NEW QUATERNARY COMPOUNDS RESULTING FROM THE REACTION OF COPPER AND F-BLOCK METALS IN MOLTEN POLYCHALCOGENIDE SALTS AT INTERMEDIATE TEMPERATURES - VALENCE FLUCTUATIONS IN THE LAYERED CSCUCES3

From the reaction of elemental copper and either lanthanides or actini des in molten alkali metal/polychalcogenide salts, several new quatern ary phases have been discovered. Specifically, these phases are ACuM(2 )Q(6) (where A = K, M = La, Q = S; A = Cs, M = Ce, Q = S; or A = K, M = Ce, Q = Se) and ACuMQ(3) (where A = Cs, M = Ce, Q = S; or A = K, M = U, Q = Se). The CsCuCe2S6 crystallizes in the orthorhombic space grou p Immm with a = 5.500(1) Angstrom, b = 22.45(1) Angstrom, c = 4.205(4) Angstrom. The KCuCe2Se6 is isostructural. The CsCuCeS3 crystallizes i n the orthorhombic space group Cmcm with a = 4.024(2) Angstrom, b = 15 .154(2) Angstrom, c = 10.353(3) Angstrom. The KCuUSe3 is isostructural . In ACuM(2)Q(6), the lanthanides bond to a mixture of mono- and disul fides in a bicapped trigonal prismatic geometry; these polyhedra subse quently connect in two dimensions, forming layers equivalent to those seen in the ZrSe3 structure type with Cu+ atoms residing in tetrahedra l sites within the layers and alkali cations in the interlayer gallery . The compounds of the formula ACuMQ(3) also possess a layered structu re. Here the [MQ(6)] octahedral units form corrugated, two-dimensional sheets via edge-sharing in the first dimension and corner-sharing in the second. Copper cations are coordinated to tetrahedral sites in the folds of the corrugations, and alkali cations are again in the interg allery region. Details of the synthesis, structure, and properties of these compounds are discussed.