Electron Diffraction Tomography on Two-Phase Nanolamellae of Topochemically Synthesized Cu(Sb(2)S(3))Cl.

The dark red semiconductor Cu(Sb(2)S(3))Cl was obtained by leaching the layered precursor Cu(Sb(2)S(3))[AlCl(4)] in a 0.1 M aqueous HCl solution. The selective extraction of AlCl(3) yielded a mica-like lamellar product of poor crystallinity. Misalignment of lamellae down to the nanoscale prevented structure determination by conventional single-crystal X-ray diffraction, but a combination of transmission electron microscopy, selected area electron diffraction, and selected area electron precession diffraction tomography on a nanoscale spot with largely ordered crystalline lamellae revealed the crystal structures of two intergrown modifications. Orthorhombic o-Cu(Sb(2)S(3))Cl and monoclinic m-Cu(Sb(2)S(3))Cl have similar layers to the precursor and differ only in the stacking of the layers. These consist of uncharged Sb(2)S(3) strands, whose sulfide ions, together with chloride ions, coordinate the copper(I) cations. Only one chloride ion remained from the [AlCl(4)](-) group. DFT calculations confirm the structure solution for the orthorhombic form and suggest that the monoclinic structure is metastable against transformation to o-Cu(Sb(2)S(3))Cl.