13,036 research outputs found
Travelling wave solutions for degenerate pseudo-parabolic equation modelling two-phase flow in porous media
We discuss a pseudo-parabolic equation modelling two-phase flow in porous media, which includes a dynamic capillary pressure term. We extend results obtained previously for linear higher order terms and investigate the existence of travelling wave solutions in the non-linear and degenerate case. These cases may lead to non-smooth travelling waves, as well as to a discontinuous capillary pressure
Limitations of Absolute Current Densities Derived from the Semel & Skumanich Method
Semel and Skumanich proposed a method to obtain the absolute electric current
density, |Jz|, without disambiguation of 180 degree in the transverse field
directions. The advantage of the method is that the uncertainty in the
determination of the ambiguity in the magnetic azimuth is removed. Here, we
investigate the limits of the calculation when applied to a numerical MHD
model. We found that the combination of changes in the magnetic azimuth with
vanishing horizontal field component leads to errors, where electric current
densities are often strong. Where errors occur, the calculation gives |Jz| too
small by factors typically 1.2 ~ 2.0.Comment: 10 pages, 4 figures. To appear on Science in China Series G: Physics,
Mechanics & Astronomy, October 200
Travelling wave solutions for degenerate pseudo-parabolic equation modelling two-phase flow in porous media
We discuss a pseudo-parabolic equation modelling two-phase flow in porous media, which includes a dynamic capillary pressure term. We extend results obtained previously for linear higher order terms and investigate the existence of travelling wave solutions in the non-linear and degenerate case. These cases may lead to non-smooth travelling waves, as well as to a discontinuous capillary pressure
Thermal signatures of tether-cutting reconnections in pre-eruption coronal flux ropes: hot central voids in coronal cavities
Using a 3D MHD simulation, we model the quasi-static evolution and the onset
of eruption of a coronal flux rope. The simulation begins with a twisted flux
rope emerging at the lower boundary and pushing into a pre-existing coronal
potential arcade field. At a chosen time the emergence is stopped with the
lower boundary taken to be rigid. Then the coronal flux rope settles into a
quasi-static rise phase during which an underlying, central sigmoid-shaped
current layer forms along the so called hyperbolic flux tube (HFT), a
generalization of the X-line configuration. Reconnections in the dissipating
current layer effectively add twisted flux to the flux rope and thus allow it
to rise quasi-statically, even though the magnetic energy is decreasing as the
system relaxes. We examine the thermal features produced by the current layer
formation and the associated "tether-cutting" reconnections as a result of
heating and field aligned thermal conduction. It is found that a central hot,
low-density channel containing reconnected, twisted flux threading under the
flux rope axis forms on top of the central current layer. When viewed in the
line of sight roughly aligned with the hot channel (which is roughly along the
neutral line), the central current layer appears as a high-density vertical
column with upward extensions as a "U" shaped dense shell enclosing a central
hot, low-density void. Such thermal features have been observed within coronal
prominence cavities. Our MHD simulation suggests that they are the signatures
of the development of the HFT topology and the associated tether-cutting
reconnections, and that the central void grows and rises with the
reconnections, until the flux rope reaches the critical height for the onset of
the torus instability and dynamic eruption ensues.Comment: 30 pages, 12 figures, accepted for publication in Ap
Nonsaturating magnetoresistance and nontrivial band topology of type-II Weyl semimetal NbIrTe4
Weyl semimetals, characterized by nodal points in the bulk and Fermi arc
states on the surface, have recently attracted extensive attention due to the
potential application on low energy consumption electronic materials. In this
report, the thermodynamic and transport properties of a theoretically predicted
Weyl semimetal NbIrTe4 is measured in high magnetic fields up to 35 T and low
temperatures down to 0.4 K. Remarkably, NbIrTe4 exhibits a nonsaturating
transverse magnetoresistance which follows a power-law dependence in B.
Low-field Hall measurements reveal that hole-like carriers dominate the
transport for T 80 K, while the significant enhancement of electron
mobilities with lowering T results in a non-negligible contribution from
electron-like carriers which is responsible for the observed non-linear Hall
resistivity at low T. The Shubnikov-de Haas oscillations of the Hall
resistivity under high B give the light effective masses of charge carriers and
the nontrivial Berry phase associated with Weyl fermions. Further
first-principles calculations confirm the existence of 16 Weyl points located
at kz = 0, 0.02 and 0.2 planes in the Brillouin zone.Comment: 5 figures, 1 tabl
On Signatures of Twisted Magnetic Flux Tube Emergence
Recent studies of NOAA active region 10953, by Okamoto {\it et al.} ({\it
Astrophys. J. Lett.} {\bf 673}, 215, 2008; {\it Astrophys. J.} {\bf 697}, 913,
2009), have interpreted photospheric observations of changing widths of the
polarities and reversal of the horizontal magnetic field component as
signatures of the emergence of a twisted flux tube within the active region and
along its internal polarity inversion line (PIL). A filament is observed along
the PIL and the active region is assumed to have an arcade structure. To
investigate this scenario, MacTaggart and Hood ({\it Astrophys. J. Lett.} {\bf
716}, 219, 2010) constructed a dynamic flux emergence model of a twisted
cylinder emerging into an overlying arcade. The photospheric signatures
observed by Okamoto {\it et al.} (2008, 2009) are present in the model although
their underlying physical mechanisms differ. The model also produces two
additional signatures that can be verified by the observations. The first is an
increase in the unsigned magnetic flux in the photosphere at either side of the
PIL. The second is the behaviour of characteristic photospheric flow profiles
associated with twisted flux tube emergence. We look for these two signatures
in AR 10953 and find negative results for the emergence of a twisted flux tube
along the PIL. Instead, we interpret the photospheric behaviour along the PIL
to be indicative of photospheric magnetic cancellation driven by flows from the
dominant sunspot. Although we argue against flux emergence within this
particular region, the work demonstrates the important relationship between
theory and observations for the successful discovery and interpretation of
signatures of flux emergence.Comment: 14 pages, 8 figures, accepted for publication in Solar Physic
Deep Gradient Learning for Efficient Camouflaged Object Detection
This paper introduces DGNet, a novel deep framework that exploits objectgradient supervision for camouflaged object detection (COD). It decouples thetask into two connected branches, i.e., a context and a texture encoder. Theessential connection is the gradient-induced transition, representing a softgrouping between context and texture features. Benefiting from the simple butefficient framework, DGNet outperforms existing state-of-the-art COD models bya large margin. Notably, our efficient version, DGNet-S, runs in real-time (80fps) and achieves comparable results to the cutting-edge modelJCSOD-CVPR with only 6.82% parameters. Application results also showthat the proposed DGNet performs well in polyp segmentation, defect detection,and transparent object segmentation tasks. Codes will be made available athttps://github.com/GewelsJI/DGNet.<br
The Three-dimensional Evolution of Rising, Twisted Magnetic Flux Tubes in a Gravitationally Stratified Model Convection Zone
We present three-dimensional numerical simulations of the rise and
fragmentation of twisted, initially horizontal magnetic flux tubes which evolve
into emerging Omega-loops. The flux tubes rise buoyantly through an
adiabatically stratified plasma that represents the solar convection zone. The
MHD equations are solved in the anelastic approximation, and the results are
compared with studies of flux tube fragmentation in two dimensions. We find
that if the initial amount of field line twist is below a critical value, the
degree of fragmentation at the apex of a rising Omega-loop depends on its
three-dimensional geometry: the greater the apex curvature of a given
Omega-loop, the lesser the degree of fragmentation of the loop as it approaches
the photosphere. Thus, the amount of initial twist necessary for the loop to
retain its cohesion can be reduced substantially from the two-dimensional
limit. The simulations also suggest that as a fragmented flux tube emerges
through a relatively quiet portion of the solar disk, extended crescent-shaped
magnetic features of opposite polarity should form and steadily recede from one
another. These features eventually coalesce after the fragmented portion of the
Omega-loop emerges through the photosphere.Comment: 17 pages, 17 figures, uses AAS LaTeX macros v5.0. ApJ, in pres
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