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4: Some Applications of the Virial Theorem

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    141462

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    • 4.1: Pulsational Stability of White Dwarfs
      This page covers the virial theorem's relevance in astrophysics, particularly for black holes and neutron stars, challenging conventional theories. It notes advancements in the 1960s in observational astronomy that led to the study of supermassive stars' instabilities.
    • 4.2: The Influence of Rotation and Magnetic Fields on White Dwarf Gravitational Instability
      This page examines the stability of stars, focusing on white dwarfs under the effects of rotation and magnetic fields in comparison to supermassive stars. It explains that while rotation provides some stability, white dwarfs require more rotational energy due to stronger gravitational forces. The discussion includes equations that illustrate stability conditions, especially near the Chandrasekhar limit, indicating that magnetic fields and rotation only slightly affect stability.
    • 4.3: Stability of Neutron Stars
      This page covers neutron stars and their unique features compared to white dwarfs, clarifying misconceptions about mass-radius relationships and limiting mass origins due to general relativity and not just changes in the Equation of state. It also addresses the instabilities neutron stars face when exceeding certain mass limits, influenced by rotation and magnetic fields.
    • 4.4: Additional Topics and Final Thoughts
      This page elaborates on the virial theorem's crucial role in stellar astrophysics, detailing its application to star stability and structure, influenced by surface pressure and magnetic fields. It discusses historical development, Kelvin-Helmholtz contraction, and future implications in quasars and gravitational collapse.
    • 4N: Notes to Chapter 4
      This page covers the integration of gravitational equations via integration by parts, linking pressure and mass in a defined volume. It presents the polytropic equation of state and the parameter \(\gamma\) tied to density and pressure. Additionally, it examines Chandrasekhar’s parametric equation for a nearly relativistic degenerate gas, demonstrating variable behavior as they approach infinity and establishing connections between the relationships in a physical context.
    • 4.6: References

    This page titled 4: Some Applications of the Virial Theorem is shared under a All Rights Reserved (used with permission) license and was authored, remixed, and/or curated by George W. Collins II (Pachart Foundation) via source content that was edited to the style and standards of the LibreTexts platform.