212 research outputs found
Dissipative Quantum Hall Effect in Graphene near the Dirac Point
We report on the unusual nature of nu=0 state in the integer quantum Hall
effect (QHE) in graphene and show that electron transport in this regime is
dominated by counter-propagating edge states. Such states, intrinsic to
massless Dirac quasiparticles, manifest themselves in a large longitudinal
resistivity rho_xx > h/e^2, in striking contrast to rho_xx behavior in the
standard QHE. The nu=0 state in graphene is also predicted to exhibit
pronounced fluctuations in rho_xy and rho_xx and a smeared zero Hall plateau in
sigma_xy, in agreement with experiment. The existence of gapless edge states
puts stringent constraints on possible theoretical models of the nu=0 state.Comment: 4 pgs, 4 fg
Tearing Graphene Sheets From Adhesive Substrates Produces Tapered Nanoribbons
Graphene is a truly two-dimensional atomic crystal with exceptional
electronic and mechanical properties. Whereas conventional bulk and thin-film
materials have been studied extensively, the key mechanical properties of
graphene, such as tearing and cracking, remain unknown, partly due to its
two-dimensional nature and ultimate single-atom-layer thickness, which result
in the breakdown of conventional material models. By combining first-principles
ReaxFF molecular dynamics and experimental studies, a bottom-up investigation
of the tearing of graphene sheets from adhesive substrates is reported,
including the observation of the formation of tapered graphene nanoribbons.
Through a careful analysis of the underlying molecular rupture mechanisms, it
is shown that the resulting nanoribbon geometry is controlled by both the
graphene-substrate adhesion energy and by the number of torn graphene layers.
By considering graphene as a model material for a broader class of
two-dimensional atomic crystals, these results provide fundamental insights
into the tearing and cracking mechanisms of highly confined nanomaterials
All Inkjet-Printed Graphene-Silver Composite Ink on Textiles for Highly Conductive Wearable Electronics Applications
© 2019, The Author(s). Inkjet-printed wearable electronic textiles (e-textiles) are considered to be very promising due to excellent processing and environmental benefits offered by digital fabrication technique. Inkjet-printing of conductive metallic inks such as silver (Ag) nanoparticles (NPs) are well-established and that of graphene-based inks is of great interest due to multi-functional properties of graphene. However, poor ink stability at higher graphene concentration and the cost associated with the higher Ag loading in metal inks have limited their wider use. Moreover, graphene-based e-textiles reported so far are mainly based on graphene derivatives such as graphene oxide (GO) or reduced graphene oxide (rGO), which suffers from poor electrical conductivity. Here we report inkjet printing of highly conductive and cost-effective graphene-Ag composite ink for wearable e-textiles applications. The composite inks were formulated, characterised and inkjet-printed onto PEL paper first and then sintered at 150 °C for 1 hr. The sheet resistance of the printed patterns is found to be in the range of ~0.08–4.74 Ω/sq depending on the number of print layers and the graphene-Ag ratio in the formulation. The optimised composite ink was then successfully printed onto surface pre-treated (by inkjet printing) cotton fabrics in order to produce all-inkjet-printed highly conductive and cost-effective electronic textiles
Контролируемые прочностные показатели для различных видов мебели
Методические указания по курсам «Расчет конструкций изделий из древесины и испытания мебели», «Технология изделий из древесины» для выполнения практических и лабораторных работ обучающимися по направлениям 35.03.02, 35.04.02 «Технология лесозаготовительных и деревоперерабатывающих производств», профиль «Технология деревообработки
Biquadratic exchange interactions in two-dimensional magnets
Magnetism in recently discovered van der Waals materials has opened several avenues in the study of fundamental spin interactions in truly two-dimensions. A paramount question is what effect higher-order interactions beyond bilinear Heisenberg exchange have on the magnetic properties of few-atom thick compounds. Here we demonstrate that biquadratic exchange interactions, which is the simplest and most natural form of non-Heisenberg coupling, assume a key role in the magnetic properties of layered magnets. Using a combination of nonperturbative analytical techniques, non-collinear first-principles methods and classical Monte Carlo calculations that incorporate higher-order exchange, we show that several quantities including magnetic anisotropies, spin-wave gaps and topological spin-excitations are intrinsically renormalized leading to further thermal stability of the layers. We develop a spin Hamiltonian that also contains antisymmetric exchanges (e.g., Dzyaloshinskii–Moriya interactions) to successfully rationalize numerous observations, such as the non-Ising character of several compounds despite a strong magnetic anisotropy, peculiarities of the magnon spectrum of 2D magnets, and the discrepancy between measured and calculated Curie temperatures. Our results provide a theoretical framework for the exploration of different physical phenomena in 2D magnets where biquadratic exchange interactions have an important contribution
Failure Processes in Embedded Monolayer Graphene under Axial Compression
Exfoliated monolayer graphene flakes were embedded in a polymer matrix and
loaded under axial compression. By monitoring the shifts of the 2D Raman
phonons of rectangular flakes of various sizes under load, the critical strain
to failure was determined. Prior to loading care was taken for the examined
area of the flake to be free of residual stresses. The critical strain values
for first failure were found to be independent of flake size at a mean value of
-0.60 % corresponding to a yield stress of -6 GPa. By combining Euler mechanics
with a Winkler approach, we show that unlike buckling in air, the presence of
the polymer constraint results in graphene buckling at a fixed value of strain
with an estimated wrinkle wavelength of the order of 1-2 nm. These results were
compared with DFT computations performed on analogue coronene/ PMMA oligomers
and a reasonable agreement was obtained.Comment: 28 pages. Manuscript 20 pages, 8 figures. Supporting information 10
pages, 6 figure
Relativistic domain-wall dynamics in van der Waals antiferromagnet MnPS3
The discovery of two-dimensional (2D) magnetic van der Waals (vdW) materials has flourished an endeavor for fundamental problems as well as potential applications in computing, sensing and storage technologies. Of particular interest are antiferromagnets, which due to their intrinsic exchange coupling show several advantages in relation to ferromagnets such as robustness against external magnetic perturbations. Here we show that, despite of this cornerstone, the magnetic domains of recently discovered 2D vdW MnPS3 antiferromagnet can be controlled via magnetic fields and electric currents. We achieve ultrafast domain-wall dynamics with velocities up to ~3000 m s−1 within a relativistic kinematic. Lorentz contraction and emission of spin-waves in the terahertz gap are observed with dependence on the edge termination of the layers. Our results indicate that the implementation of 2D antiferromagnets in real applications can be further controlled through edge engineering which sets functional characteristics for ultrathin device platforms with relativistic features
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