Cobalt bis(dicarbollide) ions functionalized by CMPO-like groups attached to boron by short bonds; efficient extraction agents for separation of trivalent f-block elements from highly acidic nuclear waste

Abstract

New boron substituted cobalta bis(dicarbollide)(1-) ion ( 1) derivatives of formula [(8,8′-(RPhP(O)(CH 2) nC(O)N) < (1,2-C 2B 9H 10) 2-3,3′-Co] − (R = Ph or C 8H 17, n = 1, 3a, 3b; R = Ph, n = 2, 3c), [(8-(Ph 2P(O)CH 2C(O)NR)(1,2-C 2B 9H 10))(1′,2′-C 2B 9H 11)-3,3′-Co] − (R = H, C 2H 5, CH 2C 6H 5, 5a–c) and [(8-( 2RPhP(O)CH 2C(O)N( 1R)CH 2-1,2-C 2B 9H 10))(8′-CH 3O-1′,2′-C 2B 9H 10)-3,3′-Co] − ( 1R = Benzyl, 2R = Ph or C 8H 17, 7a,b) were prepared with the aim to develop a new class of efficient extraction agents for partitioning of polyvalent f-block elements, i.e. lanthanides and actinides from high-level activity nuclear waste. The anionic ligands were characterized by multinuclear NMR spectroscopy and MS, the structures of Cs 3a and the calcium complex of 7a were determined by X-ray diffraction analysis. The crystallographic study of the Cs 3a proved a formation of linear chains in the structure, where the metal cation is coordinated by oxygen atoms of the CMPO terminal groups. The X-ray structure of the Ca 2+ complex of the ionic ligand 7a proved a 1:3 metal to ligand ratio. Presented also is the X-ray structure of the starting ammonium compound 6 used in the synthesis of 7a and 7b. With exception of 5c, these anionic ligands are of high extraction efficiency, the highest being found for 7a in low polar solvent mixture hexyl methyl ketone–dodecane 1:1. These properties qualify some of these derivatives for possible technological applications.