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... A star’s ________ gives clues about the star’s temperature. The coolest stars appear ________. The hottest stars appear ________. Very large stars are called ________ stars or ____________ stars. Our sun is a medium sized ________. Most stars are ________ than the sun. White dwarf stars are abou ...
... A star’s ________ gives clues about the star’s temperature. The coolest stars appear ________. The hottest stars appear ________. Very large stars are called ________ stars or ____________ stars. Our sun is a medium sized ________. Most stars are ________ than the sun. White dwarf stars are abou ...
Stars Unit 1-2: Stars
... Elements in Stars • Scientists use spectral analysis to determine the composition of stars. – Spectral analysis is a process that uses a tool called a spectroscope to separate the different wavelengths of light coming from a star. – By observing which wavelengths are stronger, missing, or weaker, s ...
... Elements in Stars • Scientists use spectral analysis to determine the composition of stars. – Spectral analysis is a process that uses a tool called a spectroscope to separate the different wavelengths of light coming from a star. – By observing which wavelengths are stronger, missing, or weaker, s ...
Integrative Studies 410 Our Place in the Universe
... • Light stars blow out their outer layers to form a Planetary Nebula • The core of a massive star (more than 8 solar masses) collapses, triggering the explosion of a Supernova • Also the core of a very massive stars (more than 25 solar masses) collapses, triggering the explosion Supernova ...
... • Light stars blow out their outer layers to form a Planetary Nebula • The core of a massive star (more than 8 solar masses) collapses, triggering the explosion of a Supernova • Also the core of a very massive stars (more than 25 solar masses) collapses, triggering the explosion Supernova ...
Apparent brightness
... Distinguish between luminosity and brightness and explain how stellar luminosity is determined. Explain how stars are classified according to their colors, surface temperatures and spectral characteristics, and tell why such a classification is useful. State how an H-R diagram is constructed, ...
... Distinguish between luminosity and brightness and explain how stellar luminosity is determined. Explain how stars are classified according to their colors, surface temperatures and spectral characteristics, and tell why such a classification is useful. State how an H-R diagram is constructed, ...
Problem set 2
... and luminosity from the textbook, and between mass and radius (you can assume it’s linear, R ∼ M), compute Proxima’s effective temperature Tef f . Comparing with sun’s temperature, prove that the star appears much redder than the sun. Compute the effective temperatures of the other two stars (1.1 an ...
... and luminosity from the textbook, and between mass and radius (you can assume it’s linear, R ∼ M), compute Proxima’s effective temperature Tef f . Comparing with sun’s temperature, prove that the star appears much redder than the sun. Compute the effective temperatures of the other two stars (1.1 an ...
The Life Cycle of Stars
... exhausted its ability to fuse other elements like carbon and oxygen, it will become a red giant and expand in size to envelope the Earth. And surprisingly, the larger the mass of the star, the quicker it burns its fuel sources and the shorter its lifespan. Also see and read about Hubble Space Telesc ...
... exhausted its ability to fuse other elements like carbon and oxygen, it will become a red giant and expand in size to envelope the Earth. And surprisingly, the larger the mass of the star, the quicker it burns its fuel sources and the shorter its lifespan. Also see and read about Hubble Space Telesc ...
Objects Beyond our Solar System
... when a large sun comes to the end of its life and explodes. The outside of the star is blown outward but the core that is left behind collapses in on itself and creates an incredibly dense mass of material. The core of a neutron star is so dense that one cupful of it would have a mass of millions ...
... when a large sun comes to the end of its life and explodes. The outside of the star is blown outward but the core that is left behind collapses in on itself and creates an incredibly dense mass of material. The core of a neutron star is so dense that one cupful of it would have a mass of millions ...
THE BIRTH AND DEATH OF A LOW/MEDIUM MASS STAR
... • THE STAGE WHEN A STAR IS IN IT’S “BEST” LIFE CYCLE • OUR SUN IS A MAIN SEQUENCE STAR • MAIN SEQUENCE STARS HAVE MOSTLY HYDROGEN. • THE HYDROGEN EXPLODES, GIVING OFF LIGHT AND HEAT • AS IT EXPLODES, THE HYDROGEN TURNS TO HELIUM. • HELIUM IS LIGHTER THAN HYDROGEN. • OUR SUN IS 4.6 BILLION YEARS OLD. ...
... • THE STAGE WHEN A STAR IS IN IT’S “BEST” LIFE CYCLE • OUR SUN IS A MAIN SEQUENCE STAR • MAIN SEQUENCE STARS HAVE MOSTLY HYDROGEN. • THE HYDROGEN EXPLODES, GIVING OFF LIGHT AND HEAT • AS IT EXPLODES, THE HYDROGEN TURNS TO HELIUM. • HELIUM IS LIGHTER THAN HYDROGEN. • OUR SUN IS 4.6 BILLION YEARS OLD. ...
Astronomers classify stars according to their physical characteristics
... called its _apparent magnitude__ or brightness. •A star’s _apparent_ brightness depends upon how bright it _actually is and its _distance_ from Earth. •A star’s actual brightness (or _absolute magnitude) usually depends on the star’s _size_ and temperature__. •Because stars with _more mass ___ have ...
... called its _apparent magnitude__ or brightness. •A star’s _apparent_ brightness depends upon how bright it _actually is and its _distance_ from Earth. •A star’s actual brightness (or _absolute magnitude) usually depends on the star’s _size_ and temperature__. •Because stars with _more mass ___ have ...
Study Guide for the 4TH Astronomy Exam
... d. List the mass limits of stars and explain why these limits apply. e. Describe the processes and stages of star formation from a giant molecular cloud to an open cluster. f. Identify in a photograph the following objects: a GMC, Bok Globule, OB Association, HII region, Open Cluster g. Describe the ...
... d. List the mass limits of stars and explain why these limits apply. e. Describe the processes and stages of star formation from a giant molecular cloud to an open cluster. f. Identify in a photograph the following objects: a GMC, Bok Globule, OB Association, HII region, Open Cluster g. Describe the ...
Interstellar clouds
... • Planetary nebula may form around low-mass dying stars • Form when the mass ejected by the AGB star piles up in a dense expanding shell. • Planetary nebula are visible for about 50,000 years of so, and can be illuminated by a white ...
... • Planetary nebula may form around low-mass dying stars • Form when the mass ejected by the AGB star piles up in a dense expanding shell. • Planetary nebula are visible for about 50,000 years of so, and can be illuminated by a white ...
REVIEW: STAR`S TEST
... What looks like a potato, orbits the sun between Mars and Jupiter, and is made of rock ? _________________________ A rock that hits the Earth’s surface is called a _______________________. A rock that is flying through space is called a _____________________________. A rock that burns up in our atmo ...
... What looks like a potato, orbits the sun between Mars and Jupiter, and is made of rock ? _________________________ A rock that hits the Earth’s surface is called a _______________________. A rock that is flying through space is called a _____________________________. A rock that burns up in our atmo ...
Star Study Guide Chapter 21 Test
... shows the relationship between absolute brightness and surface temperature of a star ...
... shows the relationship between absolute brightness and surface temperature of a star ...
Hertzsprung-Russell (H-R) Diagram Hertzsprung-Russell Diagram March 16 −
... Hot-plate model of star: L=R2T4 Model of the solar interior X How to read H-R Diagram Spectrum of black body: Hotter=>bluer Energy generation in the sun X ...
... Hot-plate model of star: L=R2T4 Model of the solar interior X How to read H-R Diagram Spectrum of black body: Hotter=>bluer Energy generation in the sun X ...
supernova!
... settle to the centre. It is merely a consequence of the fact that the progressively heavier elements are created near the centre, where the temperature progressively becomes high enough to do so! The outer envelope of the star is still the pristine material from which it was made (mainly Hydrogen an ...
... settle to the centre. It is merely a consequence of the fact that the progressively heavier elements are created near the centre, where the temperature progressively becomes high enough to do so! The outer envelope of the star is still the pristine material from which it was made (mainly Hydrogen an ...
Understanding Stars
... Every element has it’s own unique spectrum – Use this to identify the composition of a gas • Chromosphere or corona Extremely dense things (opaque gases, liquids or solids) the atoms are too close – Emit a continuous spectrum • photosphere Stefan-Boltzman Law A dense hot object emits light of all co ...
... Every element has it’s own unique spectrum – Use this to identify the composition of a gas • Chromosphere or corona Extremely dense things (opaque gases, liquids or solids) the atoms are too close – Emit a continuous spectrum • photosphere Stefan-Boltzman Law A dense hot object emits light of all co ...
Extra Questions Stellar properties
... 2 The star Procyon in Canis Major is a prominent star in the winter sky because its apparent magnitude is +0.37. It is one of the nearest stars being only 3.52 parsecs from Earth. What is the absolute magnitude of Procyon? How many times brighter or dimmer than the Sun is it? 3 Barnard’s star, the s ...
... 2 The star Procyon in Canis Major is a prominent star in the winter sky because its apparent magnitude is +0.37. It is one of the nearest stars being only 3.52 parsecs from Earth. What is the absolute magnitude of Procyon? How many times brighter or dimmer than the Sun is it? 3 Barnard’s star, the s ...
Star
A star is a luminous sphere of plasma held together by its own gravity. The nearest star to Earth is the Sun. Other stars are visible from Earth during the night, appearing as a multitude of fixed luminous points in the sky due to their immense distance from Earth. Historically, the most prominent stars were grouped into constellations and asterisms, and the brightest stars gained proper names. Extensive catalogues of stars have been assembled by astronomers, which provide standardized star designations.For at least a portion of its life, a star shines due to thermonuclear fusion of hydrogen into helium in its core, releasing energy that traverses the star's interior and then radiates into outer space. Once the hydrogen in the core of a star is nearly exhausted, almost all naturally occurring elements heavier than helium are created by stellar nucleosynthesis during the star's lifetime and, for some stars, by supernova nucleosynthesis when it explodes. Near the end of its life, a star can also contain degenerate matter. Astronomers can determine the mass, age, metallicity (chemical composition), and many other properties of a star by observing its motion through space, luminosity, and spectrum respectively. The total mass of a star is the principal determinant of its evolution and eventual fate. Other characteristics of a star, including diameter and temperature, change over its life, while the star's environment affects its rotation and movement. A plot of the temperature of many stars against their luminosities, known as a Hertzsprung–Russell diagram (H–R diagram), allows the age and evolutionary state of a star to be determined.A star's life begins with the gravitational collapse of a gaseous nebula of material composed primarily of hydrogen, along with helium and trace amounts of heavier elements. Once the stellar core is sufficiently dense, hydrogen becomes steadily converted into helium through nuclear fusion, releasing energy in the process. The remainder of the star's interior carries energy away from the core through a combination of radiative and convective processes. The star's internal pressure prevents it from collapsing further under its own gravity. Once the hydrogen fuel at the core is exhausted, a star with at least 0.4 times the mass of the Sun expands to become a red giant, in some cases fusing heavier elements at the core or in shells around the core. The star then evolves into a degenerate form, recycling a portion of its matter into the interstellar environment, where it will contribute to the formation of a new generation of stars with a higher proportion of heavy elements. Meanwhile, the core becomes a stellar remnant: a white dwarf, a neutron star, or (if it is sufficiently massive) a black hole.Binary and multi-star systems consist of two or more stars that are gravitationally bound, and generally move around each other in stable orbits. When two such stars have a relatively close orbit, their gravitational interaction can have a significant impact on their evolution. Stars can form part of a much larger gravitationally bound structure, such as a star cluster or a galaxy.