This list of nuclides shows observed nuclides that either are stable or, if radioactive, have half-lives longer than one hour. This represents isotopes of the first 105 elements, except for elements 87 (francium) and 102 (nobelium). At least 3,300 nuclides have been experimentally characterized[1] (see List of radioactive nuclides by half-life for the nuclides with decay half-lives less than one hour). Show
A nuclide is defined conventionally as an experimentally examined bound collection of protons and neutrons that either is stable or has an observed decay mode. Introduction[edit]There are 252 known so-called stable nuclides. Many of these in theory could decay through spontaneous fission, alpha decay, double beta decay, etc. with a very long half-life, but no radioactive decay has yet been observed. Thus, the number of stable nuclides is subject to change if some of these 252 are determined to be very long-lived radioactive nuclides in the future. In this article, the "stable" nuclides are divided into three tables, one for nuclides that are theoretically stable (meaning no decay mode is possible) and nuclides that can theoretically undergo spontaneous fission but have not been evaluated to check for evidence of this happening, one for nuclides that can theoretically undergo forms of decay other than spontaneous fission but have not been evaluated, and finally a table of nuclides that can theoretically decay and have been evaluated but without detecting any decay. In this latter table, where a decay has been predicted theoretically but never observed experimentally (either directly or through finding an excess of the daughter), the theoretical decay mode is given in parentheses and have "> number" in the half-life column to show the lower limit for the half-life based on experimental observation. Such nuclides are considered to be "stable" until a decay has been observed in some fashion. For example, tellurium-123 was reported to be radioactive, but the same experimental group later retracted this report, and it presently remains observationally stable. The next group is the primordial radioactive nuclides. These have been measured to be radioactive, or decay products have been identified (tellurium-128, barium-130). There are (currently) 34 of these (see these nuclides), of which 24 have half-lives longer than 1014 years. With most of these 24, decay is difficult to observe and for most purposes they can be regarded as effectively stable. Bismuth-209 is notable as it is the only naturally occurring isotope of an element which was long considered stable. A further 10 nuclides, platinum-190, samarium-147, lanthanum-138, rubidium-87, rhenium-187, lutetium-176, thorium-232, uranium-238, potassium-40, and uranium-235 have half-lives between 7.0×108 and 6.5×1011 years, which means they have experienced at least 0.5% depletion since the formation of the solar system about 4.6×109 years ago, but still exist on Earth in significant quantities. They are the primary source of radiogenic heating and radioactive decay products. Together, there are a total of 286 primordial nuclides.[a] The list then covers the ~700 radionuclides with half-lives longer than 1 hour, split into two tables, half-lives greater than one day and less than one day. Over 60 nuclides that have half-lives too short to be primordial can be detected in nature as a result of later production by natural processes, mostly in trace amounts. These include ~44 radionuclides occurring in the decay chains of primordial uranium and thorium (radiogenic nuclides), such as radon-222. Others are the products of interactions with energetic cosmic-rays (e.g. cosmic ray spallation) (cosmogenic nuclides), such as carbon-14. This gives a total of about 350 naturally occurring nuclides. Other nuclides may be occasionally produced naturally by rare cosmogenic interactions or as a result of other natural nuclear reactions (nucleogenic nuclides), but are difficult to detect. Further shorter-lived nuclides have been detected in the spectra of stars (e.g. technetium, promethium, and some actinides). The remaining nuclides are known solely from artificial nuclear transmutation. Some, such as caesium-137, are found in the environment but as a result of contamination from releases of man-made nuclear fission product (from nuclear weapons, nuclear reactors, and other processes). Other are produced artificially for industrial or medical purposes. List legend[edit]Each group of radionuclides, starting with the longest-lived primordial radionuclides, is sorted by decreasing half-life, but the tables are sortable by other columns.
Full list[edit]Theoretically stable nuclides[edit]These are the theoretically stable nuclides, ordered by "energy".
Nuclides that are observationally stable, having theoretical decay modes other than spontaneous fission[edit]Ordered by "energy".
Observationally stable nuclides for which decay has been searched for but not found (only lower bounds known)[edit]Ordered by lower bound on half-life.
Primordial radioactive nuclides (half-life > 108 years)[edit]Ordered by half-life.
Radionuclides with half-lives of 10,000 years to 108 years[edit]Ordered by half-life.
Radionuclides with half-lives of 10 years to 10,000 years[edit]Ordered by half-life.
Radionuclides with half-lives of 1 day to 10 years[edit]Ordered by half-life.
Radionuclides with half-lives of 1 hour to 1 day[edit]Ordered by half-life.
Radionuclides with half-lives of 1 minute to 1 hour[edit]Radionuclides with half-lives of 1 second to 1 minute[edit]Radionuclides with half-lives less than 1 second[edit]See also[edit]
Sources[edit]Almost all data are taken from reference.[9] For more recent updates, see reference.[10] These sources do not indicate whether certain heavy isotopes starting from Lr, Rf, Db, ... (etc.) were produced, observed, or only predicted from estimated data. Notes[edit]
References[edit]
External links[edit]
Which nuclide has a half2 From Table N, the only radioisotope of the given choices that has a half-life less than one minute is 220Fr with a half-life of 27.4 s.
What is nuclide halfThe half life of radioactive nuclides is defined as the time in which half of the original number of radioactive atoms has decayed. Example: Imagine you start with 100 atoms of nuclide X. X decays to nuclide Y with a half life of 10 days.
What is the halfFor Rn-222, the half life is 3.82 days and it goes through alpha decay to become Po-218.
What is the halfThe time required for a radioactive substance to lose 50 percent of its radioactivity by decay is known as the half-life. The half-life of thorium- 232 is very long at about 14 billion years.
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