oblique propagation
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2021 ◽  
Vol 87 (6) ◽  
Author(s):  
J.M. TenBarge ◽  
B. Ripperda ◽  
A. Chernoglazov ◽  
A. Bhattacharjee ◽  
J.F. Mahlmann ◽  
...  

Alfvén wave collisions are the primary building blocks of the non-relativistic turbulence that permeates the heliosphere and low- to moderate-energy astrophysical systems. However, many astrophysical systems such as gamma-ray bursts, pulsar and magnetar magnetospheres and active galactic nuclei have relativistic flows or energy densities. To better understand these high-energy systems, we derive reduced relativistic magnetohydrodynamics equations and employ them to examine weak Alfvénic turbulence, dominated by three-wave interactions, in reduced relativistic magnetohydrodynamics, including the force-free, infinitely magnetized limit. We compare both numerical and analytical solutions to demonstrate that many of the findings from non-relativistic weak turbulence are retained in relativistic systems. But, an important distinction in the relativistic limit is the inapplicability of a formally incompressible limit, i.e. there exists finite coupling to the compressible fast mode regardless of the strength of the magnetic field. Since fast modes can propagate across field lines, this mechanism provides a route for energy to escape strongly magnetized systems, e.g. magnetar magnetospheres. However, we find that the fast-Alfvén coupling is diminished in the limit of oblique propagation.


2021 ◽  
Vol 23 (3) ◽  
pp. 035301
Author(s):  
Muhammad KHALID ◽  
Ghufran ULLAH ◽  
Mohsin KHAN ◽  
Sheraz AHMAD ◽  
Sardar NABI ◽  
...  

2020 ◽  
Vol 6 (4) ◽  
pp. 18-25
Author(s):  
Anatoliy Nekrasov ◽  
Vyacheslav Pilipenko

We have studied MHD waves (Alfvén and fast compressional modes) in a homogeneous collisional three-component low-β plasma. The three-component plasma consists of electrons, ions, and neutrals with arbitrary ratio between collision frequencies and wave time scales. We have derived a general dispersion equation and relationships for phase velocity and collisional damping rates for MHD modes for various limiting cases: from weak collisions to a strong collisional coupling, and for longitudinal and oblique propagation. In a weak collision limit, the MHD eigen-modes are reduced to ordinary low-damping Alfvén and fast magnetosonic waves. For a partially ionized plasma with a strong collisional coupling of neutrals and ions, velocities of magnetosonic and Alfvén waves are substantially reduced, as compared to the Alfvén velocity in the ideal MHD theory. At a very low frequency, when neutrals and ions are strongly coupled, a possibility arises of weakly damping MHD modes, called “decelerated” MHD modes. These modes can be observed in the solar corona/chromosphere and in the F layer of the terrestrial ionosphere.


2020 ◽  
Vol 6 (4) ◽  
pp. 17-23
Author(s):  
Anatoliy Nekrasov ◽  
Vyacheslav Pilipenko

We have studied MHD waves (Alfvén and fast compressional modes) in a homogeneous collisional three-component low-β plasma. The three-component plasma consists of electrons, ions, and neutrals with arbitrary ratio between collision frequencies and wave time scales. We have derived a general dispersion equation and relationships for phase velocity and collisional damping rates for MHD modes for various limiting cases: from weak collisions to a strong collisional coupling, and for longitudinal and oblique propagation. In a weak collision limit, the MHD eigen-modes are reduced to ordinary low-damping Alfvén and fast magnetosonic waves. For a partially ionized plasma with a strong collisional coupling of neutrals and ions, velocities of magnetosonic and Alfvén waves are substantially reduced, as compared to the Alfvén velocity in the ideal MHD theory. At a very low frequency, when neutrals and ions are strongly coupled, a possibility arises of weakly damping MHD modes, called “decelerated” MHD modes. These modes can be observed in the solar corona/chromosphere and in the F layer of the terrestrial ionosphere.


2020 ◽  
Vol 91 (2) ◽  
pp. 20902
Author(s):  
Theodosios Karamanos ◽  
Theodoros Zygiridis ◽  
Nikolaos Kantartzis

A rigorous technique for the consistent calculation of the effective parameters of infinite three-dimensional metamaterial particle arrays in the realistic case of oblique wave propagation, is presented in this paper. The extracted polarizabilities of the consisting scatterer and the numerically retrieved wavenumber for the obliquely propagating electromagnetic waves are systematically inserted into a properly modified first-principles homogenization technique, thus leading to the characterization of the effective medium. Finally, the proposed methodology is applied to two popular, anisotropic metamaterial resonators.


2020 ◽  
Author(s):  
Neil Hindley ◽  
Corwin Wright ◽  
Lars Hoffmann ◽  
Tracy Moffat-Griffin ◽  
M. Joan Alexander ◽  
...  

<p>Atmospheric gravity waves are a fundamental component of the Earth’s dynamical system. These mesoscale waves play a key role in the coupling of different atmospheric layers, acting as crucial drivers of the middle atmospheric circulation through the transport and deposition of energy and momentum. As Global Circulation Models (GCMs) achieve ever higher resolution in the stratosphere, there is a need to ensure that the simulated gravity waves resolved in these models are well constrained by observations, which in turn ensures that modelled circulations are realistic and not over-dependent on tuning with parameterisations. However, obtaining 3-D gravity-wave measurements in the real atmosphere is notoriously difficult. Global 3-D observations of wave properties in the stratosphere are required in order to accurately estimate gravity wave fluxes that can be compared to models. Here we analyse a unique long-term satellite dataset of specialised high-resolution 3-D temperature measurements from NASA’s AIRS/Aqua instrument from 2002-2020. By analysing these data with a 3-D Stockwell transform (3DST) using high-performance computing, we can reveal global distributions of gravity-wave amplitudes, wavelengths, intermittency and directional momentum fluxes in the stratosphere across two decades - the largest such 3-D study of stratospheric gravity waves performed yet. This long-term dataset reveals solar-cycle variability of gravity-wave amplitudes in the tropics, significant reductions in gravity-wave fluxes during southern Sudden Stratospheric Warmings (SSWs) and the persistent oblique propagation of wintertime gravity waves into the southern polar vortex around 60S each year, a phenomenon that is not observed in the northern hemisphere. With these new observations we can begin to better constrain simulated gravity waves and their impacts in GCMs, ultimately leading to better forecasts of weather and climate.</p>


2020 ◽  
Author(s):  
Evgeny V. Panov ◽  
San Lu ◽  
Philip L. Pritchett

<pre>The kinetic ballooning/interchange instability (BICI) was recently found to produce azimutally narrow interchange <br />heads extending from the near-Earth magnetotail into the dipole region. In their nonlinear evolution individual <br />heads were predicted to grow into transient earthward moving northward magnetic field intensifications <br />(dipolarization fronts; DFs). The distinguished signatures of such fronts would be their oblique propagation <br />and cross-tail localization due to the finite k$_y$ structure of the BICI modes. We compare DFs that were observed <br />by two THEMIS probes at 11 Earth's radii (R$_E$) downtail amidst previously identified interchange heads with a <br />simulated interchange head during later-stage BICI development. The comparison shows that the DFs propagated <br />dawnward at about 45$^{\circ}$ to the earthward direction. The leading edges and trailing tails of the DFs were <br />structured similarly to those of the simulated interchange head. The analysis evidences that BICI indeed releases <br />obliquely propagating azimuthally localized dipolarization fronts in the Earth's magnetotail. </pre>


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