Astronomy 82 - Problem Set #1

... degeneracy pressure instead of nuclear fusion. The maximum mass that can be supported by this pressure is 1.44 Msolar. (For each calculation, you can assume the star has uniform density.) a) If such a maximum mass white dwarf has a radius of 5400 km (slightly smaller than the Earth), what is its gra ...

Neutron Stars and Black Holes

... Black Holes in Galaxies • BHs may have formed in center when galaxy formed. • Mass of billions of stars in size of SS (Kepler’s 3rd Law). • Black hole likely in center of the Milky Way. ...

First generation stars

... uncovered evidence of a 5 keV sterile neutrino emission line in the Chandra spectrum of the ultra-faint Willman 1 dwarf spheroid. The flux of this feature is consistent with the hypothesis that neutrino oscillations in the early universe produce all of the dark matter in the form of sterile neutrino ...

Disk Galaxies: Structural Components

... • Collapse of an over-dense region of space (containing more gas and dark matter than average) under gravity • Disks are produced as the cloud of material spins faster and faster as the gravitational collapse progresses • To conserve angular momentum, the spin speed must increase inversely proportio ...

In Pictures: Journey to the Stars

... are many more in the universe. But did you know that a long, long time ago, there were no stars at all? Gravity is the force of attraction between all objects in the © AMNH ...

17. The Universe

... Our galaxy would be equivalent to the size of just one micron – that’s roughly the same size as a small piece of dust! To find the Sun, you would have to shrink down to stand on the piece of dust. It would then be like finding one particular grain of sand in a seven-metre-wide circular pool filled w ...

universe new

... Our galaxy would be equivalent to the size of just one micron – that’s roughly the same size as a small piece of dust! To find the Sun, you would have to shrink down to stand on the piece of dust. It would then be like finding one particular grain of sand in a seven-metre-wide circular pool filled w ...

Galaxy3

... super massive black hole. ...

Final for Astro 322, Prof. Heinke, April 23rd, 2010 Formula sheet

... d) Which of these features in elliptical galaxies indicate a recent merger? Explain for each feature, why it does or does not. i) Strong absorption lines of H. ii) Strong rotation. iii) “Disky” isophotes. iv) Spherical shells of stars. Problem 5: AGN & Clusters a) A distant quasar is observed to be ...

Fermi Gases

... • Leftover cores of Red Giants made (usually) from C + O nuclei and degenerate electrons • cores of very massive stars are Fe nuclei plus degenerate electrons and have similar properties • gravitational pressure balanced by electrons’ pressure which increases as radius decreases ---> radius depends ...

The Origin of the Elements edited by David L. Alles Western Washington University

... The Sun generates all of its heat in its core. This heat both warms the Earth and prevents gravity from forcing the Sun to undergo a catastrophic gravitational collapse. The fuel which supplies the heat is hydrogen. Hydrogen nuclei are converted to helium as heat is released. Five billion years from ...

Layers of the Sun (~ 75% Hydrogen ~ 25% Helium)

... Solar energy is created deep within the core of the Sun. It is here that the temperature (15,000,000° C; 27,000,000° F) and pressure (340 billion times Earth's air pressure at sea level) is so intense that nuclear reactions take place. This reaction causes four protons or hydrogen nuclei to fuse tog ...

Dark Stars: Dark Matter Annihilation in the First Stars.

... further DM is captured by the star. See also work of Fabio Iocco and Gianfranco Bertone. •  The refueling can only persist as long as the DS resides in a DM rich environment, I.e. near the center of the DM halo. But the halo merges with other objects so that a reasonable guess for the lifetime would ...

Photometric variability of the Pre

... effect of color reversal (or co-called ”blueing”) was described in many studies (Bibo & The (1990), Grinin et al. (1994)). According to the model of dust clumps obscuration the observed color reversal is caused by the scattered light from the small dust grains. Normally the star becomes redder when ...

Groupmeeting_shshiu_20090803_nuclearx

... 2) b- emitted to change neutron into proton, happens when have too many neutrons 3) b emitted (or electron captured) to change proton into neutron, happens when have too few neutrons 4) g emitted to conserve energy in reaction, may accompany a or b. ...

Slide 1

... Comprised of 2 stars in a close orbit around each other (i.e., a binary system). They are tidally locked (i.e., rotation period equals orbital period, of only days). ...

document

... NUCLEOSYNTHESIS ENDED AT THIS POINT. A CLOUD OF NUCLEI, ELECTRONS, PROTONS, AND PHOTONS EXISTED AT THIS POINT - A ...

Heading for the Pole - MNASSA Page

... end, the companion galaxy, NGC 6438A. Owing to the presence of the companion I could just about make out that the larger galaxy slowly brightens towards the centre. At both ends of these two nebulae faint pin-point stars can be seen. The 9.8 magnitude yellow GSC 9527 1029 1 forms a triangle towards ...

2006ph607chaptertwo

... The energy released by the PP chain and CNO cycle are smooth functions of temperature * the rate of fusion is a very sensitive function of temperature * fusion reactions involving successively heavier elements (in ascending order: the PP chain, the CNO cycle and the triple-alpha reaction) The fusion ...

The Search for New “r-process-Enhanced” Metal

... Timothy C. Beers Michigan State University ...

The Sun (power point) by Ms. Kimball the_sun_pp

... The Sun formed 4.5 billion years ago, as the solar system coalesced from a cloud of gas and dust. Our sun is a medium-sized yellow star that is 93,026,724 miles from the Earth. • The Earth is closest to the Sun (this is called perihelion) ...

Notes - Michigan State University

... As hydrogen is exhausted in the (convective) core of a star (point 2) it moves away from the main sequence (point 3) What happens to the star ? • lower T  redder • same L  larger (Stefan’s L.) star becomes a red giant ...

THE HISTORY OF THE UNIVERSE IN ONE EASY LESSON

... NUCLEOSYNTHESIS ENDED AT THIS POINT. A CLOUD OF NUCLEI, ELECTRONS, PROTONS, AND PHOTONS EXISTED AT THIS POINT - A PLASMA. ...

Spiral arms in the milky way galaxy and cosmic rays

... The disk is characterized with stars that move in nearly circular orbits around the galactic center. The Central Bulge is characterized with stars with large random motions. Therefore its distribution is ellipsoidal. The star in the disk has a differential velocity, meaning the star nearer to the ce ...

PoS(HTRA-IV)044 - Proceeding of science

... one by main sequence stars (including blue giants), and the bottom one by dwarf stars. Some stars are of course exceptions, but the huge amount of available stars up to V -band magnitude 16 allows to waste some of them. On the figure are also shown two K-band magnitude limits, that ensure stars abov ...

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Main sequence

In astronomy, the main sequence is a continuous and distinctive band of stars that appears on plots of stellar color versus brightness. These color-magnitude plots are known as Hertzsprung–Russell diagrams after their co-developers, Ejnar Hertzsprung and Henry Norris Russell. Stars on this band are known as main-sequence stars or ""dwarf"" stars.After a star has formed, it generates thermal energy in the dense core region through the nuclear fusion of hydrogen atoms into helium. During this stage of the star's lifetime, it is located along the main sequence at a position determined primarily by its mass, but also based upon its chemical composition and other factors. All main-sequence stars are in hydrostatic equilibrium, where outward thermal pressure from the hot core is balanced by the inward pressure of gravitational collapse from the overlying layers. The strong dependence of the rate of energy generation in the core on the temperature and pressure helps to sustain this balance. Energy generated at the core makes its way to the surface and is radiated away at the photosphere. The energy is carried by either radiation or convection, with the latter occurring in regions with steeper temperature gradients, higher opacity or both.The main sequence is sometimes divided into upper and lower parts, based on the dominant process that a star uses to generate energy. Stars below about 1.5 times the mass of the Sun (or 1.5 solar masses (M☉)) primarily fuse hydrogen atoms together in a series of stages to form helium, a sequence called the proton–proton chain. Above this mass, in the upper main sequence, the nuclear fusion process mainly uses atoms of carbon, nitrogen and oxygen as intermediaries in the CNO cycle that produces helium from hydrogen atoms. Main-sequence stars with more than two solar masses undergo convection in their core regions, which acts to stir up the newly created helium and maintain the proportion of fuel needed for fusion to occur. Below this mass, stars have cores that are entirely radiative with convective zones near the surface. With decreasing stellar mass, the proportion of the star forming a convective envelope steadily increases, whereas main-sequence stars below 0.4 M☉ undergo convection throughout their mass. When core convection does not occur, a helium-rich core develops surrounded by an outer layer of hydrogen.In general, the more massive a star is, the shorter its lifespan on the main sequence. After the hydrogen fuel at the core has been consumed, the star evolves away from the main sequence on the HR diagram. The behavior of a star now depends on its mass, with stars below 0.23 M☉ becoming white dwarfs directly, whereas stars with up to ten solar masses pass through a red giant stage. More massive stars can explode as a supernova, or collapse directly into a black hole.

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Main sequence