Magnetic Fields in High-Density Stellar Matter

Lugones, G.

doi:10.1063/1.2077189

Cited by 2 publications

(1 citation statement)

References 45 publications

(68 reference statements)

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“…These compact stars typically have very large magnetic fields. Neutron stars can have magnetic fields as large as B ∼ 10 12 − 10 14 G in their surfaces, while in magnetars they are in the range B ∼ 10 14 − 10 15 G, and perhaps as high as 10 16 G [2] (for a recent review of magnetic fields in dense stars see [3]). Even though we do not know yet of any suitable mechanism to produce more intense fields, the virial theorem [4] allows the field magnitude to reach values as large as 10 18 − 10 19 G. If quark stars are self-bound rather than gravitational-bound objects, the upper limit that has been obtained by comparing the magnetic and gravitational energies, could go even higher.…”

Section: Introductionmentioning

confidence: 99%

Dense Quark Matter in a Magnetic Field

Incera

Ferrer

Manuel

2006

Proceedings of 29th Johns Hopkins Workshop on Current Problems in Particle Theory: Strong Matter in the Heavens — PoS(JHW2005)

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Section: Introductionmentioning

confidence: 99%

Dense Quark Matter in a Magnetic Field

Incera

Ferrer

Manuel

2006

Proceedings of 29th Johns Hopkins Workshop on Current Problems in Particle Theory: Strong Matter in the Heavens — PoS(JHW2005)

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A theory of the relativistic fermionic spinrevorbital

Little¹

2015

Int. J. Phys. Sci.

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The Little Rules and Effect describe the cause of phenomena of physical and chemical transformations on the basis of spin antisymmetry and the consequent magnetism of the most fundamental elements of leptons and quarks and in particular electrons, protons and neutrons causing orbital motions and mutual revolutionary motions (spinrevorbital) to determine the structure and the dynamics of nucleons, nuclei, atoms, molecules, bulk structures and even stellar structures. By considering the Little Effect in multi-body, confined, pressured, dense, temperate, and physicochemically open systems, new mechanisms and processes will be discovered and explanations are given to the stability of multifermionic systems for continuum of unstable perturbatory states with settling to stable discontinuum states (in accord to the quantum approximation) to avoid chaos in ways that have not been known or understood. On the basis of the Little Effect, the higher order terms of the Hamiltonian provide Einstein's missing link between quantum mechanics and relativity for a continuum of unstable states. Such continuum of unstable, hidden states determines fractional charges and fractured dipoles (orbitals) that strongly couple with limitations of larger space and shorter times for coupling quantum magnetism (spinrevorbitals) to macromagnetism and gravity (via phasal and group dispersions, respectively) and vice versa and for coupling orbital electricity (spintransorbitals) to macroelectricity and classical (and heat) mechanics (via phasal and group dispersions, respectively) and vice versa.

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Magnetic Fields in High-Density Stellar Matter

Cited by 2 publications

References 45 publications

Dense Quark Matter in a Magnetic Field

Dense Quark Matter in a Magnetic Field

A theory of the relativistic fermionic spinrevorbital

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