Page 1 Astronomy 110 Homework #08 Assigned: 03/13/2007 Due

... A) to dim and redden distant stars by preferentially scattering their blue light. B) to scatter the red light from stars preferentially, making them appear more blue than expected. C) almost nonexistent, because light does not interact with dust. D) to make stars appear less bright than expected by ...

17.Extra-solar

Due Date: Thursday, November 16, 2006

... The most significant difference between a high-mass star and the Sun will be their lifetime! Look at the HR diagram in Figure 11.1. The lifetime of Spica (10 Msun) is only about 10 million years. The lifetime of Achernar (6 Msun) is only 100 million years…so when we really should not expect the Sun ...

The Effects of Gravity

Stars are classified by how hot they are (temperature)

... When stars get old ...

Stellar Evolution Notes

... 10 billion years. It is already 5 billion years old, meaning it will live another 5 billion years. Luminosity – ...

Stellar Evolution

... to counteract the force of gravity, the outer layers of the star begin to collapse inward. Just as during formation, when the material contracts, the temperature and pressure increase. This newly generated heat temporarily counteracts the force of gravity, and the outer layers of the star are now pu ...

20.1 Notes

... own gravity and rebounds with a shock wave that violently blows the stars outer layers from the core. This huge, bright explosion is called a Type II _________________________. If the core that remains after a supernova has a mass of 1.4 – 3 solar masses it becomes a _______________ star, a very den ...

Solutions 5

Stellar Evolution 1 Star Formation 2 Nebulae

... The lifetimes of stars are typically in the billions of years, although the more massive the star, the shorter the lifetime. The “birth” and “death” of a star take a relatively short time compared to the long middle part of the “life” of a star. In the long middle part, in which the star is relative ...

Properties of Stars and H

The Mass-Luminosity Relationship and Stellar Lifetimes

Stars

... When seen from the Earth, most stars appear as small points of light because they are very far away. They do not move. The Earth rotates, so we are the ones moving. ...

Document

... a. Star A is closer to us than Star B. Both are farther from us than 1 pc. b. Star A is closer to us than Star B. Both are closer to us ...

Stars

... a. Star A is closer to us than Star B. Both are farther from us than 1 pc. b. Star A is closer to us than Star B. Both are closer to us ...

Slide 1

... they run out of nuclear fuel.. Typically 1,000 times the size of our solar system These Ten have names like Owl, the Cat's Eye, the Ghost of Jupiter, Ring. This glorious final phase in the life of a star lasts only about 10,000 yrs. ...

Star Life Guided Notes

... pressure ceases Core ________ at 1/4 the speed of light & takes about 1/10 of a second Collapse of the core to about 100 km across Outer layers “bounce” of the solid core Releases 100x the energy of our sun produces in it’s lifetime -- in 1/10 of a ...

Chapter 13

Binocular Universe: Bikini Bottom

Astronomy 2

... uses data from lots of stars, so there are lots of dots. The position of each dot on the diagram corresponds to the star's luminosity and its temperature  The vertical position represents the star's luminosity (absolute magnitude).  The horizontal position represents the star's surface temperature ...

Ordinary Stars - Edgewood High School

... of 10,000 K and another a temperature of 5,000 K, how much more energy does the hotter star put out? ...

Star Of Wonder

... bomb) to release much heat and light. The object recorded in 5 BC by the Chinese could have been a nova rather than a comet, and this could in fact have been the Star of Bethlehem. Because it's so stupendous, my favorite hypothesis has always been a supernova, the dramatic brightening of a star cau ...

Merak

... How Far Away: 62 light years away How Bright: About 50 times brighter than the Sun Where to View: In the constellation Ursa Major. When to View:All year round in the Northern Hemisphere ...

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Lyra

Lyra (/ˈlaɪərə/; Latin for lyre, from Greek λύρα) is a small constellation. It is one of 48 listed by the 2nd century astronomer Ptolemy, and is one of the 88 constellations recognized by the International Astronomical Union. Lyra was often represented on star maps as a vulture or an eagle carrying a lyre, and hence sometimes referred to as Aquila Cadens or Vultur Cadens. Beginning at the north, Lyra is bordered by Draco, Hercules, Vulpecula, and Cygnus. Lyra is visible from the northern hemisphere from spring through autumn, and nearly overhead, in temperate latitudes, during the summer months. From the southern hemisphere, it is visible low in the northern sky during the winter months.The lucida or brightest star—and one of the brightest stars in the sky—is the white main sequence star Vega, a corner of the Summer Triangle. Beta Lyrae is the prototype of a class of stars known as Beta Lyrae variables, binary stars so close to each other that they become egg-shaped and material flows from one to the other. Epsilon Lyrae, known informally as the Double Double, is a complex multiple star system. Lyra also hosts the Ring Nebula, the second-discovered and best-known planetary nebula.

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Lyra