Gregory Gabadadze (NYU, CCPP) with R. A. Rosen, JCAP, JHEP 08,09 D. Pirtskhalava, JCAP 09.

Slides:

Advertisements

Similar presentations

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.

Advertisements

Nuclear Interactions in Supernovae By: Alec Fisher 11/14/2012.

Life Cycle of Stars. Omega / Swan Nebula (M17) Stars are born from great clouds of gas and dust called Stars are born from great clouds of gas and dust.

THE LIFE OF A STAR

Life Cycle of Stars. Birth of a Star Born from interstellar matter (dust & gases) – Denser portions of the nebula Nebula begins to contract – Due to gravity.

Sam Wilmarth PHYS 43 Younes Ataiiyan SRJC SPRING 2011 Stellar Evolution.

LECTURE 19, NOVEMBER 4, 2010 ASTR 101, SECTION 3 INSTRUCTOR, JACK BRANDT 1ASTR 101-3, FALL 2010.

Life Cycle of a Star Based on Mass of Star. All Stars – Stage 1-Nebula Gravity main force, pulls cloud INWARD. Temperature = INCREASES Gravity based on.

Supernova. Explosions Stars may explode cataclysmically. –Large energy release (10 3 – 10 6 L  ) –Short time period (few days) These explosions used.

 When found in stars between 8 and 25x M sun, what happens to the core?  Cores are stopped by the outer layers of the star  Cores recontract and remain.

The Evolution of Stars - stars evolve in stages over billions of years 1.Nebula -interstellar clouds of gas and dust undergo gravitational collapse and.

White Dwarfs and Neutron Stars White dwarfs –Degenerate gases –Mass versus radius relation Neutron stars –Mass versus radius relation –Pulsars, magnetars,

P461 - Quan. Stats. II1 Boson and Fermion “Gases” If free/quasifree gases mass > 0 non-relativistic P(E) = D(E) x n(E) --- do Bosons first let N(E) = total.

Lecture 25 Practice problems Boltzmann Statistics, Maxwell speed distribution Fermi-Dirac distribution, Degenerate Fermi gas Bose-Einstein distribution,

Neutron Stars and Black Holes PHYS390: Astrophysics Professor Lee Carkner Lecture 18.

P460 - Quan. Stats. III1 Nuclei Protons and neutrons in nuclei separately fill their energy levels: 1s, 1p, 1d, 2s, 2p, 2d, 3s…………… (we’ll see in 461 their.

What is the Lifecycle of a Star? Chapter Stars form when a nebula contracts due to gravity and heats up (see notes on formation of the solar system).

Fermi-Dirac distribution and the Fermi-level

Lecture 10 Energy production. Summary We have now established three important equations: Hydrostatic equilibrium: Mass conservation: Equation of state:

Overview of Astronomy AST 200. Astronomy Nature designs the Experiment Nature designs the Experiment Tools Tools 1) Imaging 2) Spectroscopy 3) Computational.

Stellar Evolution. Clouds of gas and dust are floating around in space These are called “nebula”

Life Cycle of Stars. Stars are born in Nebulae Vast clouds of gas and dust Composed mostly of hydrogen and helium Some cosmic event triggers the collapse.

Pg. 12.  Mass governs a star’s properties  Energy is generated by nuclear fusion  Stars that aren’t on main sequence of H-R either have fusion from.

Can you guess why I am showing you this picture?

JP ©1 2 3 Stars are born, grow up, mature, and die. A star’s mass determines its lifepath. Let M S = mass of the Sun = ONE SOLAR MASS Stellar Evolution.

Stars 1.Measuring/Distances to stars 2.Stars aren’t always “there”. They live, they die, we will learn that cycle. 3.Properties of stars: color, brightness,

Stars Chapter 25. The Sun The Sun’s mass controls the motions of the planets Less dense than Earth High pressure and temperature causes gases to be plasma.

Unconventional superconductivity Author: Jure Kokalj Mentor: prof. dr. Peter Prelovšek.

IRGAC 2006 COLOR SUPERCONDUCTIVITY and MAGNETIC FIELD: Strange Bed Fellows in the Core of Neutron Stars? Vivian de la Incera Western Illinois University.

Life Cycle of Stars Nebula hundreds of light years in size contract under gravity

Life Cycle of Stars Birth Place of Stars:

The Life Cycle of a Star By Andy Kimmelshue. The birth of a star Stars are formed from gas and dust pulled together by gravity inside of a Nebula. A.

Star Life Cycle Review. Transports energy from the radiative zone to the surface of the sun. Sunspot Corona Photosphere Convective zone.

Recap: Death of Stars: Low and Medium Mass Red Giant Main Sequence Star Planetary Nebula White Dwarf Black Dwarf ?? Red Dwarf Low Mass Medium Mass.

The Sun Distance from Earth: 150 million km OR 93 million miles Size: 1.4 million km in diameter Age: 4.5 billion years old, halfway through its 10 billion.

Some theoretical aspects of Magnetars Monika Sinha Indian Institute of Technology Jodhpur.

Physics 55 Monday, November 14, Quiz 6 2.The evolution of low-mass and high-mass stars. 3.Where elements come from: nucleosynthesis. 4.Corpses of.

E5 stellar processes and stellar evolution (HL only)

Stars Earth Science – Mr. Foster. Why do stars exist? Stars exist because of gravity Two opposing forces in a star are – Gravity – contracts – Thermal.

Life Cycle of a Star Notes Write in Cornell Notes format.

High Energy Observational Astrophysics. 1 Processes that emit X-rays and Gamma rays.

Stellar Evolution (Star Life-Cycle). Basic Structure Mass governs a star’s temperature, luminosity, and diameter. In fact, astronomers have discovered.

1. Where Are We?? We live in the Milky Way Galaxy, which is one of at least billion (maybe up to !) galaxies in the universe. The Milky.

Death of sun-like Massive star death Elemental my dear Watson Novas Neutron Stars Black holes $ 200 $ 200$200 $ 200 $ 200 $400 $ 400$400 $ 400$400.

Stellar Evolution Life Cycle of stars.

12-2 Notes How Stars Shine Chapter 12, Lesson 2.

Handout 2-1a Stellar Evolution.

Star Formation - 6 (Chapter 5 – Universe).

Stellar Evolution Pressure vs. Gravity.

Lecture 25 Practice problems

Stars: Old Age, Death, and New Life

Fermi Gas Distinguishable Indistinguishable Classical degenerate depend on density. If the wavelength.

8 Space physics Topic overview

Solar system Orbital motions AQA SPACE PHYSICS PHYSICS ONLY Red shift

STARS Essential Questions.

Middleweight Stars 4-12 solar masses.

Star Life Cycle Review.

Neutron Stars Aree Witoelar.

White Dwarfs and Neutron Stars

The Lives of Stars.

Life Cycle of a Star.

The Sun and the Life of Stars

Fusion Reactions in the Sun

The Sun and the Life of Stars

Astronomy Chapter VII Stars.

Supernova’s By Blake Sharin.

Solar system Orbital motions AQA SPACE PHYSICS PHYSICS ONLY Red shift

Presentation transcript:

Gregory Gabadadze (NYU, CCPP) with R. A. Rosen, JCAP, JHEP 08,09 D. Pirtskhalava, JCAP 09

d -- average interparticle separation 1 Fermi << d << 1 Angstrom ??? 10 eV < T << 10 KeV.. He or C nuclei and Electrons

Crystallization temperature To crystallize

Temperature at which thermal de Broglie wavelengths begin to overlap Uncertainties in particle position as large as inter-particle separation Critical Temperature Critical T > Crystallization T => Charged Condensation!

Heavier Stars End Up Either As Neutron Stars Or As Black Holes Relatively Light Stars End Up As White Dwarfs Typical density:

versus Outward Directed Electron Pressure Inward Directed Gravitational Pull What Keeps White Dwarfs Stable? Electrons -Nuclei +

Standard Theory: Carbon, Oxygen, …, Containing WD’s Crystallize As they Cool Down (Mestel, Ruderman) Specific heat dominated by the crystal phonon contribution Cooling time: ~10 Gyr

Helium White Dwarfs In Binary Systems solar mass dwarfs with helium core

Some characteristics for helium white dwarfs

Average carbon white dwarf

Building up effective field theory Order parameter: complex scalar U(1) symmetries for scalars and fermions Rotational symmetry Galilean invariance Schrodinger equation in the lowest order..

Effective Order Parameter Lagrangian for Charged Condensation Greiter, Wilczek,Witten in BCS superconductivity Solution

Small perturbations (simplified)

Spectrum of small perturbations Phonon contribution to specific heat:

Impurity Interactions (H, He3,…)

Gap-less Fermion Excitations

Gap-less Fermions and Phonon

White dwarf cooling

Magnetic Vortices in Superconductors and White Dwarfs Rotation and Magnetic Properties of Helium White Dwarfs

Magnetic flux lines

Magnetic Flux Lines

Critical Magnetic Field Disruption of Condensate

London Magnetic Field

Conclusions and Outlook Charge Condensate – new state of matter in the Universe Fast cooling of helium white dwarfs (super-massive carbon dwarfs ?) Magnetic field in flux tubes, high critical field; small London field Other possible applications: neutron star crust,…???