One dimensional iron molybdophosphate anionic chains with different structural arrangements reflecting a flexibility character

Abstract

Structural comparison of a new compound [(bpp)3H6]Fe2 IIIFe2 IIMo24 V(H2PO4)8(HPO4)4(PO4)4O48(OH)12· (H2O)4·2H2O(1)[bpp=1,3-di(4-pyridyl)propane] with our previously reported two compounds [(bpy)3FeII]3sdFe2 IIIFe2 IIMo24 V(H2PO4)8(HPO4)4(PO4)4O48(OH)12(H2O)4·12H2O(2) and [(bpy)3FeII]2FeIIFeIIIMo12 V(H2PO4)2(H2−x PO4)·(H1+x PO4)(HPO4)2(PO4)2O24(OH)6(H2O)2·9H2O(x=0-21)(3)(bpy=2,2′-bipyridine), which all exhibit one-dimensional mixed-valence iron molybdophosphate anionic chains constructed by alternating connection of FeIII ions and magic [FeII(Mo6P4O31)2] units, reveals that the non-hydrogen atomic ratios of Mo:Fe:P:O within the polymeric anionic chains are the same for all the three compounds, while the polymeric anionic chains of the different compounds bear different numbers of negative charges. And therefore there exist different numbers of counter cations per {Fe2 III[Fe2 II(P16Mo24 VO124)]} unit found in the titled compounds. It discloses that not only are the spatial assembling of counter cations and polymeric inorganic chains of three compounds quite different, but also the O—FeIII—O bond angles and FeIII—O bond lengths of the three different inorganic chains exhibit small differences. What is more important is that such small changes in bond length and bond angle in the assemblage of FeIII—O bonds lead to the considerable fluctuations of inorganic chains in their structural conformation within the three compounds, reflecting an interesting phenomenon of “flexibility” in the pure inorganic one dimensional mixed-valence iron molybdophosphate chains.