protoactinium$64806$ - traduction vers Anglais
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protoactinium$64806$ - traduction vers Anglais

ELEMENT WITH SYMBOL PA AND ATOMIC NUMBER OF 91
Element 91; Meitnium; Protoactinium; Proactinium; Protactinium chloride; PaCl5; Protactinium pentachloride; Uranium-X; Pa (element); Pa element; History of protactinium
  • [[Dmitri Mendeleev]]'s 1871 periodic table with a gap for protactinium on the bottom row of the chart, between thorium and uranium
  • Coordination of protactinium (solid circles) and halogen atoms (open circles) in protactinium(V) fluoride or chloride.
  • Protactinium occurs in [[uraninite]] ores.
  • The proposed structure of the protactinocene (Pa(C<sub>8</sub>H<sub>8</sub>)<sub>2</sub>) molecule

protoactinium      
n. protoactinium (radioaktief metaalelement)

Définition

protactinium
[?pr??tak't?n??m]
¦ noun the chemical element of atomic number 91, a radioactive metal of the actinide series, occurring in small amounts as a product of the natural decay of uranium. (Symbol: Pa)
Origin
early 20th cent.: from proto- + actinium, so named because one of its isotopes decays to form actinium.

Wikipédia

Protactinium

Protactinium (formerly protoactinium) is a chemical element with the symbol Pa and atomic number 91. It is a dense, silvery-gray actinide metal which readily reacts with oxygen, water vapor and inorganic acids. It forms various chemical compounds in which protactinium is usually present in the oxidation state +5, but it can also assume +4 and even +3 or +2 states. Concentrations of protactinium in the Earth's crust are typically a few parts per trillion, but may reach up to a few parts per million in some uraninite ore deposits. Because of its scarcity, high radioactivity and high toxicity, there are currently no uses for protactinium outside scientific research, and for this purpose, protactinium is mostly extracted from spent nuclear fuel.

The element was first identified in 1913 by Kazimierz Fajans and Oswald Helmuth Göhring and named brevium because of the short half-life of the specific isotope studied, i.e. protactinium-234. A more stable isotope of protactinium, 231Pa, was discovered in 1917/18 by Lise Meitner in collaboration with Otto Hahn, and they chose the name protactinium. The IUPAC chose the name "protactinium" in 1949 and confirmed Hahn and Meitner as discoverers. The new name meant "(nuclear) precursor of actinium" and reflected that actinium is a product of radioactive decay of protactinium. John Arnold Cranston (working with Frederick Soddy and Ada Hitchins) is also credited with discovering the most stable isotope in 1915, but delayed his announcement due to being called up for service in the First World War.

The longest-lived and most abundant (nearly 100%) naturally occurring isotope of protactinium, protactinium-231, has a half-life of 32,760 years and is a decay product of uranium-235. Much smaller trace amounts of the short-lived protactinium-234 and its nuclear isomer protactinium-234m occur in the decay chain of uranium-238. Protactinium-233 results from the decay of thorium-233 as part of the chain of events used to produce uranium-233 by neutron irradiation of thorium-232. It is an undesired intermediate product in thorium-based nuclear reactors and is therefore removed from the active zone of the reactor during the breeding process. Ocean science utilizes the element to understand the ancient ocean. Analysis of the relative concentrations of various uranium, thorium and protactinium isotopes in water and minerals is used in radiometric dating of sediments which are up to 175,000 years old and in modeling of various geological processes.