5.1-2 Flashcards

1
Q

Degeneracy Pressure in Dense Matter (5)

maybe a better title: degenerate matter

A
  • In white dwarf stars, matter is degenerate
  • Electrons are not bound to individual nuclei
  • Average electron separation is smaller than in heavy atoms
  • Density ρ » 10 g/cm³
  • Laws for an ideal electron gas do not apply
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2
Q

Heisenberg Uncertainty Principle

A

For a 6-dimensional phase space, the size of a quantum state is defined by ΔV Δ³p ≥ h³, where h is Planck’s constant.

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3
Q

Pauli Exclusion Principle

A
  • Electrons (fermions) cannot occupy the same quantum states
  • Each element of phase space has at most 2 fermions (spin up and down)
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4
Q

Degeneracy Pressure in High Density

A
  • At high densities, fermions are forced to higher momentum (p) states
  • Degeneracy pressure arises when all p-states are occupied up to pmax: ΔV Δ3p = h3
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5
Q

Equipartition of Kinetic Energy (2)

what does it tell us?

A
  • pi2 / 2mi
  • Lighter particles have lower p for a given temperature T, less p-states occupied

-> Electrons degenerate first

i guess the first bullet point is just the kinetic energy, not really relevant for the conclusion i think

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6
Q

Pressure in a Gas

A
  • Pressure (P) is momentum transfer on the walls of a container
  • For an ideal gas: P = n kB T
  • P -> 0 as T -> 0

(where n is particle density, kB is Boltzmann’s constant, and T is temperature)

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7
Q

Number of Electron States in Phase Space

A
  • For a volume V, the number of states is (V/h3) d3p · 2 spin states
  • Occupancies are determined by Fermi-Dirac statistics
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8
Q

Fermi Momentum

A

pF = (3h3/8π)1/3 ne1/3 ∝ ne1/3
where ne is electron density.

good to know that it goes as the thrid root of electron density, whether he cares about the proportionality constant is debatable in my opinon

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9
Q

Pressure of Degenerate Electrons (Non-Relativistic)

A

P = C1 ne5/3

where C1 = (33/2 h²) / (20 π2/3 me).

I dont think he would be intersted in more than that it goes as ne5/3

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10
Q

Pressure of Degenerate Electrons (Relativistic)

A

P ∝ ne4/3

here i just changed it from (reference to another footnote): **P = C₂ ne(4/3)**, where C₂ = (2²/₃ hc) / (8 π¹/₃).

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11
Q

Mass-Radius Relation for Degenerate Stars (3)

two types of degenerate asked

A
  • Equilibrium between degeneracy pressure (Pe) and gravitational pressure (PG)
  • Non-relativistic case: R is proportional to 1/M1/3
  • Relativistic electron gas: no stable solution - leads to a maximum mass limit for stable white dwarfs.
  • occurs if M ≈ 1.4 M_O
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12
Q

Chandrasekhar Mass Limit

A

The maximum mass for a stable white dwarf star is ≈ 1.4 M.

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13
Q

What relations are there (roughly) for initial masses of stars to their end state configuration?

A
  • stars less massive than about 4M eventually become white dwarfs
  • stars with initial masses in range 4M to 10M are believed to end up as neutron stars (typically after undergoing supernova explosion)
  • stars with initial masses more than 10M probabaly cannot shed enough mass to become white dwarfs or neutron stars.
  • go on contracting until gravitational attraction so stron not even light can escape = black hole configuration
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