Self-assembled lamellar silica-surfactant mesophase composites have been prepared with crystal-like ordering in the silica frameworks using a variety of cationic surfactant species under hydrothermal conditions. These materials represent the first mesoscopically ordered composites that have been directly synthesized with structure-directing surfactants yielding highly ordered inorganic frameworks. One-dimensional solid-state 29Si NMR spectra, X-ray diffraction patterns, and infrared spectra show the progression of molecular organization in the self-assembled mesophases from structures with initially amorphous silica networks into sheets with very high degrees of molecular order. The silicate sheets appear to be two-dimensional crystals, whose structures and rates of formation depend strongly on the charge density of the cationic surfactant headgroups. Two-dimensional solid-state heteronuclear and homonuclear NMR measurements show the molecular proximities of the silica framework sites to the structure-directing surfactant molecules and establish local Si-O-Si bonding connectivities in these materials.
Over 70 years of chemical investigations have shown that plutonium exhibits some of the most complicated chemistry in the periodic table. Six Pu oxidation states have been unambiguously confirmed (0 and +3 to +7), and four different oxidation states can exist simultaneously in solution. We report a new formal oxidation state for plutonium, namely Pu in [K(2.2.2-cryptand)][PuCp″], Cp″ = CH(SiMe). The synthetic precursor PuCp″ is also reported, comprising the first structural characterization of a Pu-C bond. Absorption spectroscopy and DFT calculations indicate that the Pu ion has predominantly a 5f electron configuration with some 6d mixing.
Two-dimensional (2D) solid-state NMR spectroscopy has been used to identify interfacial species
and establish framework locations of aluminum atoms incorporated in aluminosilicate MCM-41 mesophases
and mesoporous solids. In these experiments, chemical shifts of protons in the material are correlated with
the chemical shifts of nearby (ca. 1 nm) 13C, 27Al, or 29Si species via their respective heteronuclear dipole−dipole couplings. For aluminosilicate MCM-41 mesophases prepared at room temperature, 2D heteronuclear
chemical shift correlation NMR spectra show that tetrahedrally coordinated aluminum and silicon species are
in close spatial proximity to the trimethylammonium head groups of the cationic surfactant species in the
as-synthesized materials and to ammonium cations following calcination and ion exchange. For MCM-41
materials synthesized under hydrothermal conditions, 2D heteronuclear correlation NMR measurements show
that the appearance of six-coordinate aluminum species results from strongly bound water molecules coordinated
to aluminum atoms that are also proximate to the surfactant species. The detection of couplings between 27Al
or 29Si species and protons associated with the structure-directing surfactant molecules or exchangeable
ammonium counterions establishes that a significant fraction of the aluminum atoms are present in the inorganic
frameworks of these materials.
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