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The transuranium (or transuranic) elements are the with greater than 92, which is the atomic number of . All of them are radioactively unstable and decay into other elements. They are synthetic and none occur naturally on Earth, except for and which have been found in trace amounts in nature.

Overview
Of the elements with atomic numbers 1 to 92, most can be found in nature, having stable (such as ) or very long-lived (such as ), or existing as common of the decay of uranium and (such as ). The exceptions are , , , and ; all four occur in nature, but only in very minor branches of the uranium and thorium decay chains, and thus all save francium were first discovered by synthesis in the laboratory rather than in nature.

All elements with higher atomic numbers have been first discovered in the laboratory, with and later discovered in nature. They are all , with a much shorter than the age of the Earth, so any primordial (i.e. present at the Earth's formation) atoms of these elements, have long since decayed. Trace amounts of neptunium and plutonium form in some uranium-rich rock, and small amounts are produced during atmospheric tests of . These two elements are generated by in with subsequent (e.g. U + → U → Np → Pu).

All elements beyond plutonium are entirely synthetic, at least on Earth; they are created in or particle accelerators. The half-lives of these elements show a general trend of decreasing as atomic numbers increase. There are exceptions, however, including several isotopes of and . Some heavier elements in this series, around atomic numbers 110–114, are thought to break the trend and demonstrate increased nuclear stability, comprising the theoretical island of stability.

(2025). 9780471332305, Wiley Interscience.

Transuranic elements are difficult and expensive to produce, and their prices increase rapidly with atomic number. As of 2008, the cost of weapons-grade plutonium was around $4,000/gram, and exceeded $60,000,000/gram. is the heaviest element that has been produced in macroscopic quantities.

(2025). 9781402035555, Springer Science+Business Media.

Transuranic elements that have not been discovered, or have been discovered but are not yet officially named, use IUPAC's systematic element names. The naming of transuranic elements may be a source of controversy.

Discoveries
So far, essentially all transuranium elements have been discovered at four laboratories: Lawrence Berkeley National Laboratory (LBNL) in the United States (elements 93–101, 106, and joint credit for 103–105), the GSI Helmholtz Centre for Heavy Ion Research in Germany (elements 107–112), in Japan (element 113), and the Joint Institute for Nuclear Research (JINR) in Russia (elements 102 and 114–118, and joint credit for 103–105).
  • The Radiation Laboratory (now LBNL) at University of California, Berkeley, led principally by , , and , during 1945–1974:
    • 93. , Np, named after the planet , as it follows and Neptune follows in the (1940).
    • 94. , Pu, named after , following the same naming rule as it follows neptunium and Pluto follows Neptune in the Solar System (1940).
    • 95. , Am, named because it is an analog to , and so was named after the continent where it was first produced (1944).
    • 96. , Cm, named after and , scientists who separated out the first radioactive elements (1944), as its lighter analog was named after .
    • 97. , Bk, named after Lawrence Berkeley National Laboratory, where it was first synthesized (1949).
    • 98. , Cf, named after , where LBNL is located (1950).
    • 99. , Es, named after (1952).
    • 100. , Fm, named after , the physicist who produced the first controlled (1952).
    • 101. , Md, named after Russian chemist , credited for being the primary creator of the of the (1955).
    • 102. , No, named after (1958). The element was originally claimed by a team at the in Sweden (1957) – though it later became apparent that the Swedish team had not discovered the element, the LBNL team decided to adopt their name nobelium. This discovery was also claimed by JINR, which doubted the LBNL claim, and named the element joliotium (Jl) after Frédéric Joliot-Curie (1965). IUPAC concluded that the JINR had been the first to convincingly synthesize the element (1965), but retained the name nobelium as deeply entrenched in the literature.
    • 103. , Lr, named after , a physicist best known for development of the , and the person for whom Lawrence Livermore National Laboratory and LBNL (which hosted the creation of these transuranium elements) are named (1961). This discovery was also claimed by the JINR (1965), which doubted the LBNL claim and proposed the name rutherfordium (Rf) after Ernest Rutherford. IUPAC concluded that credit should be shared, retaining the name lawrencium as entrenched in the literature.
    • 104. , Rf, named after Ernest Rutherford, who was responsible for the concept of the (1969). This discovery was also claimed by JINR, led principally by : they named the element kurchatovium (Ku), after . IUPAC concluded that credit should be shared, and adopted the LBNL name rutherfordium.
    • 105. , Db, an element that is named after , where JINR is located. Originally named hahnium (Ha) in honor of by the Berkeley group (1970). This discovery was also claimed by JINR, which named it nielsbohrium (Ns) after . IUPAC concluded that credit should be shared, and renamed the element dubnium to honour the JINR team.
    • 106. , Sg, named after Glenn T. Seaborg. This name caused controversy because Seaborg was still alive, but it eventually became accepted by international chemists (1974). This discovery was also claimed by JINR. IUPAC concluded that the Berkeley team had been the first to convincingly synthesize the element.
  • The Gesellschaft für Schwerionenforschung (Society for Heavy Ion Research) in , Hessen, Germany, led principally by Gottfried Münzenberg, , and , during 1980–2000:
    • 107. , Bh, named after Danish physicist , important in the elucidation of the structure of the (1981). This discovery was also claimed by JINR. IUPAC concluded that the GSI had been the first to convincingly synthesise the element. The GSI team had originally proposed nielsbohrium (Ns) to resolve the naming dispute on element 105, but this was changed by IUPAC as there was no precedent for using a scientist's first name in an element name.
    • 108. , Hs, named after the form of the name of , the German Bundesland where this work was performed (1984). This discovery was also claimed by JINR. IUPAC concluded that the GSI had been the first to convincingly synthesize the element, while acknowledging the pioneering work at JINR.
    • 109. , Mt, named after , an Austrian physicist who was one of the earliest scientists to study (1982).
    • 110. , Ds, named after , Germany, the city in which this work was performed (1994). This discovery was also claimed by JINR, which proposed the name becquerelium after , and by LBNL, which proposed the name hahnium to resolve the dispute on element 105 (despite having protested the reusing of established names for different elements). IUPAC concluded that GSI had been the first to convincingly synthesize the element.
    • 111. , Rg, named after Wilhelm Röntgen, discoverer of X-rays (1994).
    • 112. , Cn, named after astronomer Nicolaus Copernicus (1996).
  • RIKEN in Wakō, Saitama, Japan, led principally by Kōsuke Morita:
    • 113. , Nh, named after ( Nihon in Japanese) where the element was discovered (2004). This discovery was also claimed by JINR. IUPAC concluded that RIKEN had been the first to convincingly synthesize the element.
  • JINR in Dubna, Russia, led principally by , in collaboration with several other labs including Lawrence Livermore National Laboratory (LLNL), since 2000:
    • 114. , Fl, named after the Flerov Laboratory of Nuclear Reactions in JINR (1999).
    • 115. , Mc, named after , where the element was discovered (2004).
    • 116. , Lv, named after Lawrence Livermore National Laboratory, a collaborator with JINR in the discovery (2000).
    • 117. , Ts, after , the location of Oak Ridge National Laboratory (2010).
    • 118. , Og, after , who led the JINR team in its discovery of elements 114 to 118 (2002).

Superheavy elements
Superheavy elements, (also known as superheavies, or superheavy atoms, commonly abbreviated SHE) usually refer to the transactinide elements beginning with (atomic number 104). (Lawrencium, the first 6d element, is sometimes but not always included as well.) They have only been made artificially and currently serve no practical purpose because their short half-lives cause them to decay after a very short time, ranging from a few hours to just milliseconds, which also makes them extremely hard to study.

Superheavies have all been created since the latter half of the 20th century and are continually being created during the 21st century as technology advances. They are created through the bombardment of elements in a particle accelerator, in quantities on the atomic scale, and no method of mass creation has been found.

Applications
Transuranic elements may be used to synthesize superheavy elements. Elements of the island of stability have potentially important military applications, including the development of compact nuclear weapons.
(1997). 9783933071026, International Network of Engineers and Scientists Against Proliferation. .
The potential everyday applications are vast; is used in devices such as and . Nuclear Data Viewer 2.4, NNDC

See also
  • Bose–Einstein condensate (also known as superatom)
  • Deep geological repository, a place to deposit transuranic waste

Further reading

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