910 research outputs found
A study of microminiaturized devices for bioastronautical monitoring or analysis Quarterly report
Analog digital filters, converters, and microminiaturized circuits for bioastronautical applicatio
Interference effects in electronic transport through metallic single-wall carbon nanotubes
In a recent paper Liang {\it et al.} [Nature {\bf 411}, 665 (2001)] showed
experimentally, that metallic nanotubes, strongly coupled to external
electrodes, may act as coherent molecular waveguides for electronic transport.
The experimental results were supported by theoretical analysis based on the
scattering matrix approach. In this paper we analyze theoretically this problem
using a real-space approach, which makes it possible to control quality of
interface contacts. Electronic structure of the nanotube is taken into account
within the tight-binding model. External electrodes and the central part
(sample) are assumed to be made of carbon nanotubes, while the contacts between
electrodes and the sample are modeled by appropriate on-site (diagonal) and
hopping (off-diagonal) parameters. Conductance is calculated by the Green
function technique combined with the Landauer formalism. In the plots
displaying conductance {\it vs.} bias and gate voltages, we have found typical
diamond structure patterns, similar to those observed experimentally. In
certain cases, however, we have found new features in the patterns, like a
double-diamond sub-structure.Comment: 15 pages, 4 figures. To apear in Phys. Rev.
Electron transport in semiconducting carbon nanotubes with hetero-metallic contacts
We present an atomistic self-consistent study of the electronic and transport
properties of semiconducting carbon nanotube in contact with metal electrodes
of different work functions, which shows simultaneous electron and hole doping
inside the nanotube junction through contact-induced charge transfer. We find
that the band lineup in the nanotube bulk region is determined by the effective
work function difference between the nanotube channel and source/drain
electrodes, while electron transmission through the SWNT junction is affected
by the local band structure modulation at the two metal-nanotube interfaces,
leading to an effective decoupling of interface and bulk effects in electron
transport through nanotube junction devices.Comment: Higher quality figures available at http://www.albany.edu/~yx15212
A study of microminiaturized devices for bioastronautical monitoring or analysis Research report, 1 Mar. 1969 - 31 Mar. 1970
Microminiaturized devices for bioastronautical monitoring or analysi
Ramsar Policy Brief No. 5. Restoring drained peatlands: A necessary step to achieve global climate goals
Peatlands cover about 400 million hectares (ha), or 3% of the land surface of our planet. Yet they store more carbon, more effectively and for longer periods, than any other ecosystem on land. Intact peatlands also provide essential ecosystem services such as regulating water cycles, purifying water, and supporting a wealth of biodiversity. Since peat is hidden below ground, it is often unrecognised and can be damaged unknowingly. New, large peatland areas are still being discovered including forest-covered peatlands in the tropics.
Around 50 million ha of peatlands globally are currently drained and have been transformed to grazing land, forestry land and cropland, used for peat extraction or impacted by infrastructure. These drained peatlands are responsible for approximately 4% (2 Gt CO2 -eq/year) of all anthropogenic greenhouse gas emissions. Achieving the climate goals of the Paris Agreement requires protection of all remaining intact peatland and rapid restoration of almost all drained peatlands.
This will also contribute to delivering the Sustainable Development Goals (SDGs), in particular SDG 6, Target 6.6, on protecting and restoring water related ecosystems and SDG 15, Targets 15.1, on conservation, restoration and sustainable use of terrestrial and inland freshwater ecosystems and their services, as well as 15.5 on reducing degradation of natural habitats. The United Nations Decade on Ecosystem Restoration 2021-2030 provides the opportunity to rapidly scale up efforts
Conductance of Distorted Carbon Nanotubes
We have calculated the effects of structural distortions of armchair carbon
nanotubes on their electrical transport properties. We found that the bending
of the nanotubes decreases their transmission function in certain energy ranges
and leads to an increased electrical resistance. Electronic structure
calculations show that these energy ranges contain localized states with
significant - hybridization resulting from the increased curvature
produced by bending. Our calculations of the contact resistance show that the
large contact resistances observed for SWNTs are likely due to the weak
coupling of the NT to the metal in side bonded NT-metal configurations.Comment: 5 pages RevTeX including 4 figures, submitted to PR
Enhanced thermal stability and spin-lattice relaxation rate of N@C60 inside carbon nanotubes
We studied the temperature stability of the endohedral fullerene molecule,
N@C60, inside single-wall carbon nanotubes using electron spin resonance
spectroscopy. We found that the nitrogen escapes at higher temperatures in the
encapsulated material as compared to its pristine, crystalline form. The
temperature dependent spin-lattice relaxation time, T_1, of the encapsulated
molecule is significantly shorter than that of the crystalline material, which
is explained by the interaction of the nitrogen spin with the conduction
electrons of the nanotubes.Comment: 5 pages, 4 figures, 1 tabl
High on-off conductance switching ratio in light-driven self-assembled molecular devices
Date du colloque : 5-9/01/2010International audienc
Reversible Band Gap Engineering in Carbon Nanotubes by Radial Deformation
We present a systematic analysis of the effect of radial deformation on the
atomic and electronic structure of zigzag and armchair single wall carbon
nanotubes using the first principle plane wave method. The nanotubes were
deformed by applying a radial strain, which distorts the circular cross section
to an elliptical one. The atomic structure of the nanotubes under this strain
are fully optimized, and the electronic structure is calculated
self-consistently to determine the response of individual bands to the radial
deformation. The band gap of the insulating tube is closed and eventually an
insulator-metal transition sets in by the radial strain which is in the elastic
range. Using this property a multiple quantum well structure with tunable and
reversible electronic structure is formed on an individual nanotube and its
band-lineup is determined from first-principles. The elastic energy due to the
radial deformation and elastic constants are calculated and compared with
classical theories.Comment: To be appear in Phys. Rev. B, Apr 15, 200
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