The Stellar Graveyard

... place. Since the electrons are packed so tightly together, they are always at the “same place” and therefore all the lower energy states of the electron gas are filled. The left over electrons (and there are lots of them) have no choice but to occupy a higher energy state. This causes their velocity ...

MBuzaTalk2

... Varying densities causes pressure build up, and then the ‘bounce’ (degenerate core), the star violently ejects large amounts of the star into space. ...

Scope and Sequence for Classifying Matter

... -name something you can see that isn’t made of matter – a shadow ...

Chemistry Notes

... and Neutrons. a) Proton – Positively charged particles. b) Neutron – Neutral particles. C. For the Elements, the number of electrons in an atom is equal to the number of Protons. This is called the Atomic Number. ...

Chemistry I Unit Review: The Atom Text Chapters 2 and 7 1. The

... Determine the number of valence electrons and draw the dot diagram for the following atoms: ...

PHYS 390 Lecture 29 - White dwarfs and neutron stars 29

... luminosity just 0.03 that of our Sun. These observations can be taken together to paint a picture of an altogether different type of star than the Sun: • luminosity + temperature give a radius of 0.008 solar radii, about the size of the Earth; thus, the average density is (0.008)-3 = 2,000,000 times ...

Statistical Mechanics, Subject Examination September 6, 2006

... (a) Estimate the mean distance between the helium nuclei. (b) Derive a formula for the mean energy of the electrons, assuming the extreme relativistic limit. Why is this limit justified? (c) Do likewise for the helium nuclei. Is the extreme relativistic limit justified? How does their contribution t ...

PPT

...  Higher core temperature causes outer layers begin to expand, cool off and turn reddish in color : become Red Giants ...

–1– Order of Magnitude Astrophysics

... A star is a massive, luminous ball of plasma held together by gravity. ...

Chapter 16

... Additionally, the mass-radius relation for W.D. is M R3 = constant, which means that as the mass increases, the size decreases! ...

13. The Equation of State

... Pauli Exclusion Principle: no more than one fermion of a given spin state can occupy a given phase-space element h3 . Hence, for electrons, which have g = 2, the maximum phase-space density is 2/h3 . Degeneracy: When compressing and/or cooling a fermionic gas, at some point all possible low momentum ...

White Dwarf Stars

... • Low mass stars are unable to reach high enough temperatures to ignite elements heavier than carbon in their core become white dwarfs. • Hot exposed core of an evolved low mass star. ...

White Dwarf Stars - University of California Observatories

... • A white dwarf is the hot exposed core of an evolved low mass star. • A white dwarf is supported by electron degeneracy pressure. This is the tendency of atoms to resist compression. • The more massive a white dwarf, the smaller it is. A solar mass white dwarf is about the size of the Earth. ...

Topics for Final

... Diffusion vs. effusion ...

Prep Homework Solutions for HW due 10/04/10

... evolved star, but normally we think of binaries as stars born together and we expect higher-mass stars to evolve faster. The resolution of the paradox is presumed to be that the red giant in Algol used to be the more massive star, and it evolved off the Main Sequence before its companion, but then i ...

Lecture 18

... • Gas pressure gets less and less as the very hot core radiates away its heat...why doesn't the star collapse to a point (a 'singularity', or black hole?) – Because another pressure, besides gas pressure or radiation pressure, takes over ...

Neutron Stars

... – Then the electrons and protons can combine under this pressure and transform into neutrons. – Pulsars – rotating neutron stars ...

here

... A9: Consider the following mental experiment. Take a gas of mass M and confine it by some force into a certain volume V . In a main sequence star, that force is given by the selfgravity, and the volume will adjust itself to a certain equilibrium value where gas pressure balances gravity. The existen ...

What stars do Summary: Nuclear burning in stars •

... Sufficiently high density  Electron degeneracy. ...

Planetary Configurations

... be crammed into a given space (particles with “personal space”). • When densities approach this limit, matter becomes “degenerate”. • Gas pressure depends on density only, and not temperature. ...

Lecture20 - University of Waterloo

...  Given its low luminosity, it must be very small ...

Lecture 23 - White Dwarfs and Neutron Stars

... • Only two electrons (one up, one down) can go into each energy level. • In a degenerate gas, all low energy levels are filled. • Electrons have energy, and therefore are in motion and exert pressure even if temperature is zero. • White dwarfs are supported by electron degeneracy. ...

Neutron Star

... • When the mass of the core is greater than 1.4 M, electrons cannot support the gravitational force. • This is the Chandrasekar limit: beyond that it’s supernova. ...

Comparing Earth, Sun and Jupiter

... smaller than this, the density would be >5.0x1010 kg/m3, and it would have to be a neutron star. b. How fast can a star rotate before it breaks up? Equate centripetal and gravitational accelerations: ...

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Degenerate matter

Degenerate matter in physics is a collection of free, non-interacting particles with a pressure and other physical characteristics determined by quantum mechanical effects. It is the analogue of an ideal gas in classical mechanics. The degenerate state of matter, in the sense of deviant from an ideal gas, arises at extraordinarily high density (in compact stars) or at extremely low temperatures in laboratories. It occurs for matter particles such as electrons, neutrons, protons, and fermions in general and is referred to as electron-degenerate matter, neutron-degenerate matter, etc. In a mixture of particles, such as ions and electrons in white dwarfs or metals, the electrons may be degenerate, while the ions are not.In a quantum mechanical description, free particles limited to a finite volume may take only a discrete set of energies, called quantum states. The Pauli exclusion principle prevents identical fermions from occupying the same quantum state. At lowest total energy (when the thermal energy of the particles is negligible), all the lowest energy quantum states are filled. This state is referred to as full degeneracy. The pressure (called degeneracy pressure or Fermi pressure) remains nonzero even near absolute zero temperature. Adding particles or reducing the volume forces the particles into higher-energy quantum states. This requires a compression force, and is made manifest as a resisting pressure. The key feature is that this degeneracy pressure does not depend on the temperature and only on the density of the fermions. It keeps dense stars in equilibrium independent of the thermal structure of the star.Degenerate matter is also called a Fermi gas or a degenerate gas. A degenerate state with velocities of the fermions close to the speed of light (particle energy larger than its rest mass energy) is called relativistic degenerate matter.Degenerate matter was first described for a mixture of ions and electrons in 1926 by Ralph H. Fowler, showing that at densities observed in white dwarfs the electrons (obeying Fermi–Dirac statistics, the term degenerate was not yet in use) have a pressure much higher than the partial pressure of the ions.

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Degenerate matter