Intercalation route to nano-hybrids: inorganic/organic-high T-c cuprate hybrid materials

A systematic application of intercalation techniques to layered superconduc ting oxides enables us to open a new chapter in the development of nano-hyb rids with various functions. Recently we were successful in preparing a new series of inorganic-inorganic nano-hybrids, M-X-Bi2Sr2Cam-1CumOy (M = Hg, Ag, Au; X = Br, I; m = 1-3) and organic-inorganic ones, R2HgI4-Bi2Sr2Cam-1C umOy (R = organic cation). Our synthetic strategies are based on (1) HSAB ( hard-soft acid-base) interactions and (2) interlayer complexation concepts. Since the iodine species in IBi2Sr2Cam-1CumOy are stabilized as I-3(-) (so ft base) with a charge transfer between;host and guest, soft Lewis acids li ke Ag+, Au+, and Hg2+ can be further intercalated into the iodine layers in between the (Bi-O) double layers. On the other hand, new organic-inorganic nano-hybrids (R2HgI4-Bi2Sr2Cam-1CumOy) have also been achieved through the intercalative complex-salt formation reaction between preintercalated HgI2 molecules and R+I- salts in the interlayer space of Bi2Sr2Cam-1CumOy. Comp ared to the pure compounds the superconducting transition temperatures of t he organic-salt intercalates are little changed even with a large basal inc rement upon intercalation, indicating a two-dimensional nature of the high- ir, superconductivity. From the viewpoint of application, the intercalation of large organic molecules provides a new synthetic route to high-T-c supe rconducting thin-film and nano-particles by separating superconducting bloc ks into isolated single sheets.