Lecture 10: Curium Chemistry

1. Lecture 10: Curium Chemistry • From: Chemistry of actinides • Nuclear properties • Production of Cm isotopes • Atomic data • Cm separation and purification • Metallic state • Classes of compounds • Solution chemistry • Analytical Chemistry

2. Cm nuclear properties • Isotopes from mass 237 to 251 • Three isotopes available in quantity for chemical studies • 242Cm, t1/2=163 d • 122 W/g • Grams of the oxide glows • Low flux of 241Am target decrease fission of 242Am, increase yield of 242Cm • 244Cm, t1/2=18.1 a • 2.8 W/g • 248Cm, t1/2= 3.48E5 a • 8.39% SF yield • Limited quantities to 10-20 mg • Target for production of transactinide elements

3. Cm Production • From successive neutron capture of higher Pu isotopes • 242Pu+n243Pu (b-, 4.95 h)243Am+n244Am (b-, 10.1 h)244Cm • Favors production of 244,246,248Cm • Isotopes above 244Cm to 247Cmare not isotopically pure • Pure 248Cm available from alpha decay of 252Cf • Large campaign to product Cm from kilos of Pu • 244Cm separation • Dissolve target in HNO3 and remove Pu by solvent extraction • Am/Cm chlorides extracted with tertiary amines from 11 M LiCl in weak acid • Back extracted into 7 M HCl • Am oxidation and precipitation of Am(V) carbonate • Other methods for Cm purification included NaOH, HDEHP, and EDTA • Discussed for Am

4. Atomic and spectroscopic data • Ground state electron configuration • [Rn]5f76d17s2, Term symbol: 9D2 • Ionization limit (48 560 cm-1) • Cm3+ [Rn]5f7, 8D7/2 • X-ray data • Electron binding energies • K=128.24 KeV, LI=24.52 KeV, LII=23.65 KeV, LIII=18.9 KeV

5. Cm atomic and spectroscopic data • 5f7 has enhanced stability • Half filled orbital • Large oxidation potential for IIIIV • Cm(IV) is metastable • Cm(III) absorbance • Weak absorption in near-violet region • Solution absorbance shifted 20-30 Å compared to solid • Reduction of intensity in solid due to high symmetry • f-f transitions are symmetry forbidden • Spin-orbit coupling acts to reduce transition energies when compared to lanthanides • Cm(IV) absorbance • Prepared from dissolution of CmF4 • CmF3 under strong fluorination conditions

7. Cm fluorescence • Fluoresce from 595-613 nm • Attributed to 6D7/28S7/2 transition • Energy dependent upon coordination environment • Speciation • Hydration • complexationconstants

8. Absorption and fluorescence process of Cm3+ Optical Spectra Fluorescence Process H G F Emissionless Relaxation A 7/2 Excitation Fluorescence Emission Z 7/2

9. Cm separation and purification • Solvent extraction • Fundamentally the same as Am • Organic phosphates • Function of ligand structure • Mixed with 6 to 8 carbon chain better than TBP • HDEHP • From HNO3 and LiCl • Use of membrane can result in Am/Cm separation • CMPO • Oxidation state based removal with different stripping agent • Extraction of Cm from carbonate and hydroxide solutions, need to keep metal ions in solution • Organics with quaternary ammonium bases, primary amines, alkylpyrocatechols, b-diketones, phenols

10. Cm separations • Ion exchange (similar to Am conditions) • Anion exchange with HCl, LiCl, and HNO3 • Includes aqueous/alcohol mixtures • Formation of CmCl4- at 14 M LiCl • From fluorescence spectroscopy • TEVA resins • Same range of organic phases • Precipitation • Separation from higher valentAm (as discussed in Am chapter) • 10 g/L solution in base • Precipitation of K5AmO2(CO3)3 at 85 °C • Precipitation of Cm with hydroxide, oxalate, or fluoride

11. Cm metallic state • Melting point 1345 °C • Higher than lighter actinides Np-Am • Similar to Gd (1312 °C) • Two states • Double hexagonal close-packed (dhcp) • Neutron diffraction down to 5 K • No structure change • fcc at higher temperature • XRD studies on 248Cm • Magnetic susceptibility studies • Antiferrimagnetic transition near 65 K • 200 K for fcc phase • Metal susceptible to corrosion due to self heating • Formation of oxide on surface

12. Cm metallic state • Preparation of Cm metal • CmF3 reduction with Ba or Li • Dry, O2 free, and above 1600 K • Reduction of CmO2 with Mg-Zn alloy in MgF2/MgCl2 • Alloys • Cm-Pu phase diagram studied • Noble metal compounds • CmO2 and H2 heated to 1500 K in Pt, Ir, or Rh • Pt5Cm, Pt2Cm, Ir2Cm, Pd3Cm, Rh3Cm

13. Cm compounds • Hydrides • Reaction of metal with H2 at 250 °C • fcc from XRD, CmH2+x • Dihydride also forms • Halides • Complete CmX3 and CmF4 • CmF3 precipitates with excess F- • Anhydrous forms when compound placed over P2O5 • CmCl3 from treating Cm oxides with anhydrous HCl between 400-600 °C • Hexagonal UCl3 type structure • 9 Cl- coordination tricappedtrigonal prism • CmBr3 from treating CmCl3 with NH4Br between 400-450 °C • Orthorhombic structure (PuBr3) • Coordinated by 8 Br- • CmI3 from CmBr3 with NH4I • Also from reactions with elements • CmF4 • Fluoride oxidation of CmF3 • Monoclinic ZrF4 structure • Antiprismatic 8-coordination • Some evidence of CmF6 and trivalent oxyfluorides

14. Cm oxides • Cm2O3 • Thermal decomposition of CmO2 at 600 °C and 10-4torr • Mn2O3 type cubic lattice • Transforms to hexagonal structure due to radiation damage • Monoclinic at 800 °C • CmO2 • Heating in air, thermal treatment of Cm loaded resin, heating Cm2O3 at 600 °C under O2, heating of Cm oxalate • Shown to form in O2 as low as 400 °C • Evidence of CmO1.95 at lower temperature • fcc structure • Magnetic data indicates paramagnetic moment attributed to Cm(III) • Need to re-evaluate electronic ground state in oxides

15. Cm compounds • Oxides • Similar to oxides of Pu, Pr, and Tb • Basis of phase diagram • BaCmO3 and Cm2CuO4 • Based on high T superconductors • Cm compounds do not conduct • S, Se, Te compounds • CmS2 and CmSe2 from Cm hydride and elements heated under vacuum • Tetragonal structure • Thermal treatment of CmS2 yields Cm2S3 (bcc) • 1,1 species from heating elements 700-750 °C • bcc structure • CmTe3 from heating at 400 °C

16. Cm compounds • N, P, As, and Sb • 1,1 species • Cm metal or hydride with elements • Sealed tubes from 350-900 °C • All have NaCl structure • CmN and CmAs are ferromagnetic • Lower effective magnetic moments than expected for 5f7 configuration • Strong spin-orbit coupling and crystal field effects • Formation of Pu,CmN species • Lattice similar to known species parameters

17. Cm compounds • Cm(OH)3 • From aqueous solution, crystallized by aging in water • Same structure as La(OH)3; hexagonal • Cm2(C2O4)3.10H2O • From aqueous solution • Stepwise dehydration when heated under He • Anhydrous at 280 °C • Converts to carbonate above 360 °C • TGA analysis showed release of water (starting at 145 °C) • Converts to Cm2O3 above 500 °C’ • Cm(NO3)3 • Evaporation of Cm in nitric acid • From TGA, decomposition same under O2 and He • Dehydration up 180 °C, melting at 400 °C • Final product CmO2 • Oxidation of Cm during decomposition

18. Cm compounds • Phosphates • CmPO4.0.5 H2O from aqueous solutions with Na2HPO4 or (NH4)2HPO4 • Unknown structure • Dehydrates at 300 °C • Monazite structure • Cm[Fe(CN)6] forms solids (dark red) • K3[Fe(CN)6] with Cm in 0.2 M HNO3 • Eu, Ce, and Pr do not form solids under the same conditions • Hexafluoroacetylacetone (HFAA) • Cs ion complex forms with Cm • 1,1,4 species

19. Cm compounds • Organometallics • Studies hampered by radiolytic properties of Cm • Some compounds similar to Am • Cm(C5H5)3 form CmCl3 and Be(C5H5)2 • Weak covalency of compound • Strong fluorescence

20. Cm aqueous chemistry • Inorganic complexes similar to data for Am • Many constants determined by TRLFS • Hydrolysis constants (Cm3++H2OCmOH2++H+) • K11=1.2E-6 • Evaluated under different ionic strength • Trivalent Cm • 242Cm at 1g/L will boil • 9 coordinating H2O from fluorescence • Decreases above 5 M HCl • 7 waters at 11 M HCl • In HNO3 steady decrease from 0 to 13 M • 5 waters at 13 M • Stronger complexation with NO3-

21. Cm solution chemistry • Polytungstate shown to quench Cm fluorescence • Cm(IV) species exhibit chemiluminescence upon reduction • Stronger complexes with bidentate carboxylic acids • Some data trends may result from experimental measurement differences • Organic complexation with same ligands as Am • CMPO, HDEHP, 8-hydroxyquinoline

22. Cm Analytical chemistry • Typical alpha spectroscopy • Odd A isotopes have lower energy • May require separation prior to alpha spectroscopy • Utilization of TEVA resins or anion exchange • Fission • Even isotopes • Requires pure isotopic sample • TRLFS • No chemical separation needed

23. Review • Nuclear properties • Long lived isotopes, fissile, SF decay route • Production of Cm isotopes • Capture and separation method • Classes of compounds • Oxidation state of Cm in compounds • Solution chemistry • Spectroscopic methods for speciation • Formation of tetravalent state • Analytical Chemistry • Methods of Cm detection

24. Questions • Which Cm isotopes are available for chemical studies? • Describe the fluorescence process for Cm • What is a good excitation wavelength? • What methods can be use to separate Cm from Am? • How many states does Cm metal have? What is its melting point? • What are the binary oxides of Cm? Which will form upon heating in normal atmosphere?

25. Pop Quiz • Why does Cm have fewer accessible oxidation states than Am?