The Life Cycle of a Star

... Lowmass stars (red dwarfs) consume hydrogen at a very slow rate (~ 100 billion years). During this time, they lose significant mass, and eventually evaporate. The result is a very faint white dwarf. ...

File

... Smaller, cooler main sequence stars achieve this via the proton-proton chain reactions where protons are added successively to produce the helium. This reaction is the starting point of zero-age main sequence stars Larger, hotter main sequence stars, operating at higher core temperatures, can fuse h ...

ASTR 1120H – Spring Semester 2010 Exam 2 – Answers The

... granulation all show that the Sun's photosphere must be heated from below. ...

Stellar Evolution

...  The star begins as a cloud of interstellar gas and dust called a nebula.  The nebula collapses on itself as a result of its own gravity.  The cloud begins to rotate around the center and when the center gets hot it is called a protostar. ...

Open clusters

... Review from last time: from observations of nearby stars, we can determine: distance to star apparent brightness  luminosity spectral type  temperature (for binary systems: mass) radius ...

the free PDF resource

... on temperature (hotter = more blue) mass varies hugely usually orbited by planets sometimes exists in a pair (called binary system) almost entirely hydrogen. ...

PowerPoint

... ...

Final Exam Study Guide

... A planetary nebula is typically formed at the same time as a(n) _______________. The process in which many stars form from a single interstellar cloud is called _______. Interstellar clouds cause stars behind them to appear __________. Most stars in our Galaxy are __________. In a neutron star, the ...

80.BrainPopLifeCycleStars

... under the pressure of gravity. _____________, it will begin to expand and contract, shedding its outer layers in the process. The remains of those out layers form a big cloud of gas and dust, called a ____________________. 13.At the center of a planetary nebula is a core of ___________, which after ...

29.3 – Stellar Evolution

... gases = planetary nebula •Gravity causes star to collapse inward •Hot, dense core of matter = white dwarf ...

The Life Cycles of Stars

... collapse inward and compact. This is the white dwarf stage. At this stage, the star’s matter is extremely dense. White dwarfs shine with a white-hot light. Once all of their energy is gone, they no longer emit light. The star has now reached the black dwarf phase in which it will forever remain. ...

2.5.2 development of a star

...  During this time it is stable as the gravitational forces that enable hydrogen burning balance and pull the star in, balance with the gas pressure pushing out.  This is much like the gas pressure inside a balloon balancing with the tension in the plastic of the balloon.  In the star it is known ...

15-3

... 4. The youngest stars are called protostars ...

protostars low mass stars intermediatemass stars red giant planetary

... When an intermediatemass star leaves the main sequence as it runs out of hydrogen, the shell of gases around the star begin to expand and cool, causing a reddish glow.This is where the term red giant comes from. These stars are very bright because of their larger surface area. The core bec ...

More stellar evolution…bloated stars and compact cores

... They do exist! The white dwarf stars • Sirius is a binary star. Its companion is a white dwarf • Appendix 12 (nearest stars) lists 2 of them, so they must be very common ...

Energy Production in Stars

...  Speed of light squared is a very large number => small amount of mass corresponds to a huge amount of energy  The conversion of mass to energy accounts for the enormous energy output of the stars  What physical mechanisms can cause this?  Nuclear fission - splitting of an atom's nucleus  Nucle ...

ppt

... White dwarfs. Supernovae. Neutron stars. ...

Unit 8 Astronomy

... fuel, and eventually run out, much more ______________. lives Larger stars live shorter _____________. Bigger stars are brighter and hotter due to the rapid rate of fusion __________. ...

Life Cycle of a Star

... The violent death of a high mass star, occurring when nuclear fusion within the star can no longer produce the heat required for ...

Star Cycle [Recovered]

... fuel, and eventually run out, much more ______________. lives Larger stars live shorter _____________. Bigger stars are brighter and hotter due to the rapid rate of fusion __________. ...

08 October: Stellar life after the Main Sequence

... An easy way to see why a Main Sequence star undergoes a “crisis” Hydrogen mass fraction in core at start: 71%, now: 34% ...

Stages in the Formation of Stars

... 5. Describe the events in the lifetime of a tiny cool star. _____________________________________________ 6. What process gives a star the mass of the Sun a “second life: after its hydrogen fusion stage is over? ...

Stellar life after the Main Sequence (cont.)

... the surface is not a good indicator of its deep interior ...

Stars after the Main Sequence. Example: Betelgeuse (Alpha Orionis

... the surface is not a good indicator of its deep interior ...

The Hertzsprung – Russell Diagram

...  Very bright, red in color, very large, cool in temperature  Brightness of stars are due to their enormous size ...

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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