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{| border="1" cellpadding="2" cellspacing="0" align="right" {| border="1" cellpadding="2" cellspacing="0" align="right"
| colspan="2" cellspacing="0" cellpadding="2" | | colspan="2" cellspacing="0" cellpadding="2" |
{| align="center" border="0" {| align="center" border="0"
| colspan="2" align="center" | ] &ndash; '''curium''' &ndash; ] | colspan="2" align="center" | ] &ndash; '''curium''' &ndash; ]
|- |-
| rowspan="3" valign="center" | ]<br>'''Cm'''<br /> | rowspan="3" valign="center" | ]<br>'''Cm'''<br />
&nbsp;&nbsp;&nbsp;<br />&nbsp;<br />&nbsp; &nbsp;&nbsp;&nbsp;<br />&nbsp;<br />&nbsp;
|- |-
| align="center" | ] | align="center" | ]
<div align="right"><small>]</small></div> <div align="right"><small>]</small></div>
|} |}
|- |-
! colspan="2" align=center bgcolor="#ff99cc" | '''General''' ! colspan="2" align=center bgcolor="#ff99cc" | '''General'''
|- |-
| ], ], ] | ], ], ]
| curium, Cm, 96 | curium, Cm, 96
|- |-
| ] | ]
| ]s | ]s
|- |-
| ], ] | ], ]
| ], ] | ], ]
|- |-
| ] | ]
| silvery | silvery
|- |-
! colspan="2" align="center" bgcolor="#ff99cc" | '''Atomic properties''' ! colspan="2" align="center" bgcolor="#ff99cc" | '''Atomic properties'''
|- |-
| ] | ]
| </nowiki> amu]] | </nowiki> amu]]
|- |-
| ] (calc.) | ] (calc.)
| no data | no data
|- |-
| ] | ]
| no data | no data
|- |-
| ] | ]
| no data | no data
|- |-
| ] | ]
| <nowiki>]<nowiki>]</nowiki>5f<sup>7</sup> 6]<sup>1</sup> 7]<sup>2</sup> | <nowiki>]<nowiki>]</nowiki>5f<sup>7</sup> 6]<sup>1</sup> 7]<sup>2</sup>
|- |-
| ] 's per ] | ] 's per ]
| 2,8,18,32,25,9,2 | 2,8,18,32,25,9,2
|- |-
| ]s (]) | ]s (])
| 3 (]) | 3 (])
|- |-
! colspan="2" align="center" bgcolor="#ff99cc" | '''Physical properties''' ! colspan="2" align="center" bgcolor="#ff99cc" | '''Physical properties'''
|- |-
| ] | ]
| 13510 ] | 13510 ]
|- |-
| ] | ]
| solid | solid
|- |-
| ] | ]
| 1613 ] (2444 ]) | 1613 ] (2444 ])
|- |-
| ] | ]
| 3383 K (5630 °F) | 3383 K (5630 °F)
|- |-
| ] | ]
| hexagonal close-packed | hexagonal close-packed
|- |-
| ] | ]
| no data | no data
|- |-
| ] | ]
| no data | no data
|- |-
| ] | ]
| 18.05 ]10<sup>-6</sup> ] | 18.05 ]10<sup>-6</sup> ]
|- |-
| ] | ]
| no data | no data
|- |-
| ] | ]
| 15 ] | 15 ]
|- |-
| ] | ]
| no data | no data
|- |-
| ] | ]
| no data | no data
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! colspan="2" align="center" bgcolor="#ff99cc" | '''Miscellaneous''' ! colspan="2" align="center" bgcolor="#ff99cc" | '''Miscellaneous'''
|- |-
| ] | ]
| 1.3 (]) | 1.3 (])
|- |-
| ] | ]
| no data | no data
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| ] | ]
| no data | no data
|- |-
| ] | ]
| no data | no data
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| 1<sup>st</sup> ] | 1<sup>st</sup> ]
| 581 kJ/mol | 581 kJ/mol
|- |-
! colspan="2" align="center" bgcolor="#ff99cc" | '''Most stable isotopes''' ! colspan="2" align="center" bgcolor="#ff99cc" | '''Most stable isotopes'''
|- |-
| colspan="2" | | colspan="2" |
{| border="1" cellspacing="0" cellpadding="2" width="100%" {| border="1" cellspacing="0" cellpadding="2" width="100%"
! ] ! ]
! ] ! ]
! ] ! ]
! ] ! ]
! ] ]] ! ] ]]
! ] ! ]
|- |-
| <sup>243</sup>Cn | <sup>243</sup>Cn
| ] | ]
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| 6.169<br />0.009<br />&nbsp; | 6.169<br />0.009<br />&nbsp;
| <sup>239</sup>]<br /><sup>243</sup>]<br />&nbsp; | <sup>239</sup>]<br /><sup>243</sup>]<br />&nbsp;
|- |-
| <sup>242</sup>Cm | <sup>242</sup>Cm
| {syn.} | {syn.}
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| &nbsp;<br />6.1 | &nbsp;<br />6.1
| &nbsp;<br /><sup>238</sup>Pu | &nbsp;<br /><sup>238</sup>Pu
|- |-
| <sup>244</sup>Cm | <sup>244</sup>Cm
| {syn.} | {syn.}
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| &nbsp;<br />5.902 | &nbsp;<br />5.902
| &nbsp;<br /><sup>240</sup>Pu | &nbsp;<br /><sup>240</sup>Pu
|- |-
| <sup>245</sup>Cm | <sup>245</sup>Cm
| {syn.} | {syn.}
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| &nbsp;<br />5.623 | &nbsp;<br />5.623
| &nbsp;<br /><sup>241</sup>Pu | &nbsp;<br /><sup>241</sup>Pu
|- |-
| <sup>246</sup>Pu | <sup>246</sup>Pu
| {syn.} | {syn.}
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| 5.475<br />&nbsp; | 5.475<br />&nbsp;
| <sup>242</sup>Pu | <sup>242</sup>Pu
|- |-
| <sup>247</sup>Cm | <sup>247</sup>Cm
| {syn.} | {syn.}
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| 5.353 | 5.353
| <sup>243</sup>Pu | <sup>243</sup>Pu
|- |-
| <sup>248</sup>Cm | <sup>248</sup>Cm
| {syn.} | {syn.}
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| 5.162<br />&nbsp; | 5.162<br />&nbsp;
| <sup>244</sup>Pu<br />&nbsp; | <sup>244</sup>Pu<br />&nbsp;
|- |-
| <sup>250</sup>Cm | <sup>250</sup>Cm
| {syn.} | {syn.}
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| &nbsp;<br /><sup>246</sup>Pu<br /><sup>250</sup>] | &nbsp;<br /><sup>246</sup>Pu<br /><sup>250</sup>]
|} |}
|- |-
! colspan="2" align="center" bgcolor="#ff99cc" | <font size="-1">] units & ] are used except where noted.</font> ! colspan="2" align="center" bgcolor="#ff99cc" | <font size="-1">] units & ] are used except where noted.</font>
|} |}
'''Curium''' is a ] in the ] that has the symbol Cm and ] 96. A ] ]lic ] of the ] series, curium is produced by bombarding ] with ]s (] ]s) and was named for ] and her husband ]. '''Curium''' is a ] in the ] that has the symbol Cm and ] 96. A ] ]lic ] of the ] series, curium is produced by bombarding ] with ]s (] ]s) and was named for ] and her husband ].


== Notable characteristics == == Notable characteristics ==
The ] curium-248 has been synthesized only in milligram quantities, but curium-242 and curium-244 are made in multigram amounts, which allows for the determination of some of the element's properties. Curium-244 can be made in quantity by subjecting ] to neutron bombardment. Very small amounts of curium may exist in ] ore as a daughter product of natural decay. There are few commercial applications for curium but it may one day be useful in radioisotope thermoelectric generators. Curium ]s in ] tissue where its radiation destroys ] and thus stops ] creation. The ] curium-248 has been synthesized only in milligram quantities, but curium-242 and curium-244 are made in multigram amounts, which allows for the determination of some of the element's properties. Curium-244 can be made in quantity by subjecting ] to neutron bombardment. Very small amounts of curium may exist in ] ore as a daughter product of natural decay. There are few commercial applications for curium but it may one day be useful in radioisotope thermoelectric generators. Curium ]s in ] tissue where its radiation destroys ] and thus stops ] creation.


A ] homolog, curium is somewhat chemically similar to ] but with a more complex ]. Chemically reactive, its ] is silvery-white in color and the element is more ] than ] (most trivalent curium ]s are slightly yellow). Curium-242 is useful as a portable energy source due to the fact that it can generate around 2 ]s of thermal ] per gram. It is used in ]s, remote navigational buoys, and in ] missions. A ] homolog, curium is somewhat chemically similar to ] but with a more complex ]. Chemically reactive, its ] is silvery-white in color and the element is more ] than ] (most trivalent curium ]s are slightly yellow). Curium-242 is useful as a portable energy source due to the fact that it can generate around 2 ]s of thermal ] per gram. It is used in ]s, remote navigational buoys, and in ] missions.


Several curium compounds have been produced. They include: curium dioxide (Cm]<sub>2</sub>), curium trioxide (Cm<sup>2</sup>O<sub>3</sub>), curium bromide (Cm]<sub>3</sub>), curium chloride (Cm]<sub>3</sub>), curium tetrafluoride (Cm]<sub>4</sub>) and curium iodide (Cm]<sub>3</sub>). Several curium compounds have been produced. They include: curium dioxide (Cm]<sub>2</sub>), curium trioxide (Cm<sup>2</sup>O<sub>3</sub>), curium bromide (Cm]<sub>3</sub>), curium chloride (Cm]<sub>3</sub>), curium tetrafluoride (Cm]<sub>4</sub>) and curium iodide (Cm]<sub>3</sub>).


== History == == History ==
Curium was ] at the ] and by ], Ralph A. James, and ] in ]. The team named the new element after ] and her husband ] who are famous for discovering ] and for their work in ]. It was chemically identified at the Metallurgical Laboratory (now ]) at the ]. It was actually the third transuranium element to be discovered even though it is the second in the series. Curium-242 (] 163 days) and one free ] were made by bombarding ]s onto a ]-239 target in the 60-inch ] at Berkeley. Louis Werner and Isadore Perlman created a visible sample of curium-242 ] at the ] in ] by bombarding ]-241 with neutrons. Curium was made in its elemental form in ] for the first time. Curium was ] at the ] and by ], Ralph A. James, and ] in ]. The team named the new element after ] and her husband ] who are famous for discovering ] and for their work in ]. It was chemically identified at the Metallurgical Laboratory (now ]) at the ]. It was actually the third transuranium element to be discovered even though it is the second in the series. Curium-242 (] 163 days) and one free ] were made by bombarding ]s onto a ]-239 target in the 60-inch ] at Berkeley. Louis Werner and Isadore Perlman created a visible sample of curium-242 ] at the ] in ] by bombarding ]-241 with neutrons. Curium was made in its elemental form in ] for the first time.


== Isotopes == == Isotopes ==
19 ]s of curium have been characterized, with the most stable being Cm-247 with a ] of 1.56 &times; 10<sup>7</sup> ]s, Cm-248 with a half-life of 3.40 &times; 10<sup>5</sup> years, Cm-250 with a half-life of 9000 years, and Cm-245 with a half-life of 8500 years. All of the remaining ] isotopes have half-lifes that are less than 30 years, and the majority of these have half lifes that are less than 33 days. This element also has 4 ]s, with the most stable being Cm-244m (t<sub>½</sub> 34 ms). The isotopes of curium range in ] from 233.051 ] (Cm-233) to 252.085 amu (Cm-252). 19 ]s of curium have been characterized, with the most stable being Cm-247 with a ] of 1.56 &times; 10<sup>7</sup> ]s, Cm-248 with a half-life of 3.40 &times; 10<sup>5</sup> years, Cm-250 with a half-life of 9000 years, and Cm-245 with a half-life of 8500 years. All of the remaining ] isotopes have half-lifes that are less than 30 years, and the majority of these have half lifes that are less than 33 days. This element also has 4 ]s, with the most stable being Cm-244m (t<sub>½</sub> 34 ms). The isotopes of curium range in ] from 233.051 ] (Cm-233) to 252.085 amu (Cm-252).


==References== ==References==
* *
* ''Guide to the Elements - Revised Edition'', Albert Stwertka, (Oxford University Press; 1998) ISBN 0-19-508083-1 * ''Guide to the Elements - Revised Edition'', Albert Stwertka, (Oxford University Press; 1998) ISBN 0-19-508083-1
* *


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Revision as of 09:57, 20 March 2005

americiumcuriumberkelium
Gd
Cm

   
 
 

File:-TableImage.png Full table
General
Name, Symbol, Number curium, Cm, 96
Chemical series actinides
Period, Block 7, f
Appearance silvery
Atomic properties
Atomic weight amu
Atomic radius (calc.) no data
Covalent radius no data
van der Waals radius no data
Electron configuration 5f 6d 7s
e 's per energy level 2,8,18,32,25,9,2
Oxidation states (Oxide) 3 (amphoteric)
Physical properties
Density 13510 kg/m
State of matter solid
Melting point 1613 K (2444 °F)
Boiling point 3383 K (5630 °F)
Crystal structure hexagonal close-packed
Hardness no data
Magnetic ordering no data
Molar volume 18.05 ×10 m/mol
Heat of vaporization no data
Heat of fusion 15 kJ/mol
Vapor pressure no data
Velocity of sound no data
Miscellaneous
Electronegativity 1.3 (Pauling scale)
Specific heat capacity no data
Electrical conductivity no data
Thermal conductivity no data
1 ionization potential 581 kJ/mol
Most stable isotopes
iso NA half-life DM DE MeV DP
Cn {syn.} 29.1 y α
ε
SF 		6.169
0.009
  		Pu
Am
 
Cm {syn.} 160 days SF
α 		 
6.1 		 
Pu
Cm {syn.} 18.1 y SF
α 		 
5.902 		 
Pu
Cm {syn.} 8500 y SF
α 		 
5.623 		 
Pu
Pu {syn.} 4730 y α
SF 		5.475
  		Pu
Cm {syn.} 15.6 E6 y α 5.353 Pu
Cm {syn.} 340 E3 y α
SF 		5.162
  		Pu
 
Cm {syn.} 9000 y SF
α
β 		 
5.169
0.037 		 
Pu
Bk
SI units & STP are used except where noted.

Curium is a synthetic element in the periodic table that has 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.

Notable characteristics

The isotope curium-248 has been synthesized only in milligram quantities, but curium-242 and curium-244 are made in multigram 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. Very small amounts of curium may exist in uranium ore as a daughter product of natural decay. 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-242 is useful as a portable energy source due to the fact that it can generate around 2 watts of thermal energy per gram. It is used in pacemakers, remote navigational buoys, and in space missions.

Several curium compounds have been produced. They include: curium dioxide (CmO2), curium trioxide (CmO3), curium bromide (CmBr3), curium chloride (CmCl3), curium tetrafluoride (CmF4) and curium iodide (CmI3).

History

Curium was first synthesized at the University of California, Berkeley and by Glenn T. Seaborg, Ralph A. James, and Albert Ghiorso in 1944. 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 second 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. 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. Curium was made in its elemental form in 1951 for the first time.

Isotopes

19 radioisotopes of curium have been characterized, with the most stable being Cm-247 with a half-life of 1.56 × 10 years, Cm-248 with a half-life of 3.40 × 10 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-lifes that are less than 30 years, and the majority of these have half lifes 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 amu (Cm-233) to 252.085 amu (Cm-252).

References

External links

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