AN INTRODUCTION TO ASTRONOMY Dr. Uri Griv Department of Physics, Ben-Gurion University

... v̄ = (1/N ) i=1 vi is the mean velocity and N is the total number of stars • A true MB distribution has a “tail” • Stars will be lost from the cluster • The escape speed ve = 2V ...

main sequence star

... • Small mass stars will collapse into white dwarfs after being red giants. • The outer gases are lost, which allows us to see the core of the star. The white dwarf is very dense and hot. The emit (release) less light than they did when they were stars. • As these white dwarfs cool they become fainte ...

Structure of the Universe

... What is the name our galaxy? • Milky Way- Why is it called that? • Because we are on an outer arm of the spiral (looks like a pin wheel) when you look into it, it looks like a milky cloud. ...

Foundation 1 - Discovering Astronomy

... become 1 helium nucleus • Since the mass of 4 hydrogen nuclei is greater than the mass of 1 helium nucleus, the leftover mass (0.7%) is converted to energy by Einstein’s equation: E=mc2 ...

Galaxies and the Universe

... portion of the sky reveals that the universe is filled with galaxies • The light we see from the most distant galaxies has traveled approximately 10 billion years to reach us ...

Name____________________________________________

... 5. The Milky Way Galaxy is just one of billions of galaxies in the universe. 6. Our Solar System is a single star system, but is located in the Milky Way Galaxy which contains other single stars, double stars, star systems, and dust & gas. 7. How do the planets stay in orbit around the sun? Gravity ...

QSOs . Continuum Radiation Energy Source

... Did peculiar galaxies merge to form today’s massive E and S galaxies? Co-moving density of Hubble Types vs. Redshift ...

The “Big Bang” Theory

... • Matter started to “clump” back together • This was due to gravity • The galaxies, stars and planets formed from these clumps of dust and gas • There are billions of galaxies in the universe and each galaxy consists of billions of stars ...

Ch. 11 and 12 Study Guide (ANSWERS)

... cold, mild, and hot temperatures have 0-2 moons smaller in size between Sun and asteroid belt ...

Pistol Star of the Pistol Nebula

... 200 to 250 Solar-masses but has been violently shedding much of its substance. With over 40 Solarmasses, extremely high luminosity, a variable spectra, and surrounding ejecta, it is classified as a Luminous Blue Variable like Eta Carinae, as an extremely large star that are now often regarded as the ...

Lifecycle of Stars - Mrs. Plante Science

... forming larger and larger balls of gas and dust molecules. • When the mass becomes large enough, gravitational contraction results in high pressure and temperature, and a protostar is formed. ...

Unit 2 Review Guide

... 5. What type of galaxy contains both young and old stars? 6. What type of galaxy contains only old stars? only young stars? Both old and young stars? 8. Besides their shape what other characteristic distinguishes the different types of galaxies from each other? 9. Why do distant galaxies appear redd ...

Jeopardy Questions

... Q: What is the difference between a nova, a core-collapse supernova, and a Type Ia supernova? A: Nova – Material falls on WD, fuses in small burst of energy. Type Ia Supernova – Material falls on WD, builds up until Chandrasekhar limit, and then everything explodes. Core-collapse Supernova – Massive ...

Chapter 12

... when a large nebula condensed and was collected together by gravity. 2. Our solar system formed more than 4.5 billion years ago. 3. Inner or terrestrial planets and outer or Jovian planets. ...

08 October: Stellar life after the Main Sequence

... is the “ash” of, not the fuel for, the proton-proton cycle ...

Chapter 13 Notes – The Deaths of Stars

...  Sun will expand to a red giant in ______________ billion years  Expands to ______________ radius  Earth will then be ___________________  Sun MAY form a ________________ nebula (but uncertain)  Sun’s C, O core will become a ______________ dwarf VIII. The Deaths of Massive Stars: Supernovae  F ...

I. Stars - SharpSchool

... sunspot which suddenly brighten and shoot outward at high speed. ...

The Star–Gas–Star Cycle

... • Stars in disk relatively young. • fraction of heavy elements same as or greater than the Sun • plenty of high- and low-mass stars, blue and red ...

Stellar Evolution

... tremendous event called a supernova ...

stars concept review

... _____ 6. A small, hot, extremely dense core left after a star collapses is a a. red giant. c. nova. b. pulsar. d. white dwarf. _____ 7. During the main-sequence stage, how is energy generated in a star’s core? a. Hydrogen fuses into helium. b. Carbon fuses into hydrogen. c. Helium fuses into hydroge ...

models

... Big Bang to Big Crunch to Big Bang ...

Die Sonne im Röntgenlicht - ST-ECF

... gas indicating profound influence of local strong magnetic field. • Compact nebulae, tracing various stages of massive star evolution • Evidence for a major starburst ~ a few 108 yrs ...

File

... 8-25 X larger than our Sun Consume their fuel very fast – die more quickly and more violently Star expands into a Supergiant which causes the core to collapse and the outer portion to explode creating a Supernova then a Neutron Star ...

Stars - St. Mary School

... Yellow stars have medium temperature Our Sun is a medium sized star When stars die they become white dwarfs (the dead core of a star) ...

Star Formation

... There is a limit to how massive any star can be! Very massive stars have to be fantastically hot (to hold themselves up against gravity). This means that they will be abundantly filled with energetic radiation (light), which in turn provides a pressure that will actually disrupt the star. The so-cal ...

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H II region

An H II region is a large, low-density cloud of partially ionized gas in which star formation has recently taken place. The short-lived blue stars forged in these regions emit copious amounts of ultraviolet light that ionize the surrounding gas. H II regions—sometimes several hundred light-years across—are often associated with giant molecular clouds. The first known H II region was the Orion Nebula, which was discovered in 1610 by Nicolas-Claude Fabri de Peiresc.H II regions are named for the large amount of ionised atomic hydrogen they contain, referred to as H II, pronounced H-two by astronomers (an H I region being neutral atomic hydrogen, and H2 being molecular hydrogen). Such regions have extremely diverse shapes, because the distribution of the stars and gas inside them is irregular. They often appear clumpy and filamentary, sometimes showing bizarre shapes such as the Horsehead Nebula. H II regions may give birth to thousands of stars over a period of several million years. In the end, supernova explosions and strong stellar winds from the most massive stars in the resulting star cluster will disperse the gases of the H II region, leaving behind a cluster of birthed stars such as the Pleiades.H II regions can be seen to considerable distances in the universe, and the study of extragalactic H II regions is important in determining the distance and chemical composition of other galaxies. Spiral and irregular galaxies contain many H II regions, while elliptical galaxies are almost devoid of them. In the spiral galaxies, including the Milky Way, H II regions are concentrated in the spiral arms, while in the irregular galaxies they are distributed chaotically. Some galaxies contain huge H II regions, which may contain tens of thousands of stars. Examples include the 30 Doradus region in the Large Magellanic Cloud and NGC 604 in the Triangulum Galaxy.

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H II region