Cosmic Plasmas and Electromagnetic Phenomena
Material type:
ArticleLanguage: English Publication details: MDPI - Multidisciplinary Digital Publishing Institute 2019Description: 1 electronic resource (264 p.)ISBN: - books978-3-03921-466-2
- 9783039214662
- 9783039214655
- cosmic ray knee and ankle
- blazars
- numerical methods
- global jets
- MHD-accretion
- muti-messenger astronomy
- massive star supernovae
- galaxies: active
- TBD
- 26Al
- black holes
- accreting black holes
- particle-in-cell simulations
- kink-like instability
- laser-induced nuclear reactions
- magnetic fields
- magneto-hydrodynamics
- gamma-ray bursts
- active galactic nuclei
- accretion discs-jets
- numerical relativity
- plasma physics
- GRMHD
- high-power laser systems
- radio interferometry
- recollimation shocks
- effective lifetime
- multi-wavelength astronomy
- relativistic jets
- high energy astrophysics
- jets
- active galaxies
- relativistic astrophysics
- helical magnetic fields
- laser plasma
- X-ray binaries
- polarization
- the Weibel instability
- AGN
- neutrino astrophysics
- radiation mechanism: non-thermal
- nuclear astrophysics
- cosmic rays
- mushroom instability
- accretion disks
- MHD winds
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Electronic-Books
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OPJGU Sonepat- Campus | E-Books Open Access | Available |
Open Access star Unrestricted online access
During the past few decades, plasma science has witnessed a great growth in laboratory studies, in simulations, and in space. Plasma is the most common phase of ordinary matter in the universe. It is a state in which ionized matter (even as low as 1%) becomes highly electrically conductive. As such, long-range electric and magnetic fields dominate its behavior. Cosmic plasmas are mostly associated with stars, supernovae, pulsars and neutron stars, quasars and active galaxies at the vicinities of black holes (i.e., their jets and accretion disks). Cosmic plasma phenomena can be studied with different methods, such as laboratory experiments, astrophysical observations, and theoretical/computational approaches (i.e., MHD, particle-in-cell simulations, etc.). They exhibit a multitude of complex magnetohydrodynamic behaviors, acceleration, radiation, turbulence, and various instability phenomena. This Special Issue addresses the growing need of the plasma science principles in astrophysics and presents our current understanding of the physics of astrophysical plasmas, their electromagnetic behaviors and properties (e.g., shocks, waves, turbulence, instabilities, collimation, acceleration and radiation), both microscopically and macroscopically. This Special Issue provides a series of state-of-the-art reviews from international experts in the field of cosmic plasmas and electromagnetic phenomena using theoretical approaches, astrophysical observations, laboratory experiments, and state-of-the-art simulation studies.
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