352 research outputs found
Modification of Nanodiamonds by Xenon Implantation: A Molecular Dynamics Study
Xenon implantation into nanodiamonds is studied using molecular dynamics. The
nanodiamonds range in size from 2-10 nm and the primary knock-on (PKA) energy
extends up to 40 keV. For small nanodiamonds an energy-window effect occurs in
which PKA energies of around 6 keV destroy the nanodiamond, while in larger
nanodiamonds the radiation cascade is increasingly similar to those in bulk
material. Destruction of the small nanodiamonds occurs due to thermal annealing
associated with the small size of the particles and the absence of a heat-loss
path. Simulations are also performed for a range of impact parameters, and for
a series of double-nanodiamond systems in which a heat-loss path is present.
The latter show that the thermal shock caused by the impact occurs on the
timescale of a few picoseconds. These findings are relevant to ion-beam
modification of nanoparticles by noble gases as well as meteoritic studies
where implantation is proposed as the mechanism for xenon incorporation in
pre-solar nanodiamonds
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The structure of junctions between carbon nanotubes and graphene shells
Junctions between carbon nanotubes and flat or curved graphene structures are fascinating for a number of reasons. It has been suggested that such junctions could be used in nanoelectronic devices, or as the basis of three-dimensional carbon materials, with many potential applications. However, there have been few detailed experimental analyses of nanotube-graphene connections. Here we describe junctions between nanotubes and graphene shells in a material produced by passing a current through graphite. Transmission electron micrographs show that the junction angles are not random but fall close to multiples of 30°. We show that connections with these angles are the only ones which are consistent with the symmetry of the hexagonal lattice, and molecular models show that a continuous lattice requires the presence of large carbon rings at the junction. Some of the configurations we propose have not been previously considered, and could be used to construct new kinds of three-dimensional carbon architecture. We also discuss the possible formation mechanism of the junctions
Hemispherical-Directional Reflectance (HDRF) of Windblown Snow-Covered Arctic Tundra at Large Solar Zenith Angles
Ground-based measurements of the hemispherical-directional
reflectance factor (HDRF) of windblown snowcovered
Arctic tundra were measured at large solar zenith angles
(79◦–85◦) for six sites near the international research base in
Ny-Ålesund, Svalbard. Measurements were made with the Gonio
RAdiometric Spectrometer System over the viewing angles 0◦–50◦
and the azimuth angles 0◦–360◦, for the wavelength range
400–1700 nm. The HDRF measurements showed good consistency
between sites for near-nadir and backward viewing angles, with a
relative standard deviation of less than 10% between sites where
the snowpack was smooth and the snow depth was greater than
40 cm. The averaged HDRF showed good symmetry with respect
to the solar principal plane and exhibited a forward scattering
peak that was strongly wavelength dependent, with greater than
a factor of 2 increase in the ratio of maximum to minimum HDRF
values for all viewing angles over the wavelength range 400–
1300 nm. The angular effects on the HDRF had minimal influence
for viewing angles less than 15◦ in the backward viewing direction
for the averaged sites and agreed well with another study of snow
HDRF for infrared wavelengths, but showed differences of up to
0.24 in the HDRF for visible wavelengths owing to light-absorbing
impurities measured in the snowpack. The site that had the largest
roughness elements showed the strongest anisotropy in the HDRF,
a large reduction in forward scattering, and a strong asymmetry
with respect to the solar principal plane
Preparing potential teachers for the transition from employment to teacher training: an evaluative case study of a Maths Enhancement Course
In response to a UK government drive to improve maths teaching in schools, the South West London Maths Enhancement Course (MEC) has been set up though collaboration between three Higher Education institutions (HEIs) to provide an efficient route for non maths graduates in employment to upgrade their subject knowledge and give a smooth transition into teacher training (PGCE).
An evaluation of the scheme, measured against Teacher Development Agency (TDA) objectives and success criteria agreed by university staff, involved thematic analysis of focus group discussions and interviews with students and staff during both the MEC and PGCE courses. This has revealed a high level of satisfaction and success related to a number of underlying issues, particularly around student recruitment, curriculum design, peer support and staff collaboration. The model offers an example of practice transferable to a range of programmes aimed at supporting students in the transition between levels and institutions
Defining graphenic crystallites in disordered carbon: moving beyond the platelet model
We develop a picture of graphenic crystallites within disordered carbons that
goes beyond the traditional model of graphitic platelets at random orientation.
Using large atomistic models containing one million atoms, we redefine the
meaning of the quantity La extracted from X-ray diffraction (XRD) patterns. Two
complementary approaches are used to measure the size of graphenic
crystallites, which are defined as regions of regularly arranged hexagons.
Firstly, we calculate the X-ray diffraction pattern directly from the atomistic
coordinates of the structure and analyse them following a typical experimental
process. Second, the graphenic crystallites are identified from a direct
geometrical approach. By mapping the structure directly, we replace the
idealised picture of the crystallite with a more realistic representation of
the material and provide a well-defined interpretation for measurements
of disordered carbon. A key insight is that the size distribution is skewed
heavily towards small fragments, with more than 75% of crystallites smaller
than half of
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Catalysis-free transformation of non-graphitising carbons into highly crystalline graphite
High-purity graphite is a sought-after material for lithium-ion batteries and graphene production. Most organic materials do not graphitise upon heating unless a metal catalyst is present. The catalyst becomes embedded in the graphite and is difficult to remove. Here, we present a catalysis-free technique capable of producing highly crystalline graphite from materials generally considered incapable of this transformation. Using the furnace inside an Atomic Absorption Spectrometer, we perform repeated high-temperature pulsing of polyvinylidene chloride followed by analysis with Raman, X-ray diffraction and transmission electron microscopy. Unexpectedly, ~90% of the sample transforms into highly ordered graphite with very few defects. A combustion route is proposed in which oxygen attacks the structural units that inhibit graphitisation. We apply the same approach to cellulose and obtain ten times more ordered material than conventional furnaces, confirming that polyvinylidene chloride is not an isolated case. Potentially, this method could be used to synthesise graphite from any organic material, including waste sources such as biomass
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Bottom-up assembly of metallic germanium
Extending chip performance beyond current limits of miniaturisation requires new materials and functionalities that integrate well with the silicon platform. Germanium fits these requirements and has been proposed as a high-mobility channel material, a light emitting medium in silicon-integrated lasers, and a plasmonic conductor for bio-sensing. Common to these diverse applications is the need for homogeneous, high electron densities in three-dimensions (3D). Here we use a bottom-up approach to demonstrate the 3D assembly of atomically sharp doping profiles in germanium by a repeated stacking of two-dimensional (2D) high-density phosphorus layers. This produces high-density (1019 to 1020 cm−3) low-resistivity (10−4Ω · cm) metallic germanium of precisely defined thickness, beyond the capabilities of diffusion-based doping technologies. We demonstrate that free electrons from distinct 2D dopant layers coalesce into a homogeneous 3D conductor using anisotropic quantum interference measurements, atom probe tomography, and density functional theory
Calibrating the atomic balance by carbon nanoclusters
Carbon atoms are counted at near atomic-level precision using a scanning
transmission electron microscope calibrated by carbon nanocluster mass
standards. A linear calibration curve governs the working zone from a few
carbon atoms up to 34,000 atoms. This linearity enables adequate averaging of
the scattering cross sections, imparting the experiment with near atomic-level
precision despite the use of a coarse mass reference. An example of this
approach is provided for thin layers of stacked graphene sheets. Suspended
sheets with a thickness below 100 nm are visualized, providing quantitative
measurement in a regime inaccessible to optical and scanning probe methods
Rare-Earth Orthophosphates From Atomistic Simulations
Lanthanide phosphates (LnPO4) are considered as a potential nuclear waste form for immobilization of Pu and minor actinides (Np, Am, and Cm). In that respect, in the recent years we have applied advanced atomistic simulation methods to investigate various properties of these materials on the atomic scale. In particular, we computed several structural, thermochemical, thermodynamic and radiation damage related parameters. From a theoretical point of view, these materials turn out to be excellent systems for testing quantum mechanics-based computational methods for strongly correlated electronic systems. On the other hand, by conducting joint atomistic modeling and experimental research, we have been able to obtain enhanced understanding of the properties of lanthanide phosphates. Here we discuss joint initiatives directed at understanding the thermodynamically driven long-term performance of these materials, including long-term stability of solid solutions with actinides and studies of structural incorporation of f elements into these materials. In particular, we discuss the maximum load of Pu into the lanthanide-phosphate monazites. We also address the importance of our results for applications of lanthanide-phosphates beyond nuclear waste applications, in particular the monazite-xenotime systems in geothermometry. For this we have derived a state-of-the-art model of monazite-xenotime solubilities. Last but not least, we discuss the advantage of usage of atomistic simulations and the modern computational facilities for understanding of behavior of nuclear waste-related materials
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