binary stars
... we are dealing with circular orbits in which case we measure the projected velocity Vr sini for each component. In the case of elliptical orbits, the velocity curves are no longer sinusoidal. Although radial velocity curves are mirror images, they may have differing amplitudes ...
... we are dealing with circular orbits in which case we measure the projected velocity Vr sini for each component. In the case of elliptical orbits, the velocity curves are no longer sinusoidal. Although radial velocity curves are mirror images, they may have differing amplitudes ...
The Sun and the Stars
... we are dealing with circular orbits in which case we measure the projected velocity Vr sini for each component. In the case of elliptical orbits, the velocity curves are no longer sinusoidal. Although radial velocity curves are mirror images, they may have differing amplitudes ...
... we are dealing with circular orbits in which case we measure the projected velocity Vr sini for each component. In the case of elliptical orbits, the velocity curves are no longer sinusoidal. Although radial velocity curves are mirror images, they may have differing amplitudes ...
steady flow
... As a star forms density and temperature (heat source ?) increase in its center Fusion of hydrogen (1H) is the first long term nuclear energy source that can ignite. Why ? With only hydrogen available (for example in a first generation star right after it’s formation) the ppI chain is the only possib ...
... As a star forms density and temperature (heat source ?) increase in its center Fusion of hydrogen (1H) is the first long term nuclear energy source that can ignite. Why ? With only hydrogen available (for example in a first generation star right after it’s formation) the ppI chain is the only possib ...
Stefan-Boltzmann`s law Wien`s law
... Cosmological background radiation / Cosmic microwave background radiation (CMB) is microwave radiation - left over from the Big Bang that fills the universe roughly uniformly in all directions. The Big Bang predicts an expanding universe that had a very high temperature at the beginning; during the ...
... Cosmological background radiation / Cosmic microwave background radiation (CMB) is microwave radiation - left over from the Big Bang that fills the universe roughly uniformly in all directions. The Big Bang predicts an expanding universe that had a very high temperature at the beginning; during the ...
Name: Candle Spectra Lab Objective: Students will be able to
... Explain how this lab relates to the following: a. Aurora Bourelis: ...
... Explain how this lab relates to the following: a. Aurora Bourelis: ...
galctr
... • Solution: ambipolar diffusion (assisted by turbulence in cloud or disk) What defines core masses => stellar masses? • Jeans-mass core has M~ LJ2 with LJ =(v2 + cs2)/(G ) if thermally+turbulently supported; magnetically critical 1/~ 2 G 1/2/B ; combine to obtain M crit,turb ~ v4 /(G 3/2 B) ...
... • Solution: ambipolar diffusion (assisted by turbulence in cloud or disk) What defines core masses => stellar masses? • Jeans-mass core has M~ LJ2 with LJ =(v2 + cs2)/(G ) if thermally+turbulently supported; magnetically critical 1/~ 2 G 1/2/B ; combine to obtain M crit,turb ~ v4 /(G 3/2 B) ...
Contemporary Physics - Department of Physics and Astronomy
... apparent magnitude of a star as we see it? Is Proxima Centauri smaller in diameter than the Sun, or larger? ...
... apparent magnitude of a star as we see it? Is Proxima Centauri smaller in diameter than the Sun, or larger? ...
Standard EPS Shell Presentation
... Describe how the composition and size of planets is related to their formation and proximity to the sun. Identify the structure of the Milky Way Galaxy and the location of our solar system within the galaxy. Explain how astronomers measure the distance to stars and ...
... Describe how the composition and size of planets is related to their formation and proximity to the sun. Identify the structure of the Milky Way Galaxy and the location of our solar system within the galaxy. Explain how astronomers measure the distance to stars and ...
exam1guide - Chemistry at Winthrop University
... There will be at three metric conversion questions, as well as questions about the metric system of measurement. Please see the sample test questions document for example questions. Scientific Methods: the definition and purpose of science, scientific accuracy, the natural world, “the” scientific me ...
... There will be at three metric conversion questions, as well as questions about the metric system of measurement. Please see the sample test questions document for example questions. Scientific Methods: the definition and purpose of science, scientific accuracy, the natural world, “the” scientific me ...
–1– 1. Stellar Evolution For Massive Stars 1.1. The Importance of
... that are more compact, with smaller radii, than solar Z stars. A 0Z 20M ⊙ star has a radius 3.5 times smaller than that of star with the same mass at Solar Z. A smaller radius leads to a shorter timescale to mix from center to surface for a given value of the diffusion coefficient, and to steeper gr ...
... that are more compact, with smaller radii, than solar Z stars. A 0Z 20M ⊙ star has a radius 3.5 times smaller than that of star with the same mass at Solar Z. A smaller radius leads to a shorter timescale to mix from center to surface for a given value of the diffusion coefficient, and to steeper gr ...
Chapter 10: The Stars
... • 8. Why doesn’t stellar parallax work to find distances to all stars? • As the stars get further away, the parallax angle gets smaller (and the apparent shift gets smaller). At distances beyond a few hundred light years, the angle and apparent shift are so small we can’t ...
... • 8. Why doesn’t stellar parallax work to find distances to all stars? • As the stars get further away, the parallax angle gets smaller (and the apparent shift gets smaller). At distances beyond a few hundred light years, the angle and apparent shift are so small we can’t ...
Name
... 11. Explain the big bang theory in as much detail as possible. Make sure you answer the following questions: 1. Is the universe expanding or getting smaller? 2. What evidence did the WMAP provide scientists about the big bang theory? 3. Is the universe cooling or getting hotter? 4. How has the amou ...
... 11. Explain the big bang theory in as much detail as possible. Make sure you answer the following questions: 1. Is the universe expanding or getting smaller? 2. What evidence did the WMAP provide scientists about the big bang theory? 3. Is the universe cooling or getting hotter? 4. How has the amou ...
Astronomy Study Guide
... Named for their round appearance When a medium - mass star, like our sun, runs out of its fuel the outer shell of the star drifts out and leaves a very dense, white hot star. The light from this star illuminates the nebula. ...
... Named for their round appearance When a medium - mass star, like our sun, runs out of its fuel the outer shell of the star drifts out and leaves a very dense, white hot star. The light from this star illuminates the nebula. ...
Lecture 18
... d) Perhaps massive stars don’t form from one collapsing cloud, but instead form from collisions of smaller stars? Idea: stars today never collide, but collisions would be more frequent: • In young clusters where stars form, which are much denser than the Galaxy in the Solar neighborhood. • Young st ...
... d) Perhaps massive stars don’t form from one collapsing cloud, but instead form from collisions of smaller stars? Idea: stars today never collide, but collisions would be more frequent: • In young clusters where stars form, which are much denser than the Galaxy in the Solar neighborhood. • Young st ...
script
... the stellar atmosphere. Because the convection zone for main sequence stars is not as deep, the „polluted“ layers survive for some time. For giant stars that have a deep convection zone, this polluted layer gets mixed and one does not see a higher metal content. ...
... the stellar atmosphere. Because the convection zone for main sequence stars is not as deep, the „polluted“ layers survive for some time. For giant stars that have a deep convection zone, this polluted layer gets mixed and one does not see a higher metal content. ...
Transcript - Chandra X
... Mira variable stage of evolution. The end products of these stars are located on the white dwarf in the lower left quadrant of the diagram as they are hot but also extremely dim as they are very compact. Slide 15: Omicron Ceti is also known as Mira. Mira is the prototype of all Mira variable stars. ...
... Mira variable stage of evolution. The end products of these stars are located on the white dwarf in the lower left quadrant of the diagram as they are hot but also extremely dim as they are very compact. Slide 15: Omicron Ceti is also known as Mira. Mira is the prototype of all Mira variable stars. ...
Slide 1
... Main-Sequence Stars Mmax ~ 100 solar masses a) More massive clouds fragment into smaller pieces during star formation. b) Very massive stars lose mass in strong stellar winds ...
... Main-Sequence Stars Mmax ~ 100 solar masses a) More massive clouds fragment into smaller pieces during star formation. b) Very massive stars lose mass in strong stellar winds ...
nuclear fusion
... nuclei falling in from outer shells stopped, partially disrupted made to bounce back as fragments release of p, n, high energy collisions ...
... nuclei falling in from outer shells stopped, partially disrupted made to bounce back as fragments release of p, n, high energy collisions ...
ph507-16-4form
... Massive Stars & Clusters: Massive stars should not form: hydrogen burning begins while accreting: radiation pressure should resist the infall. Accretion must be high and through a disk: to suffocate the feedback. Massive stars create hot molecular cores, masers, compact/extended H II ...
... Massive Stars & Clusters: Massive stars should not form: hydrogen burning begins while accreting: radiation pressure should resist the infall. Accretion must be high and through a disk: to suffocate the feedback. Massive stars create hot molecular cores, masers, compact/extended H II ...
Stellar evolution
Stellar evolution is the process by which a star changes during its lifetime. Depending on the mass of the star, this lifetime ranges from a few million years for the most massive to trillions of years for the least massive, which is considerably longer than the age of the universe. The table shows the lifetimes of stars as a function of their masses. All stars are born from collapsing clouds of gas and dust, often called nebulae or molecular clouds. Over the course of millions of years, these protostars settle down into a state of equilibrium, becoming what is known as a main-sequence star.Nuclear fusion powers a star for most of its life. Initially the energy is generated by the fusion of hydrogen atoms at the core of the main-sequence star. Later, as the preponderance of atoms at the core becomes helium, stars like the Sun begin to fuse hydrogen along a spherical shell surrounding the core. This process causes the star to gradually grow in size, passing through the subgiant stage until it reaches the red giant phase. Stars with at least half the mass of the Sun can also begin to generate energy through the fusion of helium at their core, whereas more-massive stars can fuse heavier elements along a series of concentric shells. Once a star like the Sun has exhausted its nuclear fuel, its core collapses into a dense white dwarf and the outer layers are expelled as a planetary nebula. Stars with around ten or more times the mass of the Sun can explode in a supernova as their inert iron cores collapse into an extremely dense neutron star or black hole. Although the universe is not old enough for any of the smallest red dwarfs to have reached the end of their lives, stellar models suggest they will slowly become brighter and hotter before running out of hydrogen fuel and becoming low-mass white dwarfs.Stellar evolution is not studied by observing the life of a single star, as most stellar changes occur too slowly to be detected, even over many centuries. Instead, astrophysicists come to understand how stars evolve by observing numerous stars at various points in their lifetime, and by simulating stellar structure using computer models.In June 2015, astronomers reported evidence for Population III stars in the Cosmos Redshift 7 galaxy at z = 6.60. Such stars are likely to have existed in the very early universe (i.e., at high redshift), and may have started the production of chemical elements heavier than hydrogen that are needed for the later formation of planets and life as we know it.