive decay of natural bismuth". Nature. 422 (6934): 876–878. Bibcode:2003Natur.422..876D. doi:10.1038/nature01541. PMID 12712201. S2CID 4415582.
^ Dumé, Belle (2003-04-23). "Bismuth breaks half-life record for alpha decay". Institute of Physics Publishing.
^ Siegel, Ethan. "Dark Matter Search Discovers A Spectacular Bonus: The Longest-Lived Unstable Element Ever". Forbes. Retrieved 2019-04-25.
^ "Noble Gas Research". Archived from the original on 2011-09-28. Retrieved 2013-01-10. Novel Gas Research. Accessed April 26, 2009

[Note1-4] See Stability of technetium isotopes and Stability of promethium isotopes for a detailed discussion as to why technetium and promethium have no stable isotopes.

[Note2-6] Isotopes that have a half-life of more than about 10⁸ yr may still be found on Earth, but only those with half-lives above 7×10⁸ yr (as of ²³⁵U) are found in appreciable quantities. The present list neglects a few isotopes with half-lives about 10⁸ yr because they have been measured in tiny quantities on Earth. Uranium-234 with its half-life of 246,000 yr and natural isotopic abundance 0.0055% is a special case: it is a decay product of uranium-238 rather than a primordial nuclide.

[Note3-8] There are unstable isotopes with extremely long half-lives that are also found on Earth, and some of them are even more abundant than all the stable isotopes of a given element (for example, beta-active ¹⁸⁷Re is twice as abundant as stable ¹⁸⁵Re). Also, a bigger natural abundance of an isotope just implies that its formation was favored by the stellar nucleosynthesis process that produced the matter now constituting the Earth (and, of course, the rest of the Solar System) (see also Formation and evolution of the Solar System). In the case of argon the cosmically rarer ⁴⁰
Ar dominates on Earth over ³⁶
Ar as argon is too volatile to have been retained in the early proto-atmosphere of Earth while ⁴⁰
Ar is a decay product of long-lived and non-volatile ⁴⁰
K. Most argon in Earth's atmosphere is a product of potassium-40 decay. Most argon in the universe is not. At the present time 0.012% (120 ppm) of potassium on Earth is ⁴⁰
K. Taking the age of Earth and the half life of ⁴⁰
K (~1.25 billion years), this ratio was approximately an order of magnitude higher when the planet first formed. About 10.72% of that since-decayed ⁴⁰
K produced ⁴⁰
Ar, the rest having decayed to ⁴⁰
Ca.

[Note4-9] While bismuth has only one primordial isotope, uranium has three isotopes that are found in nature in significant amounts (²³⁸
U
, ²³⁵
U
, and ²³⁴
U
; the first two are primordial, while ²³⁴U is radiogenic), and thorium has two (primordial ²³²
Th
and radiogenic ²³⁰
Th
).

[Note5-10] See many different industrial and medical applications of radioactive elements in Radionuclide, Nuclear medicine, Common beta emitters, Commonly used gamma-emitting isotopes, Fluorine-18, Cobalt-60, Strontium-90, Technetium-99m, Iodine-123, Iodine-124, Promethium-147, Iridium-192, etc.

[Note6-11] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j ^k ^l ^m ⁿ ^o ^p ^q ^r ^s ^t ^u For elements with a higher atomic number than californium (with Z>98), there might exist undiscovered isotopes that are more stable than the known ones.

[Note7-12] Legend: yr=year, d=day, h=hour, min=minute, s=second.

[nuclidetable-1] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Sonzogni, Alejandro. "Interactive Chart of Nuclides". National Nuclear Data Center: Brookhaven National Laboratory. Retrieved 2019-08-30.

[2] Marcillac, Pierre de; Noël Coron; Gérard Dambier; Jacques Leblanc & Jean-Pierre Moalic (2003). "Experimental detection of α-particles from the radioactive decay of natural bismuth". Nature. 422 (6934): 876–878. Bibcode:2003Natur.422..876D. doi:10.1038/nature01541. PMID 12712201. S2CID 4415582.

[3] Dumé, Belle (2003-04-23). "Bismuth breaks half-life record for alpha decay". Institute of Physics Publishing.

[5] Siegel, Ethan. "Dark Matter Search Discovers A Spectacular Bonus: The Longest-Lived Unstable Element Ever". Forbes. Retrieved 2019-04-25.

[7] "Noble Gas Research". Archived from the original on 2011-09-28. Retrieved 2013-01-10. Novel Gas Research. Accessed April 26, 2009

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