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curium

 
Dictionary: cu·ri·um   (kyʊr'ē-əm) pronunciation
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n. (Symbol Cm)
A silvery metallic synthetic radioactive transuranic element. Its longest lived isotope is Cm 247 with a half-life of 16.4 million years. Atomic number 96; melting point (estimated) 1,350°C; valence 3.

[After Marie CURIE and Pierre CURIE.]


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Sci-Tech Encyclopedia: Curium
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A chemical element, Cm, in the actinide series, with an atomic number of 96. Curium does not exist in the terrestrial environment, but may be produced artificially. The chemical properties of curium are so similar to those of the typical rare earths that, if it were not for its radioactivity, it might easily be mistaken for one of these elements. The known isotopes of curium include mass numbers 238–250. The isotope 244Cm is of particular interest because of its potential use as a compact, thermoelectric power source, through conversion to electrical power of the heat generated by nuclear decay. See also Periodic table.

Metallic curium may be produced by the reduction of curium trifluoride with barium vapor. The metal has a silvery luster, tarnishes in air, and has a specific gravity of 13.5. The melting point has been determined as 2444 ± 72°F (1340 ± 40°C). The metal dissolves readily in common mineral acids with the formation of the tripositive ion.

A number of solid compounds of curium have been prepared and their structures determined by x-ray diffraction. These include CmF4, CmF3, CmCl3, CmBr3, CmI3, Cm2O3, and CmO2. Isostructural analogs of the compounds of curium are observed in the lanthanide series of elements. See also Actinide elements; Transuranium elements.

 
Columbia Encyclopedia: curium
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curium (kyʊr'ēəm), artificially produced radioactive chemical element; symbol Cm; at. no. 96; mass no. of most stable isotope 247; m.p. about 1,340°C; b.p. 3,110°C; sp. gr. 13.5 (calculated); valence +3, +4. A hard, brittle, silvery metal that tarnishes in air, curium is chemically reactive and resembles gadolinium in its chemical properties, although it has a more complex crystalline structure. Oxides, fluorides, a chloride, a bromide, and an iodide of curium have been prepared. Curium is a member of the actinide series in Group 3 of the periodic table. Sixteen isotopes of curium are known. Curium-242, prepared by neutron bombardment of americium-241, has a half-life of 163 days; curium-247, the most stable isotope, has a half-life of 15.6 million years. Some curium isotopes are available in multigram quantities.

Curium is intensely radioactive; it is about 3,000 times as radioactive as radium. It is also very toxic when absorbed into the body because it accumulates in the bones and disrupts the formation of red blood cells. Curium-242 and curium-244 are used in the space program as a heat source (from the heat they generate as they undergo radioactive decay) for compact thermionic and thermoelectric power generation.

Curium has not been found to occur naturally; it was the third transuranium element to be synthesized. Curium was first produced by the bombardment of plutonium-239 with alpha particles in a cyclotron at the Univ. of California at Berkeley. Identified in 1944 by Glenn T. Seaborg, Ralph A. James, and Albert Ghiorso, it was named for Pierre and Marie Curie, the noted pioneers in the study of radioactivity. The metal was first isolated in visible amounts as the hydroxide by L. B. Werner and I. Perlman in 1947.

Veterinary Dictionary: curium
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A chemical element, atomic number 96, atomic weight 247, symbol Cm.

Wikipedia: Curium
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This article is about the chemical element. For the ancient city located in Cyprus, see Kourion.
americiumcuriumberkelium
Gd

Cm

(Uqh)
Appearance
silvery
General properties
Name, symbol, number curium, Cm, 96
Element category actinide
Group, period, block n/a7, f
Standard atomic weight (247)g·mol−1
Electron configuration [Rn] 5f7 6d1 7s2
Electrons per shell 2, 8, 18, 32, 25, 9, 2 (Image)
Physical properties
Phase solid
Density (near r.t.) 13.51 g·cm−3
Melting point 1613 K
Boiling point 3383 K
Heat of fusion  ? 15 kJ·mol−1
Vapor pressure
P/Pa 1 10 100 1 k 10 k 100 k
at T/K 1788 1982        
Atomic properties
Oxidation states 4, 3 (amphoteric oxide)
Electronegativity 1.3 (Pauling scale)
Ionization energies 1st: 581 kJ·mol−1
Atomic radius 174 pm
Covalent radius 169±3 pm
Miscellanea
Crystal structure hexagonal close-packed
Magnetic ordering no data
CAS registry number 7440-51-9
Most stable isotopes
Main article: Isotopes of curium
iso NA half-life DM DE (MeV) DP
242Cm syn 160 days SF - -
α 6.1 238Pu
243Cm syn 29.1 y α 6.169 239Pu
ε 0.009 243Am
SF - -
244Cm syn 18.1 y SF - -
α 5.902 240Pu
245Cm syn 8500 y SF - -
α 5.623 241Pu
246Cm syn 4730 y α 5.475 242Pu
SF - -
247Cm syn 1.56×107 y α 5.353 243Pu
248Cm syn 3.40×105 y α 5.162 244Pu
SF - -
250Cm syn 9000 y SF - -
α 5.169 246Pu
β 0.037 250Bk
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Curium (pronounced /ˈkjʊəriəm/ KEWR-ee-əm) is a synthetic chemical element with the symbol Cm and atomic number 96. A radioactive metallic transuranic element of the actinide series, curium is produced by bombarding plutonium with alpha particles (helium ions) and was named for Marie Curie and her husband Pierre.

Contents

Characteristics

The isotope curium-248 has been synthesized only in milligram quantities, but curium-242 and curium-244 are made in gram amounts, which allows for the determination of some of the element's properties. Curium-244 can be made in quantity by subjecting plutonium to neutron bombardment. Curium does not occur in nature. There are few commercial applications for curium but it may one day be useful in radioisotope thermoelectric generators. Curium bio-accumulates in bone tissue where its radiation destroys bone marrow and thus stops red blood cell creation.

A rare earth homolog, curium is somewhat chemically similar to gadolinium but with a more complex crystal structure. Chemically reactive, its metal is silvery-white in color and the element is more electropositive than aluminium (most trivalent curium compounds are slightly yellow).

Curium has been studied greatly as a potential fuel for radioisotope thermoelectric generators (RTG). Curium-242 can generate up to 120 watts of thermal energy per gram (W/g); however, its very short half-life makes it undesirable as a power source for long-term use. Curium-242 can decay by alpha emission to plutonium-238 which is the most common fuel for RTGs. Curium-244 has also been studied as an energy source for RTGs having a maximum energy density ~3 W/g,[1] but produces a large amount of neutron radiation from spontaneous fission. Curium-243 with a ~30 year half-life and good energy density of ~1.6 W/g would seem to make an ideal fuel, but it produces significant amounts of gamma and beta radiation from radioactive decay products.

Compounds

Some compounds are:

  • curium dioxide (CmO2)
  • curium trioxide (Cm2O3)
  • curium bromide (CmBr3)
  • curium chloride (CmCl3)
  • curium tetrafluoride (CmF4)
  • curium iodide (CmI3)

History

Curium was first synthesized at the University of California, Berkeley by Glenn T. Seaborg, Ralph A. James, and Albert Ghiorso in 1944.[2] The team named the new element after Marie Curie and her husband Pierre who are famous for discovering radium and for their work in radioactivity. It was chemically identified at the Metallurgical Laboratory (now Argonne National Laboratory) at the University of Chicago. It was actually the third transuranium element to be discovered even though it is the fourth in the series. Curium-242 (half-life 163 days) and one free neutron were made by bombarding alpha particles onto a plutonium-239 target in the 60-inch cyclotron at Berkeley.[3]

23994Pu + 42He24296Cm + 10n

Due to the fact that the discovery of the new elements, curium and americium, was closely related to the Manhattan Project the results were confidential and publication was impossible. Seaborg announced the discovery of the elements on the radio show for kids, the Quiz Kids, five days before the official presentation at an American Chemical Society meeting on November 11, 1945.[4] Seaborg also patented the synthesis of the new elements.[5]

Louis Werner and Isadore Perlman created a visible sample of curium-242 hydroxide at the University of California in 1947 by bombarding americium-241 with neutrons.[6] Curium was made in its elemental form in 1951 for the first time.[7][8]

Isotopes

Main article: Isotopes of curium

19 radioisotopes of curium have been characterized, with the most stable being Cm-247 with a half-life of 1.56 × 107 years, Cm-248 with a half-life of 3.40 × 105 years, Cm-250 with a half-life of 9000 years, and Cm-245 with a half-life of 8500 years. All of the remaining radioactive isotopes have half-lives that are less than 30 years, and the majority of these have half-lives that are less than 33 days. This element also has 4 meta states, with the most stable being Cm-244m (t½ 34 ms). The isotopes of curium range in atomic weight from 233.051 u (Cm-233) to 252.085 u (Cm-252).

Nuclear fuel cycle

Transmutation flow between 238Pu and 244Cm in LWR.[9]
Fission percentage is 100 minus shown percentages.
Total rate of transmutation varies greatly by nuclide.
245Cm–248Cm are long-lived with negligible decay.
Thermal neutron cross sections (barns)
242Cm 243Cm 244Cm 245Cm 246Cm 247Cm
Fission 5 617 1.04 2145 0.14 81.90
Capture 16 130 15.20 369 1.22 57
C/F ratio 3.20 0.21 14.62 0.17 8.71 0.70
LEU spent fuel 20 years after 53 MWd/kg burnup[10]
3 common isotopes 51 3700 390
Fast reactor MOX fuel (avg 5 samples, burnup 66-120GWd/t)[11]
Total curium 3.09 × 10−3% 27.64% 70.16% 2.166% 0.0376% 0.000928%

The odd-mass number isotopes are fissile, the even-mass number isotopes are not and can only capture neutrons, but very slowly. Therefore in a thermal reactor the even-mass isotopes accumulate as burnup increases.

The MOX which is to be used in power reactors should contain little or no curium as the neutron activation of 248Cm will create californium which is a strong neutron emitter. The californium would pollute the back end of the fuel cycle and increase the dose to workers. Hence if the minor actinides are to be used as fuel in a thermal neutron reactor, the curium should be excluded from the fuel or placed in special fuel rods where it is the only actinide present.

Applications

The Curium isotopes 244Cm and 242Cm are strong alpha emitters with a halflife in the months to years range and produce considerable heat during this process. These properties make them useful for applications as alpha particle source and as heat generator in radioisotope thermoelectric generators (RTG).

A 244Curium source is used for the Alpha particle X-ray spectrometer on board several American and European space missions, for example the Mars Exploration Rover[12] and the Rosetta/Philae. The use in RTG is proposed for several future missions.[13][14]

References

  1. ^ Gmelins Handbuch der anorganischen Chemie, System Nr. 71, Band 7 a, Transurane, Teil A 2, p. 289.
  2. ^ Hall, Nina (2000). The New Chemistry: A Showcase for Modern Chemistry and Its Applications. Cambridge University Press. pp. 8–9. ISBN 9780521452243. http://books.google.com/books?id=U4rnzH9QbT4C. 
  3. ^ G. T. Seaborg, R. A. James, A. Ghiorso: "The New Element Curium (Atomic Number 96)", NNES PPR (National Nuclear Energy Series, Plutonium Project Record), Vol. 14B, The Transuranium Elements: Research Papers, Paper No. 22.2, McGraw-Hill Book Co., Inc., New York, 1949; Abstract; Typoskript (January 1948).
  4. ^ PEPLING, RACHEL SHEREMETA (2003). "Chemical & Engineering News: It's Elemental: The Periodic Table – Americium". http://pubs.acs.org/cen/80th/americium.html. Retrieved 07-12-2008. 
  5. ^ Glen T. Seaborg "Element" U.S. Patent 3,161,462 Issue date: December 1964
  6. ^ L. B. Werner, I. Perlman: "Isolation of Curium", NNES PPR (National Nuclear Energy Series, Plutonium Project Record), Vol. 14 B, The Transuranium Elements: Research Papers, Paper No. 22.5, McGraw-Hill Book Co., Inc., New York, 1949.
  7. ^ Wallmann, J. C.; Crane, W. W. T.; Cunningham, B. B. (1951). "The Preparation and Some Properties of Curium Metal". Journal of the American Chemical Society 73 (1): 493–494. doi:10.1021/ja01145a537. 
  8. ^ Werner, L. B., L. B. last =Werner; Perlman, I. (1951). "First Isolation of Curium"". Journal of the American Chemical Society 73 (1): 5215–5217. doi:10.1021/ja01155a063. 
  9. ^ Sasahara, Akihiro (2004). "Neutron and Gamma Ray Source Evaluation of LWR High Burn-up UO2 and MOX Spent Fuels". Journal of Nuclear Science and Technology 41 (4): 448–456. doi:10.3327/jnst.41.448. http://www.jstage.jst.go.jp/article/jnst/41/4/448/_pdf. 
  10. ^ "Limited Proliferation-Resistance Benefits from Recycling Unseparated Transuranics and Lanthanides from Light-Water Reactor Spent Fuel" (PDF). p. 4. http://www.princeton.edu/~globsec/publications/pdf/13_3%20Kang%20vonhippel.pdf. 
  11. ^ "Analysis of Curium Isotopes in Mixed Oxide Fuel Irradiated in Fast Reactor" (PDF). http://wwwsoc.nii.ac.jp/aesj/publication/JNST2001/No.10/38_912-914.pdf. 
  12. ^ R. Rieder, R. Gellert, J. Brückner, G. Klingelhöfer, G. Dreibus, A. Yen, S. W. Squyres (2003). "The new Athena alpha particle X-ray spectrometer for the Mars Exploration Rovers". J. Geophysical Research 108: 8066. doi:10.1029/2003JE002150. 
  13. ^ Miskolczy, G.; Lieb, D.P. (1990). "Radioisotope Thermionic Converters for Space Applications". Energy Conversion Engineering Conference (IECEC-90) 1: 222–226. doi:10.1109/IECEC.1990.716874. 
  14. ^ O’Brien,, R.C.; Ambrosi, R. M.; Bannister, N.P.; Howe S.D.; Atkinso, H. V. (2008). "Safe radioisotope thermoelectric generators and heat sources for space applications". Journal of Nuclear Materials 377 (3): 506–521. doi:10.1016/j.jnucmat.2008.04.009. 

Literature

  • Guide to the Elements - Revised Edition, Albert Stwertka, (Oxford University Press; 1998) ISBN 0-19-508083-1.

External links

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