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thorium

[ thawr-ee-uhm, thohr- ]

noun

, Chemistry.
  1. a grayish-white, lustrous, somewhat ductile and malleable, radioactive metallic element present in monazite: used as a source of nuclear energy, as a coating on sun-lamp and vacuum-tube filament coatings, and in alloys. : Th; : 232.038; : 90; : 11.7.


thorium

/ ˈθɔːrɪəm /

noun

  1. a soft ductile silvery-white metallic element. It is radioactive and occurs in thorite and monazite: used in gas mantles, magnesium alloys, electronic equipment, and as a nuclear power source. Symbol: Th; atomic no: 90; atomic wt: 232.0381; half-life of most stable isotope, 232Th: 1.41 × 10 10years; valency: 4; relative density: 11.72; melting pt: 1755°C; boiling pt: 4788°C
“Collins English Dictionary — Complete & Unabridged” 2012 Digital Edition © William Collins Sons & Co. Ltd. 1979, 1986 © HarperCollins Publishers 1998, 2000, 2003, 2005, 2006, 2007, 2009, 2012

thorium

/ thôrē-əm /

  1. A silvery-white, radioactive metallic element of the actinide series. It is used for fuel in some nuclear reactors and for improving the high-temperature strength of magnesium alloys. The only naturally occurring isotope of thorium, Th 232, is also its most stable, having a half-life of 14.1 billion years. Atomic number 90; atomic weight 232.038; approximate melting point 1,750°C; approximate boiling point 4,500°C; approximate specific gravity 11.7; valence 4.
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Derived Forms

  • ˈthoric, adjective
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Other Words From

  • thor·ic [thawr, -ik, thor, -], adjective
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Word History and Origins

Origin of thorium1

< New Latin (1829); Thor, -ium
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Word History and Origins

Origin of thorium1

C19: New Latin, from Thor + -ium
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Example Sentences

Unlike uranium, thorium doesn't dissolve well in water, so it precipitates out on particles in the water column.

Weathering may have ultimately concentrated heat-producing elements like uranium, thorium and potassium in the shallow crust, allowing the deeper crust to cool and harden.

Heavy elements may result from this "nucleosynthesis"; in fact, half of the heavy isotopes up to bismuth and all of thorium and uranium in the universe may have been created by the r process.

It forms through the radioactive decay of uranium and thorium deep in the crust and eventually seeps out and escapes into space.

Other elements such as iodine and thorium, which are needed to sustain life on earth, are also likely to be amongst the material ejected by the explosion, also known as a kilonova.

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thoritethorium dioxide