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'''Curium(III) oxide''' is a ] composed of ] and ] with the chemical formula {{curium|2}}{{oxygen|3}}. It is a crystalline solid with a ] that contains two curium atoms and three oxygen atoms. The simplest synthesis equation involves the reaction of curium(III) metal with O<sup>2-</sup>: 2 Cm<sup>3+</sup> + 3 O<sup>2-</sup> ---> Cm<sub>2</sub>O<sub>3</sub> |
'''Curium(III) oxide''' is a ] composed of ] and ] with the chemical formula {{curium|2}}{{oxygen|3}}. It is a crystalline solid with a ] that contains two curium atoms and three oxygen atoms. The simplest synthesis equation involves the reaction of curium(III) metal with O<sup>2-</sup>: 2 Cm<sup>3+</sup> + 3 O<sup>2-</sup> ---> Cm<sub>2</sub>O<sub>3</sub>.<ref>8. N.A. (2010). “Study of oxychloride compound formation in chloride melt by spectroscopic methods''.”'' Radiochemical Division/Research Institute of Atomic Reactors. pp. 1-17.</ref> Curium trioxide can exist as five ] forms.<ref>Cunningham, B.B. (1964). “Chemistry of the Actinide Elements.” ''Annual Review of Nuclear Science'' (n.a): 323-347.</ref><ref name=":0">Milman, V., Winkler, B., and C.J. Pickard (2003). “Crystal Structures of Curium Compounds: An Ab Initio Study''.” Journal of Nuclear Materials'' (322): 165-179.</ref> Two of the forms exist at extremely high temperatures, making it difficult for experimental studies to be done on the formation of their structures. The three other possible forms which curium sesquioxide can take are the ] form, the ] form, and the ] form.<ref name=":0" /><ref name=":4">Petit, L., Svane, A., Szotek, Z., Temmerman, W.M., and G. M. Stocks (2009). “Electronic structure and ionicity of actinide oxides from first principles calculations.” Materials Science and Technology Division, Oak Ridge National Laboratory. pp. 1-12.</ref> Curium(III) oxide is either white or light tan in color and, while ] in ], is soluble in inorganic and ]s.<ref>{{cite book|last=Norman M. Edelstein, James D. Navratil, Wallace W. Schulz|title=Americium and curium chemistry and technology|year=1984|publisher=D. Reidel Pub. Co.|pages=167–168}}</ref><ref name=":1">Helfinstine, Suzanne Y., Guilmette, Raymond A., and Gerald A. Schlapper (1992). “In Vitro Dissolution of Curium Oxide Using a Phagolysosomal Simulant Solvent System.” ''Environmental Health Perspectives'' (97): 131-137.</ref> Its synthesis was first recognized in 1955.<ref name=":5">Morss, L. R., Fuger, J., Goffart, J. and R.G. Haire (1983). “Enthalpy of Formation and Magnetic Susceptibility of Curium Sesquioxide, Cm<sub>2</sub>0<sub>3</sub>.” ''Inorganic Chemistry'' (22)'':''1993-1996.</ref> | ||
== Synthesis == | == Synthesis == | ||
Curium sesquioxide can be prepared in a variety of ways. (Note: Keep in mind that the ways listed below do not contain all of the possible ways in which it can be produced.) | Curium sesquioxide can be prepared in a variety of ways. (Note: Keep in mind that the ways listed below do not contain all of the possible ways in which it can be produced.) | ||
<u>Ignition with O]:</u> Curium(III) oxalate is precipitated through a capillary tube. The precipitate is ignited by gaseous oxygen at 400 |
<u>Ignition with O]:</u> Curium(III) oxalate is precipitated through a capillary tube. The precipitate is ignited by gaseous oxygen at 400 °C, and the resulting product is thermally ] via 600 °C and 10<sup>−4</sup> mm of pressure.<ref name=":2">Wallmann, J.C. (1964). “A Structural Transformation of Curium Sesquioxide.” ''Journal of Inorganic and Nuclear Chemistry'' (26): 2053-2057.</ref> | ||
<u>Aerosolized Curium Sesquioxide:</u> The aerosolization process of Cm<sub>2</sub>O<sub>3</sub> can be done through multiple experimental processes. Typically, Cm<sub>2</sub>O<sub>3</sub> is aerosolized for experimental procedures which set out to discover the effects of curium metal within a biological system<ref name=":1" /><ref name=":3">Lundgren, D. L. , Hahn, F. F., Carlton, W. W., Griffith, W. C., Guilmette, R. A., and N. A. Gillett (1997). “Dose Responses from Inhaled Monodisperse Aerosols of <sup>244</sup>Cm<sub>2</sub>0<sub>3</sub> in the Lung, Liver and Skeleton of F344 Rats and Comparison with <sup>239</sup>Pu0<sub>2</sub>.” ''Radiation Research'' (5): 598-612.</ref> |
<u>Aerosolized Curium Sesquioxide:</u> The aerosolization process of Cm<sub>2</sub>O<sub>3</sub> can be done through multiple experimental processes. Typically, Cm<sub>2</sub>O<sub>3</sub> is aerosolized for experimental procedures which set out to discover the effects of curium metal within a biological system.<ref name=":1" /><ref name=":3">Lundgren, D. L. , Hahn, F. F., Carlton, W. W., Griffith, W. C., Guilmette, R. A., and N. A. Gillett (1997). “Dose Responses from Inhaled Monodisperse Aerosols of <sup>244</sup>Cm<sub>2</sub>0<sub>3</sub> in the Lung, Liver and Skeleton of F344 Rats and Comparison with <sup>239</sup>Pu0<sub>2</sub>.” ''Radiation Research'' (5): 598-612.</ref> | ||
''Route 1:'' The traditional aerosolization reaction utilizes curium metal as the starting material. While curium metal has been discovered to naturally exist as a mixture of 87.4% <sup>244</sup>Cm, 8.4% <sup>243</sup>Cm, 3.9% other curium isotopes, and ~0.3% of the ], plutonium, in most aerosolized syntheses of curium(III) oxide, curium metal is purified through solvent extraction of curium nitrate and ''bis''(2-ethylhexyl) phosphoric acid in toluene to remove the plutonium<ref name=":1" /> |
''Route 1:'' The traditional aerosolization reaction utilizes curium metal as the starting material. While curium metal has been discovered to naturally exist as a mixture of 87.4% <sup>244</sup>Cm, 8.4% <sup>243</sup>Cm, 3.9% other curium isotopes, and ~0.3% of the ], plutonium, in most aerosolized syntheses of curium(III) oxide, curium metal is purified through solvent extraction of curium nitrate and ''bis''(2-ethylhexyl) phosphoric acid in toluene to remove the plutonium.<ref name=":1" /> NH<sub>3</sub>OH is then added to the purified curium nitrate, and the resulting precipitate is collected and rinsed with deionized water. The precipitate (Cm<sub>2</sub>O]) is resuspended in solvent and aerosolized with some sort of high output aerosol generator (ex: Lovelace ]).<ref name=":1" /> | ||
''Route 2:'' In other aerosolizations, instead of the addition of NH<sub>3</sub>OH to the purified curium nitrate, ammonium hydroxide is utilized to adjust the pH value of the solution to 9. The increased basicity of the solution creates a curium hydroxide precipitate. This precipitate is then collected through filtration and resuspended in deionized water, and a nebulizer is then used to aerosolize the product<ref name=":3" /> |
''Route 2:'' In other aerosolizations, instead of the addition of NH<sub>3</sub>OH to the purified curium nitrate, ammonium hydroxide is utilized to adjust the pH value of the solution to 9. The increased basicity of the solution creates a curium hydroxide precipitate. This precipitate is then collected through filtration and resuspended in deionized water, and a nebulizer is then used to aerosolize the product.<ref name=":3" /> | ||
<u>Reduction by Hydrogen Gas:</u> |
<u>Reduction by Hydrogen Gas:</u> A solution of curium trichloride is evaporated to dryness with pure nitric acid to produce curium nitrate. The curium nitrate is then ignited in air, producing curium oxide, believed to be an intermediate structure between CmO<sub>2</sub> and the formation of Cm<sub>2</sub>O<sub>3</sub>. The intermediate is scraped into capillary tubes attached to a vacuum system and reduced with gaseous hydrogen - the result of the combustion of UH<sub>3</sub>.<ref name=":2" /> | ||
<u>Obtaining Curium-244:</u> For many of the reactions described above, curium metal is provided by an outside retailer. In order to obtain curium metal, <sup>239</sup>Pu metal can be sent through the pile |
<u>Obtaining Curium-244:</u> For many of the reactions described above, curium metal is provided by an outside retailer. In order to obtain curium metal, <sup>239</sup>Pu metal can be sent through the pile ] process described by the ] processes below (note that neutrons are indicated by the letter "n" and beta-minus particles by "β−"): | ||
<sup>239</sup>Pu + n ---> <sup>240</sup>Pu + n ---> <sup>241</sup>Pu + n ---> <sup>242</sup>Pu + n ---> <sup>243</sup>Pu+ β− ---> <sup>243</sup>Am + n ---> <sup>244</sup>Am + β− ---> <sup>244</sup>Cu<ref>Stevens, C. M., Studier, M. H., Fields, P. R. , Meck, J. F., Sellers, P. A., Friedman, A. M., Diamond H., and J. R. Huizenga (1954). “Evidence for Quadrivalent Curium: X-Ray Data on Curium Oxides.” ''Communications to the Editor'' (7): 1707-1708.</ref> |
<sup>239</sup>Pu + n ---> <sup>240</sup>Pu + n ---> <sup>241</sup>Pu + n ---> <sup>242</sup>Pu + n ---> <sup>243</sup>Pu+ β− ---> <sup>243</sup>Am + n ---> <sup>244</sup>Am + β− ---> <sup>244</sup>Cu.<ref>Stevens, C. M., Studier, M. H., Fields, P. R. , Meck, J. F., Sellers, P. A., Friedman, A. M., Diamond H., and J. R. Huizenga (1954). “Evidence for Quadrivalent Curium: X-Ray Data on Curium Oxides.” ''Communications to the Editor'' (7): 1707-1708.</ref> | ||
However, <sup>244</sup>curium is one of the more unstable curium isotopes, so any structural data obtained for compounds containing <sup>244</sup>Cm may deviate from the expected as a result of structural damage<ref name=":0" /> |
However, <sup>244</sup>curium is one of the more unstable curium isotopes, so any structural data obtained for compounds containing <sup>244</sup>Cm may deviate from the expected as a result of structural damage.<ref name=":0" /> It has been experimentally determined that, within one day, <sup>244</sup>CmO<sub>2</sub>'s lattice parameter increases by a factor of 0.2%.<ref name=":0" /> This has been hypothesized to be a result of the weakening interatomic interactions between curium(IV) and the neighboring oxide groups as a result of alpha-decay. This affects the thermal conductivity of curium oxides, causing it to exponentially decrease over time as the effects of alpha-decay strengthen.<ref name=":6">S.E. Lemehov *, V. Sobolev, and P. Van Uffelen (2003). "Modelling thermal conductivity and self-irradiation effects in mixed oxide fuels." ''Journal of Nuclear Materials'' (320): 66–76.</ref> Abnormal phase transitions have also been reported and have been theorized to be a result of induced self-irradiation, either by <sup>244</sup>Cm or the presence of leftover <sup>244</sup>Am from incomplete radioactive decay.<ref name=":0" /><ref name=":6" /> | ||
== Structure == | == Structure == | ||
The body-centered cubic and monoclinic forms are the most common polymorphic forms of curium trioxide, produced by the chemical reactions detailed above. Their crystalline structures are very similar. One of the polymorphs of curium trioxide - the body-centered cubic form - spontaneously transforms to the hexagonal form after several weeks<ref name=":2" /> |
The body-centered cubic and monoclinic forms are the most common polymorphic forms of curium trioxide, produced by the chemical reactions detailed above. Their crystalline structures are very similar. One of the polymorphs of curium trioxide - the body-centered cubic form - spontaneously transforms to the hexagonal form after several weeks.<ref name=":2" /> This transformation is undergone upon spontaneous <sup>244</sup>Cm alpha decay, which produces radiation damage effects within the cubic crystal lattice to distort it to that of hexagonal.<ref name=":0" /> Although not experimentally proven, there is speculation that monoclinic curium trioxide may be an intermediate form in between the transformation of the cubic form to that of the hexagonal. The body-centered cubic form of curium trioxide exists below temperatures of 800 °C, the monoclinic form between 800 °C and 1615 °C, and the hexagonal form above 1615 °C.<ref name=":2" /> | ||
== Crystallography == | == Crystallography == | ||
Line 64: | Line 64: | ||
] | ] | ||
{| class="wikitable" | {| class="wikitable" | ||
!Data Table<ref name=":7">Lumetta, Gregg J., Thompson, Major C., Penneman, Robert A., and P. Gary Eller (2006). ''The Chemistry of the Actinide and Transactinide Elements.'' “Curium: Chapter Nine.” Springer Pub. Co. Vol.3. pp. 1397-1443.</ref |
!Data Table<ref name=":2" /><ref name=":7">Lumetta, Gregg J., Thompson, Major C., Penneman, Robert A., and P. Gary Eller (2006). ''The Chemistry of the Actinide and Transactinide Elements.'' “Curium: Chapter Nine.” Springer Pub. Co. Vol.3. pp. 1397-1443.</ref> | ||
!Temperature ( |
!Temperature (°C) | ||
!Lengths of a (Å) | !Lengths of a (Å) | ||
!Uncertainty (Å) | !Uncertainty (Å) | ||
Line 85: | Line 85: | ||
|0.005 | |0.005 | ||
|} | |} | ||
(*: No specific temperature has been stated to produce the lengths listed in the second row<ref name=": |
(*: No specific temperature has been stated to produce the lengths listed in the second row.<ref name=":2" /><ref name=":7" />) | ||
<u>Monoclinic:</u> |
<u>Monoclinic:</u> | ||
] | ] | ||
{| class="wikitable" | {| class="wikitable" | ||
!Data Table<ref name=":8">Rimshaw, S. J., and E. E. Ketchen (1967). “Curium Data Sheets.” Oak Ridge National Laboratory - Union Carbide Corporation. pp. 42-102.</ref> | !Data Table<ref name=":8">Rimshaw, S. J., and E. E. Ketchen (1967). “Curium Data Sheets.” Oak Ridge National Laboratory - Union Carbide Corporation. pp. 42-102.</ref> | ||
!Temperature ( |
!Temperature (°C) | ||
!Lengths of a (Å) | !Lengths of a (Å) | ||
!Lengths of b (Å) | !Lengths of b (Å) | ||
Line 103: | Line 103: | ||
|3.65** | |3.65** | ||
|} | |} | ||
(**: None of these lengths contained given uncertainties<ref name=":8" /> |
(**: None of these lengths contained given uncertainties.<ref name=":8" />) | ||
<u>Cubic:</u> | <u>Cubic:</u> | ||
Line 110: | Line 110: | ||
{| class="wikitable" | {| class="wikitable" | ||
!Data Table<ref name=":2" /> | !Data Table<ref name=":2" /> | ||
!Temperature ( |
!Temperature (°C) | ||
!Lengths of a (Å) | !Lengths of a (Å) | ||
!Uncertainty (Å) | !Uncertainty (Å) | ||
Line 121: | Line 121: | ||
== Data == | == Data == | ||
Ever since the discovery (and isolation) of <sup>248</sup>Cm, the most stable curium isotope, experimental work on the thermodynamic properties of curium sesquioxide (and other curium compounds) has become more prevalent. However, <sup>248</sup>Cm can only be obtained in mg samples, so data collection for <sup>248</sup>Cm-containing compounds takes longer than that for compounds which predominantly contain other curium isotopes<ref name=":0" /> |
Ever since the discovery (and isolation) of <sup>248</sup>Cm, the most stable curium isotope, experimental work on the thermodynamic properties of curium sesquioxide (and other curium compounds) has become more prevalent. However, <sup>248</sup>Cm can only be obtained in mg samples, so data collection for <sup>248</sup>Cm-containing compounds takes longer than that for compounds which predominantly contain other curium isotopes.<ref name=":0" /> The data table below reflects a large variety of data collected specifically for curium sesquioxide, some of which is purely theoretical, but most of which have been obtained from <sup>248</sup>Cm-compounds.<ref name=":0" /><ref name=":4" /><ref name=":5" /><ref name=":9">Konings, R.J.M (2001). “Estimation of the Standard Entropies of some Am(III) and Cm(III) Compounds.” ''Journal of Nuclear Materials'' (295): 57-63.</ref><ref name=":10">Smith, Paul Kent (1969). “Melting Point of Curium Trioxide (Cm<sub>2</sub>O<sub>3</sub>).” ''Journal of Inorganic and Nuclear Chemistry'' (31): 241-245.</ref><ref name=":11">Smith, Paul Kent (1970). “High-Temperature Evaporation and Thermodynamic Properties of Cm<sub>2</sub>O<sub>3</sub>.” ''The Journal of Chemical Physics'' (52): 4964-4972.</ref> | ||
{| class="wikitable" | {| class="wikitable" | ||
!Ground State F-Configuration for Metal | !Ground State F-Configuration for Metal | ||
!Approximate Melting Point ( |
!Approximate Melting Point (°C) | ||
!'''Magnetic Susceptibility''' (μb) | !'''Magnetic Susceptibility''' (μb) | ||
!Uncertainty (μb) | !Uncertainty (μb) | ||
Line 141: | Line 141: | ||
|5*** | |5*** | ||
|} | |} | ||
(*: Different syntheses of curium trioxide have been shown to produce compounds with different experimental melting points. The melting point given in this data table is merely an average of those collected from the references<ref name=": |
(*: Different syntheses of curium trioxide have been shown to produce compounds with different experimental melting points. The melting point given in this data table is merely an average of those collected from the references.<ref name=":10" /><ref name=":11" />) | ||
(**: Characteristic of the monoclinic form.) | (**: Characteristic of the monoclinic form.) | ||
(***: Various experiments have calculated different estimates of the standard molar entropy for curium trioxide: Moskin has reported a standard molar entropy of 144.3 J/molK (no given uncertainty). Westrum and Grønvold have reported a value of 160.7 J/molK (no given uncertainty), and Konings’ value is reported to be 167 +/- 5 J/molK<ref name=":9" /> |
(***: Various experiments have calculated different estimates of the standard molar entropy for curium trioxide: Moskin has reported a standard molar entropy of 144.3 J/molK (no given uncertainty). Westrum and Grønvold have reported a value of 160.7 J/molK (no given uncertainty), and Konings’ value is reported to be 167 +/- 5 J/molK.<ref name=":9" />) | ||
== Toxicology == | == Toxicology == | ||
Curium metal is a ''']''' and emits ''']''' upon radioactive decay<ref name=":9" /> |
Curium metal is a ''']''' and emits ''']''' upon radioactive decay.<ref name=":9" /> Although it has a half life of 34 ms, many curium oxides, including curium sesquioxide, have half lives nearing thousands of years.<ref name=":5" /> Curium, in the form of curium sesquioxide, can be inhaled into the body, causing many biological defects. The LD50 of curium is 3 micro-Ci through ingestion and inhalation and 1 micro-Ci through absorption through the skin.<ref>“Radionuclide Data Sheet: Curium.” University of California, San Diego. n.d.1.</ref> In one experiment, rats were introduced to aerosolized particulates of curium(III) oxide. Although the experiment proved that inhaled <sup>244</sup>Cm<sub>2</sub>O<sub>3</sub> is half as carcinogenic as compared to inhaled <sup>239</sup>PuO<sub>2</sub>, the rats still suffered from many biological deformities, such as skin lesions, malignant tumors, and lung neoplasms.<ref name=":3" /> A small amount of the rat population was able to clear particulate curium sesquioxide from the lungs, suggesting that curium sesquioxide is partially soluble in lung fluid.<ref name=":3" /> | ||
== Applications == | == Applications == | ||
Curium(III) oxide is heavily used in industrial grade-reactions and reagents<ref name=":10" /> |
Curium(III) oxide is heavily used in industrial grade-reactions and reagents.<ref name=":10" /> As recently as 2009, actinide oxides, such as curium sesquioxide, are being considered for storage uses (in the form of heavily durable ceramic glassware) for the transportation of the light-and-air sensitive ] and ] target substances.<ref name=":10" /> | ||
== Other Reactions == | == Other Reactions == | ||
Curium sesquioxide will spontaneously react with gaseous oxygen at high temperatures<ref name=":7" /> |
Curium sesquioxide will spontaneously react with gaseous oxygen at high temperatures.<ref name=":7" /> At lower temperatures, a spontaneous reaction will occur over a period of time. Curium trioxide reacted with water has been hypothesized to afford a hydration reaction, but little experimentation has been done to prove the hypothesis.<ref name=":7" /> Curium sesquioxide has been shown to not react with nitrogen gas, spontaneously or non-spontaneously.<ref name=":7" /> | ||
== See also == | == See also == | ||
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* | * | ||
{{Curium compounds}} | {{Curium compounds}} | ||
⚫ | {{Inorganic-compound-curium-trioxide}} | ||
] | ] | ||
] | ] | ||
⚫ | {{Inorganic-compound-curium-trioxide}} |
Revision as of 05:35, 30 April 2016
Names | |
---|---|
IUPAC name Curium(III) oxide | |
Systematic IUPAC name Curium(3+) oxide | |
Other names
Curic oxide Curium sesquioxide | |
Identifiers | |
CAS Number | |
3D model (JSmol) | |
PubChem CID | |
CompTox Dashboard (EPA) | |
InChI
| |
SMILES
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Properties | |
Chemical formula | Cm2O3 |
Molar mass | 542 g·mol |
Structure | |
Crystal structure | Hexagonal, hP5, Body-Centered Cubic, Monoclinic |
Space group | P-3m1, No. 164 |
Related compounds | |
Other cations | Gadolinium(III) oxide, Curium hydroxide, Curium trifluoride, Curium Tetrafluoride, Curium Trichloride, Curium Triiodide |
Except where otherwise noted, data are given for materials in their standard state (at 25 °C , 100 kPa). N verify (what is ?) Infobox references |
Curium(III) oxide is a compound composed of curium and oxygen with the chemical formula Template:CuriumTemplate:Oxygen. It is a crystalline solid with a unit cell that contains two curium atoms and three oxygen atoms. The simplest synthesis equation involves the reaction of curium(III) metal with O: 2 Cm + 3 O ---> Cm2O3. Curium trioxide can exist as five polymorphic forms. Two of the forms exist at extremely high temperatures, making it difficult for experimental studies to be done on the formation of their structures. The three other possible forms which curium sesquioxide can take are the body-centered cubic form, the monoclinic form, and the hexagonal form. Curium(III) oxide is either white or light tan in color and, while insoluble in water, is soluble in inorganic and mineral acids. Its synthesis was first recognized in 1955.
Synthesis
Curium sesquioxide can be prepared in a variety of ways. (Note: Keep in mind that the ways listed below do not contain all of the possible ways in which it can be produced.)
Ignition with O2: Curium(III) oxalate is precipitated through a capillary tube. The precipitate is ignited by gaseous oxygen at 400 °C, and the resulting product is thermally decomposed via 600 °C and 10 mm of pressure.
Aerosolized Curium Sesquioxide: The aerosolization process of Cm2O3 can be done through multiple experimental processes. Typically, Cm2O3 is aerosolized for experimental procedures which set out to discover the effects of curium metal within a biological system.
Route 1: The traditional aerosolization reaction utilizes curium metal as the starting material. While curium metal has been discovered to naturally exist as a mixture of 87.4% Cm, 8.4% Cm, 3.9% other curium isotopes, and ~0.3% of the daughter nuclide, plutonium, in most aerosolized syntheses of curium(III) oxide, curium metal is purified through solvent extraction of curium nitrate and bis(2-ethylhexyl) phosphoric acid in toluene to remove the plutonium. NH3OH is then added to the purified curium nitrate, and the resulting precipitate is collected and rinsed with deionized water. The precipitate (Cm2O3) is resuspended in solvent and aerosolized with some sort of high output aerosol generator (ex: Lovelace nebulizer).
Route 2: In other aerosolizations, instead of the addition of NH3OH to the purified curium nitrate, ammonium hydroxide is utilized to adjust the pH value of the solution to 9. The increased basicity of the solution creates a curium hydroxide precipitate. This precipitate is then collected through filtration and resuspended in deionized water, and a nebulizer is then used to aerosolize the product.
Reduction by Hydrogen Gas: A solution of curium trichloride is evaporated to dryness with pure nitric acid to produce curium nitrate. The curium nitrate is then ignited in air, producing curium oxide, believed to be an intermediate structure between CmO2 and the formation of Cm2O3. The intermediate is scraped into capillary tubes attached to a vacuum system and reduced with gaseous hydrogen - the result of the combustion of UH3.
Obtaining Curium-244: For many of the reactions described above, curium metal is provided by an outside retailer. In order to obtain curium metal, Pu metal can be sent through the pile irradiation process described by the radioactive decay processes below (note that neutrons are indicated by the letter "n" and beta-minus particles by "β−"):
Pu + n ---> Pu + n ---> Pu + n ---> Pu + n ---> Pu+ β− ---> Am + n ---> Am + β− ---> Cu.
However, curium is one of the more unstable curium isotopes, so any structural data obtained for compounds containing Cm may deviate from the expected as a result of structural damage. It has been experimentally determined that, within one day, CmO2's lattice parameter increases by a factor of 0.2%. This has been hypothesized to be a result of the weakening interatomic interactions between curium(IV) and the neighboring oxide groups as a result of alpha-decay. This affects the thermal conductivity of curium oxides, causing it to exponentially decrease over time as the effects of alpha-decay strengthen. Abnormal phase transitions have also been reported and have been theorized to be a result of induced self-irradiation, either by Cm or the presence of leftover Am from incomplete radioactive decay.
Structure
The body-centered cubic and monoclinic forms are the most common polymorphic forms of curium trioxide, produced by the chemical reactions detailed above. Their crystalline structures are very similar. One of the polymorphs of curium trioxide - the body-centered cubic form - spontaneously transforms to the hexagonal form after several weeks. This transformation is undergone upon spontaneous Cm alpha decay, which produces radiation damage effects within the cubic crystal lattice to distort it to that of hexagonal. Although not experimentally proven, there is speculation that monoclinic curium trioxide may be an intermediate form in between the transformation of the cubic form to that of the hexagonal. The body-centered cubic form of curium trioxide exists below temperatures of 800 °C, the monoclinic form between 800 °C and 1615 °C, and the hexagonal form above 1615 °C.
Crystallography
The lattice parameters for three of the polymorphic structures of curium sesquioxide are given below.
Hexagonal:
Data Table | Temperature (°C) | Lengths of a (Å) | Uncertainty (Å) | Lengths of c (Å) | Uncertainty (Å) |
---|---|---|---|---|---|
1615 | 3.845 | 0.005 | 6.092 | 0.005 | |
--* | 3.496 | 0.003 | 11.331 | 0.005 |
(*: No specific temperature has been stated to produce the lengths listed in the second row.)
Monoclinic:
Data Table | Temperature (°C) | Lengths of a (Å) | Lengths of b (Å) | Lengths of c (Å) |
---|---|---|---|---|
21 | 14.257** | 8.92** | 3.65** |
(**: None of these lengths contained given uncertainties.)
Cubic:
Data Table | Temperature (°C) | Lengths of a (Å) | Uncertainty (Å) |
---|---|---|---|
21 | 10.97 | 0.01 |
Data
Ever since the discovery (and isolation) of Cm, the most stable curium isotope, experimental work on the thermodynamic properties of curium sesquioxide (and other curium compounds) has become more prevalent. However, Cm can only be obtained in mg samples, so data collection for Cm-containing compounds takes longer than that for compounds which predominantly contain other curium isotopes. The data table below reflects a large variety of data collected specifically for curium sesquioxide, some of which is purely theoretical, but most of which have been obtained from Cm-compounds.
Ground State F-Configuration for Metal | Approximate Melting Point (°C) | Magnetic Susceptibility (μb) | Uncertainty (μb) | Enthalpy of Formation (kJ/mol) | Uncertainty (kJ/mol) | Average Standard Molar Entropy (J/molK) | Uncertainty (J/molK) |
---|---|---|---|---|---|---|---|
f (Cm) | 2265* | 7.89** | 0.04** | -400** | 5** | 157*** | 5*** |
(*: Different syntheses of curium trioxide have been shown to produce compounds with different experimental melting points. The melting point given in this data table is merely an average of those collected from the references.)
(**: Characteristic of the monoclinic form.)
(***: Various experiments have calculated different estimates of the standard molar entropy for curium trioxide: Moskin has reported a standard molar entropy of 144.3 J/molK (no given uncertainty). Westrum and Grønvold have reported a value of 160.7 J/molK (no given uncertainty), and Konings’ value is reported to be 167 +/- 5 J/molK.)
Toxicology
Curium metal is a radionuclide and emits alpa particles upon radioactive decay. Although it has a half life of 34 ms, many curium oxides, including curium sesquioxide, have half lives nearing thousands of years. Curium, in the form of curium sesquioxide, can be inhaled into the body, causing many biological defects. The LD50 of curium is 3 micro-Ci through ingestion and inhalation and 1 micro-Ci through absorption through the skin. In one experiment, rats were introduced to aerosolized particulates of curium(III) oxide. Although the experiment proved that inhaled Cm2O3 is half as carcinogenic as compared to inhaled PuO2, the rats still suffered from many biological deformities, such as skin lesions, malignant tumors, and lung neoplasms. A small amount of the rat population was able to clear particulate curium sesquioxide from the lungs, suggesting that curium sesquioxide is partially soluble in lung fluid.
Applications
Curium(III) oxide is heavily used in industrial grade-reactions and reagents. As recently as 2009, actinide oxides, such as curium sesquioxide, are being considered for storage uses (in the form of heavily durable ceramic glassware) for the transportation of the light-and-air sensitive fission and transmutation target substances.
Other Reactions
Curium sesquioxide will spontaneously react with gaseous oxygen at high temperatures. At lower temperatures, a spontaneous reaction will occur over a period of time. Curium trioxide reacted with water has been hypothesized to afford a hydration reaction, but little experimentation has been done to prove the hypothesis. Curium sesquioxide has been shown to not react with nitrogen gas, spontaneously or non-spontaneously.
See also
References
- 8. N.A. (2010). “Study of oxychloride compound formation in chloride melt by spectroscopic methods.” Radiochemical Division/Research Institute of Atomic Reactors. pp. 1-17.
- Cunningham, B.B. (1964). “Chemistry of the Actinide Elements.” Annual Review of Nuclear Science (n.a): 323-347.
- ^ Milman, V., Winkler, B., and C.J. Pickard (2003). “Crystal Structures of Curium Compounds: An Ab Initio Study.” Journal of Nuclear Materials (322): 165-179.
- ^ Petit, L., Svane, A., Szotek, Z., Temmerman, W.M., and G. M. Stocks (2009). “Electronic structure and ionicity of actinide oxides from first principles calculations.” Materials Science and Technology Division, Oak Ridge National Laboratory. pp. 1-12.
- Norman M. Edelstein, James D. Navratil, Wallace W. Schulz (1984). Americium and curium chemistry and technology. D. Reidel Pub. Co. pp. 167–168.
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: CS1 maint: multiple names: authors list (link) - ^ Helfinstine, Suzanne Y., Guilmette, Raymond A., and Gerald A. Schlapper (1992). “In Vitro Dissolution of Curium Oxide Using a Phagolysosomal Simulant Solvent System.” Environmental Health Perspectives (97): 131-137.
- ^ Morss, L. R., Fuger, J., Goffart, J. and R.G. Haire (1983). “Enthalpy of Formation and Magnetic Susceptibility of Curium Sesquioxide, Cm203.” Inorganic Chemistry (22):1993-1996.
- ^ Wallmann, J.C. (1964). “A Structural Transformation of Curium Sesquioxide.” Journal of Inorganic and Nuclear Chemistry (26): 2053-2057.
- ^ Lundgren, D. L. , Hahn, F. F., Carlton, W. W., Griffith, W. C., Guilmette, R. A., and N. A. Gillett (1997). “Dose Responses from Inhaled Monodisperse Aerosols of Cm203 in the Lung, Liver and Skeleton of F344 Rats and Comparison with Pu02.” Radiation Research (5): 598-612.
- Stevens, C. M., Studier, M. H., Fields, P. R. , Meck, J. F., Sellers, P. A., Friedman, A. M., Diamond H., and J. R. Huizenga (1954). “Evidence for Quadrivalent Curium: X-Ray Data on Curium Oxides.” Communications to the Editor (7): 1707-1708.
- ^ S.E. Lemehov *, V. Sobolev, and P. Van Uffelen (2003). "Modelling thermal conductivity and self-irradiation effects in mixed oxide fuels." Journal of Nuclear Materials (320): 66–76.
- ^ Lumetta, Gregg J., Thompson, Major C., Penneman, Robert A., and P. Gary Eller (2006). The Chemistry of the Actinide and Transactinide Elements. “Curium: Chapter Nine.” Springer Pub. Co. Vol.3. pp. 1397-1443.
- ^ Rimshaw, S. J., and E. E. Ketchen (1967). “Curium Data Sheets.” Oak Ridge National Laboratory - Union Carbide Corporation. pp. 42-102.
- ^ Konings, R.J.M (2001). “Estimation of the Standard Entropies of some Am(III) and Cm(III) Compounds.” Journal of Nuclear Materials (295): 57-63.
- ^ Smith, Paul Kent (1969). “Melting Point of Curium Trioxide (Cm2O3).” Journal of Inorganic and Nuclear Chemistry (31): 241-245.
- ^ Smith, Paul Kent (1970). “High-Temperature Evaporation and Thermodynamic Properties of Cm2O3.” The Journal of Chemical Physics (52): 4964-4972.
- “Radionuclide Data Sheet: Curium.” University of California, San Diego. n.d.1.
External links
Curium compounds | |
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Curium(III) | |
Curium(IV) | |
Curium(VI) |
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