We report on the structural analysis of graphene oxide (GO) by transmission electron microscopy (TEM). Electron diffraction shows that on average the underlying carbon lattice maintains the order and lattice-spacings of graphene; a structure that is clearly resolved in 80 kV aberration-corrected atomic resolution TEM images. These results also reveal that single GO sheets are highly electron transparent and stable in the electron beam, and hence ideal support films for the study of nanoparticles and macromolecules by TEM. We demonstrate this through the structural analysis of physiological ferritin, an iron-storage protein.
The capability of sodium hydride as a reducing agent in oxide deintercalation reactions is explored.
The Ni(III) perovskite LaNiO3 can be reduced topotactically to LaNiO2, isostructural with the “infinite layer”
cuprates, using solid sodium hydride in a sealed evacuated tube at 190 ≤ T/°C ≤ 210, and a similar infinite-layer phase is prepared by reduction of NdNiO3. Structural characterization indicates the coexistence of
incompletely reduced regions, with five-coordinate Ni centers due to the introduction of oxide anions between
the NiO2
3- sheets, giving samples with a refined stoichiometry of LaNiO2.025(3). Neutron powder diffraction
and magnetization measurements indicate that the lamellar Ni(I) phase does not show the long-range
antiferromagnetic ordering characteristic of isoelectronic Cu(II) oxides. This may be due either to the influence
of the interlamellar oxide defect regions or to the reduced covalent mixing of Ni 3d and O 2p levels.
As a first step to validate the use of carbon nanotubes as novel vaccine or drug delivery devices, their interaction with a part of the human immune system, complement, has been explored. Haemolytic assays were conducted to investigate the activation of the human serum complement system via the classical and alternative pathways. Western blot and sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) techniques were used to elucidate the mechanism of activation of complement via the classical pathway, and to analyse the interaction of complement and other plasma proteins with carbon nanotubes. We report for the first time that carbon nanotubes activate human complement via both classical and alternative pathways. We conclude that complement activation by nanotubes is consistent with reported adjuvant effects, and might also in various circumstances promote damaging effects of excessive complement activation, such as inflammation and granuloma formation. C1q binds directly to carbon nanotubes. Protein binding to carbon nanotubes is highly selective, since out of the many different proteins in plasma, very few bind to the carbon nanotubes. Fibrinogen and apolipoproteins (AI, AIV and CIII) were the proteins that bound to carbon nanotubes in greatest quantity.
The complete crystallography of a one-dimensional crystal of potassium iodide encapsulated within a 1.6-nanometer-diameter single-walled carbon nanotube has been determined with high-resolution transmission electron microscopy. Individual atoms of potassium and iodine within the crystal were identified from a phase image that was reconstructed with a modified focal series restoration approach. The lattice spacings within the crystal are substantially different from those in bulk potassium iodide. This is attributed to the reduced coordination of the surface atoms of the crystal and the close proximity of the van der Waals surface of the confining nanotube.
Recently, a method to produce bulk quantities of pure multiwall WS2 nanotubes, which could reach
several microns in length, has been developed. A detailed study of the growth mechanism of these WS2 nanotubes
has been undertaken, which is reported hereby. A series of experiments were conducted to define the key
parameters, which determine the shape of the WS2 nanotubes. An alternative approach for the synthesis of
WS2 nanotubes, starting from long WO3
-
x
nanowhiskers, which can be extended for the synthesis of other
nanotubes, is described as well.
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