Gyroresonance and Free–Free Radio Emissions from Multithermal Multicomponent Plasma

Type III radio bursts are radio emissions associated with solar flares. They are considered to be caused by electron beams travelling from the solar corona to the solar wind. Magnetic reconnection is a possible accelerator of electron beams in the course of solar flares since it causes unstable distribution functions and density inhomogeneities (cavities). The properties of radio emission by electron beams in an inhomogeneous environment are still poorly understood. We capture the nonlinear kinetic plasma processes of the generation of beam-related radio emissions in inhomogeneous plasmas by utilizing fully kinetic particle-in-cell code numerical simulations. Our model takes into account initial electron velocity distribution functions (EVDFs) as they are supposed to be created by magnetic reconnection. We focus our analysis on low-density regions with strong magnetic fields. The assumed EVDFs allow two distinct mechanisms of radio wave emissions: plasma emission due to wave–wave interactions and so-called electron cyclotron maser emission (ECME) due to direct wave–particle interactions. We investigate the effects of density inhomogeneities on the conversion of free energy from the electron beams into the energy of electrostatic and electromagnetic waves via plasma emission and ECME, as well as the frequency shift of electron resonances caused by perpendicular gradients in the beam EVDFs. Our most important finding is that the number of harmonics of Langmuir waves increases due to the presence of density inhomogeneities. The additional harmonics of Langmuir waves are generated by a coalescence of beam-generated Langmuir waves and their harmonics.

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Sliding Contacts in Planetary Magnetospheres

Symmetry ◽

10.3390/sym13020283 ◽

2021 ◽

Vol 13 (2) ◽

pp. 283

Author(s):

Elena Belenkaya ◽

Igor Alexeev

Keyword(s):

Large Scale ◽

Strong Field ◽

Magnetized Plasma ◽

Sliding Contacts ◽

Radio Emissions ◽

Planetary Magnetospheres ◽

Current Task ◽

Surrounding Space ◽

Non Local ◽

A Current

In the planetary magnetospheres there are specific places connected with velocity breakdown, reconnection, and dynamo processes. Here we pay attention to sliding layers. Sliding layers are formed in the ionosphere, on separatrix surfaces, at the magnetopauses and boundaries of stellar astrospheres, and at the Alfvén radius in the equatorial magnetosphere of rapidly rotating strongly magnetized giant planets. Although sliding contacts usually occur in thin local layers, their influence on the global structure of the surrounding space is very great. Therefore, they are associated with non-local processes that play a key role on a large scale. There can be an exchange between different forms of energy, a generation of strong field-aligned currents and emissions, and an amplification of magnetic fields. Depending on the conditions in the magnetosphere of the planet/exoplanet and in the flow of magnetized plasma passing it, different numbers of sliding layers with different configurations appear. Some are associated with regions of auroras and possible radio emissions. The search for planetary radio emissions is a current task in the detection of exoplanets.

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Wideband Dual-Polarized VHF Antenna for Space Observation Applications

Sensors ◽

10.3390/s20154351 ◽

2020 ◽

Vol 20 (15) ◽

pp. 4351

Author(s):

Alexandru Tatomirescu ◽

Alina Badescu

Keyword(s):

Radiation Pattern ◽

Group Delay ◽

High Gain ◽

Antenna Element ◽

Frequency Bandwidth ◽

Radio Emissions ◽

Relative Bandwidth ◽

Pattern Stability ◽

Dual Polarized ◽

Delay Variation

This work presents the design for an antenna element that can be used in radio arrays for the monitoring and detecting of radio emissions from cosmic particles’ interactions in the atmosphere. For these applications, the pattern stability over frequency is the primary design goal. The proposed antenna has a high gain over a relative bandwidth of 88%, a beamwidth of 2.13 steradians, a small group delay variation and a very stable radiation pattern across the frequency bandwidth of 110 to 190 MHz. It is dual polarized and has a simple mechanical structure which is easy and inexpensive to manufacture. The measurements show that the ground has insignificant impact on the overall radiation pattern.

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Reduction of Electromagnetic Interference Using ZnO-PCL Nanocomposites at Microwave Frequency

Advances in Materials Science and Engineering ◽

10.1155/2015/132509 ◽

2015 ◽

Vol 2015 ◽

pp. 1-7 ◽

Cited By ~ 6

Author(s):

Abubakar Yakubu ◽

Zulkifly Abbas ◽

Nor Azowa Ibrahim ◽

Ahmad Fahad

Keyword(s):

Electromagnetic Interference ◽

Electromagnetic Compatibility ◽

Environmentally Friendly ◽

Microwave Frequency ◽

Absorption Properties ◽

Radio Emissions ◽

Surface Areas ◽

Home Appliance ◽

Coaxial Probe ◽

Very High

In industrial equipment and home appliance applications, the electromagnetic compatibility compliance directive (ECCD) demands that electromagnetic interference side effects be eliminated or marginally minimized. The equipment must not disturb radio and telecommunication as well as other appliances. Additionally the ECCD also governs the immunity of such equipment to interference and seeks to ensure that this equipment is not disturbed by radio emissions when used as intended. Many types of absorbing materials are commercially available. However, many are expensive and not environmentally friendly. It is in the light of the above that we studied the electromagnetic absorption properties of ZnO-PCL nanocomposites prepared from cheap and abundant resources which are environmentally friendly (zinc and polycaprolactone). The test was carried out using a microstrip, open ended coaxial probe, and vector network analyzer. Amongst other findings, result showed that the ZnO-PCL nanocomposite has the capability of attenuating microwave frequency up to −18.2 dB due to their very high specific surface areas attributed to the nanofillers at 12 GHz.

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