The sensing ability of individual SnO(2) nanowires and nanobelts configured as gas sensors was measured before and after functionalization with Pd catalyst particles. In situ deposition of Pd in the same reaction chamber in which the sensing measurements were carried out ensured that the observed modification in behavior was due to the Pd functionalization rather than the variation in properties from one nanowire to another. Changes in the conductance in the early stages of metal deposition (i.e., before metal percolation) indicated that the Pd nanoparticles on the nanowire surface created Schottky barrier-type junctions resulting in the formation of electron depletion regions within the nanowire, constricting the effective conduction channel and reducing the conductance. Pd-functionalized nanostructures exhibited a dramatic improvement in sensitivity toward oxygen and hydrogen due to the enhanced catalytic dissociation of the molecular adsorbate on the Pd nanoparticle surfaces and the subsequent diffusion of the resultant atomic species to the oxide surface.
Atomic substitution in alloys can efficiently scatter phonons, thereby reducing the thermal conductivity in crystalline solids to the "alloy limit." Using In0.53Ga0.47As containing ErAs nanoparticles, we demonstrate thermal conductivity reduction by almost a factor of 2 below the alloy limit and a corresponding increase in the thermoelectric figure of merit by a factor of 2. A theoretical model suggests that while point defects in alloys efficiently scatter short-wavelength phonons, the ErAs nanoparticles provide an additional scattering mechanism for the mid-to-long-wavelength phonons.
Heterostructures and superlattices consisting of a prototype Mott insulator,
GdTiO3, and the band insulator SrTiO3 are grown by molecular beam epitaxy and
show intrinsic electronic reconstruction, approximately 1/2 electron per
surface unit cell at each GdTiO3/SrTiO3 interface. The sheet carrier densities
in all structures containing more than one unit cell of SrTiO3 are independent
of layer thicknesses and growth sequences, indicating that the mobile carriers
are in a high concentration, two-dimensional electron gas bound to the
interface. These carrier densities closely meet the electrostatic requirements
for compensating the fixed charge at these polar interfaces. Based on the
experimental results, insights into interfacial band alignments, charge
distribution and the influence of different electrostatic boundary conditions
are obtained.Comment: The article has been accepted by Applied Physics Letters. After it is
published, it will be found at http://apl.aip.org
We demonstrate atomic-resolution chemical mapping using energy-dispersive x-ray spectroscopy in scanning transmission electron microscopy. Theoretical simulations of the imaging process demonstrate that these images are directly interpretable. This is due to the fact that the effective ionization interaction is local and this is an incoherent mode of imaging.
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