The Big Bang
... the galaxies in the universe were red shifted? 2. In order to analyze starlight, astronomers direct it through ____________________. 3. The idea that all matter and energy was compressed into a small volume at one time billions of years ago and then exploded and began to expand is called ___________ ...
... the galaxies in the universe were red shifted? 2. In order to analyze starlight, astronomers direct it through ____________________. 3. The idea that all matter and energy was compressed into a small volume at one time billions of years ago and then exploded and began to expand is called ___________ ...
Lecture 12- Stars: Distances and Magnitudes
... • Apparent magnitude is the brightness of an object as it appears to you • System due to Hipparchos (2nd century BC) • Nowadays system made more precise • Magnitude changes are “logarithmic”, each magnitude means factor of 2.512 in brightness • Brightness in magnitudes in Table 16.1 • Apparent magni ...
... • Apparent magnitude is the brightness of an object as it appears to you • System due to Hipparchos (2nd century BC) • Nowadays system made more precise • Magnitude changes are “logarithmic”, each magnitude means factor of 2.512 in brightness • Brightness in magnitudes in Table 16.1 • Apparent magni ...
2006ph607chapterone
... The whole system is in equilibrium if this equation is valid at all radii. * Eq. (1.4) implies that the pressure gradient must be negative, or in other words, pressure decreases from the inner central region to the outer region * The three quantities m, r, are not independent 2.2 From Hydrostatic ...
... The whole system is in equilibrium if this equation is valid at all radii. * Eq. (1.4) implies that the pressure gradient must be negative, or in other words, pressure decreases from the inner central region to the outer region * The three quantities m, r, are not independent 2.2 From Hydrostatic ...
The Death of Massive Stars
... • M-class stars may remain protostars for hundreds of millions of years. • G stars (like the Sun) spend about 30 million years in the protostar phase. • Massive O- and B-type stars may spend only 100,000 years as protostars before joining the main sequence. • Evolutionary track is the path on the H- ...
... • M-class stars may remain protostars for hundreds of millions of years. • G stars (like the Sun) spend about 30 million years in the protostar phase. • Massive O- and B-type stars may spend only 100,000 years as protostars before joining the main sequence. • Evolutionary track is the path on the H- ...
Structure of the Sun
... 1) Enormous pressure and high temperatures of the sun’s core cause the atoms to separate into nuclei and electrons. 2) In the core (unlike on Earth), the energy and pressure strip electrons away from the atomic nuclei. 3) The nuclei have positive charges, so they tend to push away from each other. S ...
... 1) Enormous pressure and high temperatures of the sun’s core cause the atoms to separate into nuclei and electrons. 2) In the core (unlike on Earth), the energy and pressure strip electrons away from the atomic nuclei. 3) The nuclei have positive charges, so they tend to push away from each other. S ...
Explore the Galaxy - Museum of Science, Boston
... White Dwarf- The incredibly dense remnant of a star of low or medium mass (roughly 0.07 to 10 times the mass of the Sun). After a star has burned through its hydrogen supply, a star of this size will shed its outer layers as a planetary nebula, leaving the dense core behind, which will become the wh ...
... White Dwarf- The incredibly dense remnant of a star of low or medium mass (roughly 0.07 to 10 times the mass of the Sun). After a star has burned through its hydrogen supply, a star of this size will shed its outer layers as a planetary nebula, leaving the dense core behind, which will become the wh ...
Standard Solar/Stellar Model
... • Like all stars, the Sun’s energy is generated by thermonuclear reactions in its core, where temperature, density and pressure are Q: why only in the core? tremendously high to push light atoms to fuse into heavy ones, e.g., hydrogen fusion. Energy release by mass loss: E = Δmc2 • Neither Kelvin- ...
... • Like all stars, the Sun’s energy is generated by thermonuclear reactions in its core, where temperature, density and pressure are Q: why only in the core? tremendously high to push light atoms to fuse into heavy ones, e.g., hydrogen fusion. Energy release by mass loss: E = Δmc2 • Neither Kelvin- ...
Binary Stars/Star Clusters
... The faster the source, the more compression/stretching Sound: frequency (pitch) of a siren gets higher as ambulance moves toward an observer (vice versa) MPP©2004 ...
... The faster the source, the more compression/stretching Sound: frequency (pitch) of a siren gets higher as ambulance moves toward an observer (vice versa) MPP©2004 ...
Light and the Electromagnetic Spectrum Problems
... Milky Way, but they are taken at different wavelengths. 6. Which types of telescopes would be used to look for high energy wavelengths and which types of telescopes would be used to look for low energy wavelengths? ...
... Milky Way, but they are taken at different wavelengths. 6. Which types of telescopes would be used to look for high energy wavelengths and which types of telescopes would be used to look for low energy wavelengths? ...
The age–metallicity distribution of earth-harbouring stars
... • The relation between age and metallicity is very tight and agrees with the general predictions of the chemical evolution theory. • The Sun is more metalrich than 85% of its coeval stars. • Direct spectroscopic findings of terrestrial planets would be more efficient if young stars (having 3 t ...
... • The relation between age and metallicity is very tight and agrees with the general predictions of the chemical evolution theory. • The Sun is more metalrich than 85% of its coeval stars. • Direct spectroscopic findings of terrestrial planets would be more efficient if young stars (having 3 t ...
What is np?
... Differences of Stars to Life 3.! Length of time on the main sequence. We needed temperature stability for 5 billion years to get intelligence on Earth. This rules out stars more massive than 1.25 solar masses! 90% of all stars are less massive than that. http://mjbs.org/hr.jpg ...
... Differences of Stars to Life 3.! Length of time on the main sequence. We needed temperature stability for 5 billion years to get intelligence on Earth. This rules out stars more massive than 1.25 solar masses! 90% of all stars are less massive than that. http://mjbs.org/hr.jpg ...
Document
... • There are several distinct phases in the life cycle of a star. The evolutionary path depends on the initial mass of the star. • Although there is a continuous range of masses, there are 4 ranges of masses that capture all of the interesting features. ...
... • There are several distinct phases in the life cycle of a star. The evolutionary path depends on the initial mass of the star. • Although there is a continuous range of masses, there are 4 ranges of masses that capture all of the interesting features. ...
Lecture 12: Age, Metalicity, and Observations Abundance
... non-α elements into the ISM MW bulge formed fast and early, before the disc. ...
... non-α elements into the ISM MW bulge formed fast and early, before the disc. ...
Solution key
... ___C___9. A star moves horizontally and to the right on an HR diagram. Which is true? A. Surface temperature decreases and radius decreases B. Surface temperature increases and radius decreases C. Surface temperature decreases and radius increases D. Surface temperature increases and radius increase ...
... ___C___9. A star moves horizontally and to the right on an HR diagram. Which is true? A. Surface temperature decreases and radius decreases B. Surface temperature increases and radius decreases C. Surface temperature decreases and radius increases D. Surface temperature increases and radius increase ...
ultracam observations of pulsating sdB stars
... horizontal branch stars and normal stellar evolution Post-GB and He-flash He-burning core 0.5 M H-rich envelope 0.4 M/ metal-rich - red HB 0.2 M/ metal-poor - blue HB 0. - .05 M - EHB / sdB Problems: How does RGB star lose its entire H envelope? How does it still suffer Heflash? ...
... horizontal branch stars and normal stellar evolution Post-GB and He-flash He-burning core 0.5 M H-rich envelope 0.4 M/ metal-rich - red HB 0.2 M/ metal-poor - blue HB 0. - .05 M - EHB / sdB Problems: How does RGB star lose its entire H envelope? How does it still suffer Heflash? ...
PH607 The Physics of Stars
... Convection will occur if temperature gradient exceeds a certain multiple of the pressure gradient. The criterion for convection derived above can be satisfied in two ways : a) The ratio of specific heats, , is close to unity In the cool outer layers of a star, the gas is only partially ionized, muc ...
... Convection will occur if temperature gradient exceeds a certain multiple of the pressure gradient. The criterion for convection derived above can be satisfied in two ways : a) The ratio of specific heats, , is close to unity In the cool outer layers of a star, the gas is only partially ionized, muc ...
Scholarship Earth and Space Science (93104) 2015
... Zero degrees Kelvin (K) = –273 degrees Celsius (°C), 0°C = 273 K. The melting point of water is 0°C and that of methane is –183°C at one atmosphere pressure. The boiling point of water is 100°C and that of methane is –161°C at one atmosphere pressure. The Sun’s surface temperature is about 5800 K, a ...
... Zero degrees Kelvin (K) = –273 degrees Celsius (°C), 0°C = 273 K. The melting point of water is 0°C and that of methane is –183°C at one atmosphere pressure. The boiling point of water is 100°C and that of methane is –161°C at one atmosphere pressure. The Sun’s surface temperature is about 5800 K, a ...
March 2016 star chart
... Golden Jupiter appears in the east at dusk, the brightest 'star' in the sky. At midnight it is due north. By dawn it is low in the west. Bright stars are overhead and down into the southeast evening sky. Jupiter is the biggest planet by far. Its mass is greater than all the other planets put togethe ...
... Golden Jupiter appears in the east at dusk, the brightest 'star' in the sky. At midnight it is due north. By dawn it is low in the west. Bright stars are overhead and down into the southeast evening sky. Jupiter is the biggest planet by far. Its mass is greater than all the other planets put togethe ...
Testing - Elon University
... The thin disk (z_thin = 350) is a younger star population with a higher density of stars. ...
... The thin disk (z_thin = 350) is a younger star population with a higher density of stars. ...
Chapter 1 1. The parallax angle of Sirius is 0.377 ′′. Find the
... of solar granulation is 0.5 km s−1 .) p.75 9. Use the equation of hydrostatic equilibrium and the assumption of constant density to compute the central pressures for each of the following stars: a) a K0 V star, b) a K0 III star, c) a K0 I star. p2.87 10. When the HR diagram is constructed from obser ...
... of solar granulation is 0.5 km s−1 .) p.75 9. Use the equation of hydrostatic equilibrium and the assumption of constant density to compute the central pressures for each of the following stars: a) a K0 V star, b) a K0 III star, c) a K0 I star. p2.87 10. When the HR diagram is constructed from obser ...
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.