jan0605

... The Sun lies in a relatively low density region, diameter ~300 l.y. Average stellar separation ~ 3 l.y. Almost all stars known to have planets lie within 100 l.y. of the Sun ...

The Galactic Halo

... order of 10-100 Mo undergoing mixing and fallback, or rapidly rotating mega metal-poor (MMP; [Fe/H] < -6.0) stars, both of which eject large amount of CNO, but little heavy metals. Low-mass stars formed with the help of C, O cooling Stars with “normal” carbon and light-element abundances, apparently ...

Soal Short

... Earth (t2). Let T eff  be the effective temperature of the Sun, R the radius of the Sun, r the radius of the Earth, and x the distance between the Sun and the Earth. Derive the temperature of the Earth’s surface as a function of the aforementioned parameters. ...

Which Stars Form Black Holes and Neutron Stars?

... supergiants, and a luminous blue variable [23, 18, 21].2 Red supergiants have not yet formed, which suggests that the cluster is 3.0–4.5 Myr old, and that the progenitor to the magnetar had an initial mass of >50 M⊙ . Likewise, SGR 1900+14 is a member of an anonymous star cluster that is probably <2 ...

ET_at_Science_Cafe

... class of variable stars, notable for tight correlation between their period of variability and absolute luminosity. • Namesake and prototype of these variables is the star Delta Cephei, discovered to be variable by John Goodricke in 1784. • This correlation was discovered and stated by Henrietta Swa ...

ppt

... • In general it is not possible to uncover the inclination angle. However, for large samples of a given type of star it may be appropriate to take the average inclination to determine the ...

RAPID MASS ACCRETION IN THE SYMBIOTIC STAR AG DRA T

... The temperature of the hot component of AG Dra in the quiescent stage is about 150000 K which is derived from the intensities of He H 4686 and He 14471 relative to Hg obtained on August 5, 1980 (Blair et al., 1983) using the formula of Iijima (1982). The luminosity of the hot component in the ultrav ...

–1– 1. Polytropes – Derivation and Solutions of the Lane

... for estimates of various quantities. They are much simpler to manipulate than the full rigorous solutions of all the equations of stellar structure. But the price of this simplicity is assuming a power law relationship between pressure and density which must hold (including a fixed constant) through ...

Earth and Beyond - We can`t sign you in

... Summary activities ...

No Slide Title

... m - M = 5 log (d/ 10pc) = 5 log (0.1” / parallax) This gave accurate distances to ~few*100 pc. ...

Lecture 13 Presupernova Models, Core Collapse and Bounce

... Original model due to Miyaji et al (1980). Studied many times since. A similar evolution may occur for accreting Ne-O white dwarfs (or very rapidly accreting CO-white dwarfs) in binary systems - an alternate outcome to Type Ia supernovae. This phenomena in a binary is generally referred to as Accre ...

Sco

... Be stars are rapidly rotating non-supergiant objects of spectral type B that sometimes show hydrogen emission lines in their spectra ...

galaxy phenomenology

... sorted by absolute magnitude in the horizontal direction, ranging between Mr − 5 log10 h ∼ −18.5 and −22 from left to right, and g − r color in the vertical direction, ranging between 0.2 and 0.9 mag from the bottom to the top. Thus, the brightest, reddest spirals are in the upper-right. The galaxie ...

Document

... spectral line profiles & energy distribution, so we may still study convection observationally Simplest example of velocity field: stellar rotation Small for “cool” stars, large for “hot” stars ...

The Virial Theorem - Harvard-Smithsonian Center for Astrophysics

... circular orbit T = 2πr/vc = (3π/Gρ)1/2 ...

Galaxies - science1d

... •The most distant galaxies are 15 million ly away •When light left them, the ...

Lab: Heliocentric Parallax

... 1. Calculate the amount that each star has moved horizontally (in grid units) and fill in the X2-X1 column 2. Calculate the amount that each star has moved vertically (in grid units) and fill in the ...

Physics from Creation to Collapse

... One possibility is a big crunch where the universe eventually contracts back into a point of infinite density. A universe with such a future would be described as being A closed. B critical. C flat. D open. (Total for Question 3 = 1 mark) ...

Question paper

... One possibility is a big crunch where the universe eventually contracts back into a point of infinite density. A universe with such a future would be described as being A closed. B critical. C flat. D open. (Total for Question 3 = 1 mark) ...

MS Word version

... Question 4: What is the latitude of the observer in the horizon diagram to the right? (Circle N or S) a) 0° b) 20° N / S c) 45° N / S d) 75° N / S e) 90° N / S ...

What is the biggest star? - University of Central Lancashire

... The Gemini telescope in Chile was 8 meters in diameter, all the way across. We are not building telescopes that are 30 meters in diameter so imagine what we can see with them! How hot is the biggest star? The biggest star is called R136a1 and is about 10 times hotter than the Sun on the surface, but ...

Finding the Mass of an Exoplanet

... Written by: Joey Chatelain, Jeremy Jones, and Ryan Sketch ...

Dynamics

... reflect the forces that act between its component stars in the same way that the structure of a crystal reflects the nature of interatomic forces. Galaxies and crystals have strongly contrasting large-scale properties because a galaxy is held together by a force that has very different properties fr ...

Dark Matter Mathematics

... What is Dark Matter?  Baryonic (Normal) Matter: Low mass stars, brown dwarfs (likely), large planets, meteoroids, black holes, neutron stars, white dwarfs, hydrogen snowballs, clouds in halo.  Non-Baryonic (Exotic) Matter: Hot Dark Matter: fast-moving at time of galaxy formation, eg massive neu ...

Coronal Mass Ejections and Angular Momentum Loss in Young Stars

... disks? In Aarnio et al. (2010), we did not find evidence for this. Second, if there is not a star-disk link, how do the loops remain stable for the multiple rotation periods over which the X-ray flares are observed to decay? We showed in Aarnio et al. (2012) that when modeled as hot prominences, the ...

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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