Space Science Unit - World of Teaching

... star and the absolute magnitude (brightness) of the star to help astronomers decide which phase of the star’s life cycle the star is in and other important information about the star. • Most stars are what we consider main sequence (including our sun). They make up 90% of the stars in our sky. These ...

The Solar System

Stars

... If the remaining mass of the star is more than about three times that of the Sun, it will collapse so completely that it will literally disappear from the universe. What is left behind is an intense region of gravity called a black hole ...

name - New York Science Teacher

... 1. Name the brightest star in the known universe. _____________________________ 2. What is its magnitude? ________________________ 3. Are the brightest stars low magnitude or high magnitude? ______________________________ 4. Make a top 10 list of the names of the 10 brightest stars in the known univ ...

Expansion of the Universe

... Stars spend roughly 90% of their lives burning hydrogen into helium on the main sequence Massive stars need higher central temperatures and pressures to support themselves against gravitational collapse, and for this reason, fusion reactions in these stars proceed at a faster rate than in lower ma ...

Twinkle, Twinkle Little Star

... gas and dust in my Solar Nursery and begins to Shine! When the cool masses of dust and gas combine, a star has a temperature of 1,800,000 degrees F! http://www.virginmedia.com/images/ ...

How are stars formed

AST 207 Test 2 Answers 20 October 2010

... star A. Prof. Adams says he discovered a new type of star that is fainter than white dwarfs. Has he discovered a new type of star? Explain. The clues are very much like Walter Adams’ discovery that Sirius B is a white dwarf. However, there is a crucial missing clue. Since Sirius A and B were known t ...

Solutions 5

... In high-mass stars everything takes place more rapidly. Greater mass means greater gravity and the protostar process is accelerated. Greater mass leads to greater core pressures and temperatures, thus, a hotter more luminous star. The greater mass star consumes the available hydrogen at a much highe ...

Module G - U1_ L3 - Life Cycle of Stars

... • As a result, dense regions of gas and dust form within the nebula. • The densest regions, called dense cores, form new stars. • The temperature within dense cores increases for millions of years. • At about 10 million °C, the process of hydrogen nuclear fusion begins, marking the birth of a star. ...

Space Science Unit

... star and the absolute magnitude (brightness) of the star to help astronomers decide which phase of the star’s life cycle the star is in and other important information about the star. • Most stars are what we consider main sequence (including our sun). They make up 90% of the stars in our sky. These ...

Lecture 10 February 13

... Each electron added must find its own quantum state by having its own velocity. But what happens when the next electron has to go faster than light? ...

Document

... Orion Copyright – Tyler Nordgren ...

NOVAE and SUPERNOVAE

...  The nova explosion causes the WD to increase in brightness by 10,000 times or more. From our perspective a new star shines in the sky.  Novae are repeat phenomena; WDs may explode many times. The explosion cycle is regulated by the rate at which matter is deposited onto the WD. More violent (and ...

File

... Answer the following questions in your notebook. Write the complete question and write your answer in complete sentences. 4. Explain how astronomers measure the distance to nearby stars. 5. What are the main characteristics used to classify stars? 6. How would you classify the sun based on each of t ...

122final10

... tells us the intrinsic luminosity of the pre-supernovae stars determines the amount of Gold in the Earth ensures the creation of a neutron star depends on the core neutron degeneracy pressure causes the neutron star to collapse to a black hole 4) When the core of the sun has been converted from hydr ...

ppt file

... If M>0.4Msun, start to burn HeC through the triplealpha process (occurs explosively if 0.4Msun2-3Msun) The expels stellar envelope in series of explosive events (novae)… form a planetary nebula He or C core remains as a white dwarf… dense (stellar mass but size of Earth) an ...

PPT

... High core temperatures allow helium to fuse with heavier elements ...

Stars

... Beginning of a Star • Stars begin as a large cloud of gas and dust called a nebula. • Gravity pulls the particles of gas and dust causing the nebula to shrink. • A contracting cloud of gas and dust with enough mass to form a star is called a protostar. (Proto means “earliest” in ...

eta carinae – nature`s own hadron collider

Formation of Stars - mcp

... 2. Created inside of Nebulae ...

Supernovae: Heavy Elements

... Supernova explosions could easily be responsible for all of the iron and other heavy elements found in the galaxy Our sun, our planets, the silicon in our rocks, the change in our pockets, and the metal in the little green men’s spaceships, are all the result of supernova explosions ...

Stellar Classification and Evolution What is a star? A cloud of gas

... Brown Dwarfs are _____________________________, but they do give off small amounts of ___________ as they cool ...

Study Guide: Use your notes and handouts to

... What is dark matter? What type of object do scientists believe it helps to hold together? ...

Test#3

... Why don't less massive objects ever experience nuclear fusion? a) they explode before fusion can begin b) they collide with other objects and increase their masses c) they never become hot enough for fusion to occur d) they become black holes before fusion can begin 21. What do all main sequence sta ...

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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.

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Star