Tin oxide (SnO2) nanowires of different diameters can be conveniently grown by combining the chemical influence of a single‐molecular precursor [Sn(OtBu)4] with vapor–liquid–solid growth. Upon illumination with UV light at a wavelength of 370 nm, the nanowires exhibit interesting photoconductance, which can be modulated by tuning the wire diameter, as demonstrated for samples possessing radial dimensions in the range 50–1000 nm (see image).
High-yield synthesis of germanium nanowires (NWs) and core−shell structures is achieved
by the chemical vapor deposition (CVD) of dicyclopentadienyl germanium ([Ge(C5H5)2]). The
one-dimensional (1D) nanostructures are formed on an iron substrate following a base-growth
model in which an Fe−Ge epilayer functions as a catalytic bed. The wire growth is selective
and no catalyst particles are observed at the tip of the NWs, which is contrary to the
characteristic feature of a 1D growth based on the vapor−liquid−solid (VLS) mechanism.
The diameter and length of the NWs were in the ranges 15−20 nm and 25−40 μm,
respectively, as found by high-resolution electron microscopy. Both axial and radial
dimensions of the NWs can be controlled by adjusting the precursor feedstock, deposition
temperature, and size of alloy nuclei in the Fe−Ge epilayer. High precursor flux produced
coaxial heterostructures where single-crystalline Ge cores are covered with an overlayer of
nanocrystalline Ge. Single-crystal Ge nanowires exhibit a preferred growth direction [112̄]
confirmed by X-ray and electron diffraction patterns. When compared to bulk Ge, the micro-Raman spectra of Ge NWs show a low field shift, probably due to the dimensional
confinement. Patterned growth of Ge NWs was achieved by shadow-masking the Fe substrate
with a carbon film, which prevents the formation of Fe−Ge nuclei, thereby inhibiting the
nanowire growth.
Imaging single epidermal growth factor receptors (EGFR) in intact cells is presently limited by the available microscopy methods. Environmental scanning electron microscopy (ESEM) of whole cells in hydrated state in combination with specific labeling with gold nanoparticles was used to localize activated EGFRs in the plasma membranes of COS7 and A549 cells. The use of a scanning transmission electron microscopy (STEM) detector yielded a spatial resolution of 3 nm, sufficient to identify the locations of individual EGFR dimer subunits. The sizes and distribution of dimers and higher order clusters of EGFRs were determined. The distance between labels bound to dimers amounted to 19 nm, consistent with a molecular model. A fraction of the EGFRs was found in higher order clusters with sizes ranging from 32–56 nm. ESEM can be used for quantitative whole cell screening studies of membrane receptors, and for the study of nanoparticle-cell interactions in general.
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