astrophysics - Uplift Summit Intl
... (a) Explain why a star having a mass of 50 times the solar mass would be expected to have a lifetime of many times less than that of the Sun. (a) The more massive stars will have much more nuclear material (initially hydrogen). Massive stars have greater gravity so equilibrium is reached at a highe ...
... (a) Explain why a star having a mass of 50 times the solar mass would be expected to have a lifetime of many times less than that of the Sun. (a) The more massive stars will have much more nuclear material (initially hydrogen). Massive stars have greater gravity so equilibrium is reached at a highe ...
Pre-Main Sequence Evolution
... the disk has the lowest density (out the poles). These patches of nebulosity are called Herbig-Haro objects. ...
... the disk has the lowest density (out the poles). These patches of nebulosity are called Herbig-Haro objects. ...
HW #01
... (e.g., when a main sequence star becomes a red giant)? What would happen to the size of a star if its core steadily produced less energy than it did at some earlier time (e.g., when a star stops fusing nuclei in its core)? Do photons produced in the core zip right out from the Sun or does it take lo ...
... (e.g., when a main sequence star becomes a red giant)? What would happen to the size of a star if its core steadily produced less energy than it did at some earlier time (e.g., when a star stops fusing nuclei in its core)? Do photons produced in the core zip right out from the Sun or does it take lo ...
Iron in Stars
... A few minutes after the Big Bang there was a period of primordial nucleosynthesis: the creation of elements from the sea of protons and neutrons that filled the Universe. This resulted in the production of deuterium (a hydrogen isotope of one proton and one neutron), helium-3 and -4, and lithium-6 a ...
... A few minutes after the Big Bang there was a period of primordial nucleosynthesis: the creation of elements from the sea of protons and neutrons that filled the Universe. This resulted in the production of deuterium (a hydrogen isotope of one proton and one neutron), helium-3 and -4, and lithium-6 a ...
White dwarfs - University of Toronto
... see the papers in Nature (vol 443, p 283 and p 308) A Type Ia supernova more than twice as bright as others of its type has been observed, suggesting it arose from a star that managed to grow more massive than the Chandrasekhar limit. This mass cut-off was thought to make all such supernovae explode ...
... see the papers in Nature (vol 443, p 283 and p 308) A Type Ia supernova more than twice as bright as others of its type has been observed, suggesting it arose from a star that managed to grow more massive than the Chandrasekhar limit. This mass cut-off was thought to make all such supernovae explode ...
NUCLEAR FISSION- a Tunneling Process NUCLEAR FUSION
... A He-4 nucleus (2 protons, 2 neutrons) +H-3 tunnel through the barrier and fuse with the (tritium-1 proton + 2 neutrons) gives Li-7 nucleus, forming a new heavier nucleus. This will get rid of its excess energy by re-emitting photons or a few sub-nuclear particles (protons, neutrons, etc)- which can ...
... A He-4 nucleus (2 protons, 2 neutrons) +H-3 tunnel through the barrier and fuse with the (tritium-1 proton + 2 neutrons) gives Li-7 nucleus, forming a new heavier nucleus. This will get rid of its excess energy by re-emitting photons or a few sub-nuclear particles (protons, neutrons, etc)- which can ...
Nuclear Physics - fission, fusion, and the stars
... A He-4 nucleus (2 protons, 2 neutrons) +H-3 tunnel through the barrier and fuse with the (tritium-1 proton + 2 neutrons) gives Li-7 nucleus, forming a new heavier nucleus. This will get rid of its excess energy by re-emitting photons or a few sub-nuclear particles (protons, neutrons, etc)- which can ...
... A He-4 nucleus (2 protons, 2 neutrons) +H-3 tunnel through the barrier and fuse with the (tritium-1 proton + 2 neutrons) gives Li-7 nucleus, forming a new heavier nucleus. This will get rid of its excess energy by re-emitting photons or a few sub-nuclear particles (protons, neutrons, etc)- which can ...
Chapter 14
... This led to the formation of H nuclei. • The H nuclei were pulled together by gravity into masses that would become the stars. The H nuclei fused into He nuclei, releasing enough energy that the star began to shine. • The fusion process continued for billions of years, releasing energy as heavier an ...
... This led to the formation of H nuclei. • The H nuclei were pulled together by gravity into masses that would become the stars. The H nuclei fused into He nuclei, releasing enough energy that the star began to shine. • The fusion process continued for billions of years, releasing energy as heavier an ...
Stars Part Two
... How do we know all this? By observing Globular clusters… 1. Globular clusters are thousands of stars that all formed at more or less the same time. 2. Globular clusters are much smaller than galaxies. 3. Galaxies create stars in an on-going process. 4. The stars in a globular cluster accrete sudde ...
... How do we know all this? By observing Globular clusters… 1. Globular clusters are thousands of stars that all formed at more or less the same time. 2. Globular clusters are much smaller than galaxies. 3. Galaxies create stars in an on-going process. 4. The stars in a globular cluster accrete sudde ...
Slide 1
... ours, with something we call a “nova”. When the middle reaches carbon and can’t fuse any more, it shuts down. All those puffed up layers drift off into space and we’re left with a tiny, white-hot core of carbon just sitting there. This is a “white dwarf”. All the stuff that puffs off into space form ...
... ours, with something we call a “nova”. When the middle reaches carbon and can’t fuse any more, it shuts down. All those puffed up layers drift off into space and we’re left with a tiny, white-hot core of carbon just sitting there. This is a “white dwarf”. All the stuff that puffs off into space form ...
The Milky Way
... Ultraviolet radiation and strong stellar winds from young, hot, massive stars in open star clusters are compressing the surrounding gas. ...
... Ultraviolet radiation and strong stellar winds from young, hot, massive stars in open star clusters are compressing the surrounding gas. ...
Pre-Main Sequence Evolution
... structure and evolution; instead of moving vertically, it moves horizontally on the HR diagram, i.e., at constant L but changing T. ...
... structure and evolution; instead of moving vertically, it moves horizontally on the HR diagram, i.e., at constant L but changing T. ...
The Milky Way - Houston Community College System
... Ultraviolet radiation and strong stellar winds from young, hot, massive stars in open star clusters are compressing the surrounding gas. ...
... Ultraviolet radiation and strong stellar winds from young, hot, massive stars in open star clusters are compressing the surrounding gas. ...
School of Physics Multiwavelength Observations of Evolved Stars Research project in Astrophysics
... of our own Sun. Although supernovae are showy objects, stars with mass similar to our Sun are much more plentiful and when they evolve to the red giant stage they begin to lose processed material in the form of a cool wind. These stars contribute a significant quantity of the carbon, nitrogen and ox ...
... of our own Sun. Although supernovae are showy objects, stars with mass similar to our Sun are much more plentiful and when they evolve to the red giant stage they begin to lose processed material in the form of a cool wind. These stars contribute a significant quantity of the carbon, nitrogen and ox ...
here - Tenafly Middle School
... • About 90 percent of all stars are main sequence stars. • What about the other ten percent? • Some of these stars are hot but not bright. • These small stars are located on the lower left of the H-R diagram and are called white dwarfs. • Other stars are extremely bright but not hot. • These large s ...
... • About 90 percent of all stars are main sequence stars. • What about the other ten percent? • Some of these stars are hot but not bright. • These small stars are located on the lower left of the H-R diagram and are called white dwarfs. • Other stars are extremely bright but not hot. • These large s ...
The Distance Ladder I - Sierra College Astronomy Home Page
... Learn how we measure the size of the Universe. See how other quantities depend upon the Universe’s size. ...
... Learn how we measure the size of the Universe. See how other quantities depend upon the Universe’s size. ...
Life Cycle of Stars Powerpoint
... but is the size of Earth, it is one million times as dense as the sun. When a white dwarf runs out of fuel and energy it becomes a black dwarf. • A black dwarf has stopped glowing because fusion has stopped. It is a “dead” star, not the Death Star that is ...
... but is the size of Earth, it is one million times as dense as the sun. When a white dwarf runs out of fuel and energy it becomes a black dwarf. • A black dwarf has stopped glowing because fusion has stopped. It is a “dead” star, not the Death Star that is ...
Stars and Galaxies
... diagram. Stars spend most of their lives on the main sequence. A star becomes a main-sequence star as soon as it begins to fuse hydrogen into helium. It remains on the main sequence for as long as it continues to fuse hydrogen into helium. Lower-mass stars such as the Sun stay on the main sequence f ...
... diagram. Stars spend most of their lives on the main sequence. A star becomes a main-sequence star as soon as it begins to fuse hydrogen into helium. It remains on the main sequence for as long as it continues to fuse hydrogen into helium. Lower-mass stars such as the Sun stay on the main sequence f ...
solution
... causes the mass of the core remnant to exceed about 3 M , thus forming a black hole; and finally 3) two neutron stars are in close orbit with one another and due to gravitational wave radiation, their orbits gradually decay and they collide/coalesce, thus forming a black hole. 21.19 How do astronom ...
... causes the mass of the core remnant to exceed about 3 M , thus forming a black hole; and finally 3) two neutron stars are in close orbit with one another and due to gravitational wave radiation, their orbits gradually decay and they collide/coalesce, thus forming a black hole. 21.19 How do astronom ...
Stars Blown Blind
... and then conducted more deeply into the star. When a burning star is moving through the air, the flame will be deflected down wind. (See Figure 2.) Thus, in this case, the feedback of thermal energy to unignited composition is impeded. Also, the up wind side of the star will be exposed to relatively ...
... and then conducted more deeply into the star. When a burning star is moving through the air, the flame will be deflected down wind. (See Figure 2.) Thus, in this case, the feedback of thermal energy to unignited composition is impeded. Also, the up wind side of the star will be exposed to relatively ...
The Life Cycles of Stars, Part I
... nuclei crash into each other so hard that they stick together, or fuse. In doing so, they give off a great deal of energy. This energy from fusion pours out from the core, setting up an outward pressure in the gas around it that balances the inward pull of gravity. When the released energy reaches t ...
... nuclei crash into each other so hard that they stick together, or fuse. In doing so, they give off a great deal of energy. This energy from fusion pours out from the core, setting up an outward pressure in the gas around it that balances the inward pull of gravity. When the released energy reaches t ...
![19 — Stellar Energy [Revision : 1.4]](http://s1.studyres.com/store/data/017867977_1-139820145cee69abc1dc516c7511cb2b-300x300.png)
19 — Stellar Energy [Revision : 1.4]
... – This is Kelvin-Helmholtz contraction: in a star with no other energy sources, luminosity is supplied by gravitational energy release (half goes into luminosity, other half goes into thermal energy) – Typical timescale of KH contraction: tKH ∼ ...
... – This is Kelvin-Helmholtz contraction: in a star with no other energy sources, luminosity is supplied by gravitational energy release (half goes into luminosity, other half goes into thermal energy) – Typical timescale of KH contraction: tKH ∼ ...
Cells The Basic Unit of Life
... but it is actually much less luminous than the nearby red giant, Betelgeuse, in the constellation Orion. Very often, stars appear bright simply because they are close to us. 12. A _________________ is the remains of a supermassive star that is apparently invisible due to the fact that tremendous ___ ...
... but it is actually much less luminous than the nearby red giant, Betelgeuse, in the constellation Orion. Very often, stars appear bright simply because they are close to us. 12. A _________________ is the remains of a supermassive star that is apparently invisible due to the fact that tremendous ___ ...
THERMAL STABILITY OF LOW MASS STARS
... the normal main sequence stars are thermally stable, while models on the high density branch are thermally unstable. The transition from stability to instability coincides with the turning point of the main sequence, where a minimum mass is reached. This is just as expected from a general relation b ...
... the normal main sequence stars are thermally stable, while models on the high density branch are thermally unstable. The transition from stability to instability coincides with the turning point of the main sequence, where a minimum mass is reached. This is just as expected from a general relation b ...
Sources of energy and the origin of the chemical elements
... and small (relative to the Sun) star is called a White Dwarf. Stars with M< 0.4 M¤ will not become red giants because they do not become hot enough for He burning, but their lifetimes will be longer than the present age of the Universe. Typical C,O white dwarf specs: • mass of about 1 M¤ (on aver ...
... and small (relative to the Sun) star is called a White Dwarf. Stars with M< 0.4 M¤ will not become red giants because they do not become hot enough for He burning, but their lifetimes will be longer than the present age of the Universe. Typical C,O white dwarf specs: • mass of about 1 M¤ (on aver ...
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.