* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Chapter 31 Galaxies & the Universe
Drake equation wikipedia , lookup
Perseus (constellation) wikipedia , lookup
Wilkinson Microwave Anisotropy Probe wikipedia , lookup
Fermi paradox wikipedia , lookup
Space Interferometry Mission wikipedia , lookup
Corvus (constellation) wikipedia , lookup
Gamma-ray burst wikipedia , lookup
Dark matter wikipedia , lookup
Outer space wikipedia , lookup
Observational astronomy wikipedia , lookup
Andromeda Galaxy wikipedia , lookup
Dark energy wikipedia , lookup
Cosmic distance ladder wikipedia , lookup
Shape of the universe wikipedia , lookup
Hubble's law wikipedia , lookup
Modified Newtonian dynamics wikipedia , lookup
Fine-tuned Universe wikipedia , lookup
Ultimate fate of the universe wikipedia , lookup
Star formation wikipedia , lookup
Timeline of astronomy wikipedia , lookup
Expansion of the universe wikipedia , lookup
H II region wikipedia , lookup
Non-standard cosmology wikipedia , lookup
High-velocity cloud wikipedia , lookup
Chapter 31 Galaxies & the Universe Review & Recap The Hubble Space Telescope measures black holes that cannot be seen. It does this by precisely measuring the speed of gas and stars around a black hole. This provides clues for the existence of a black hole. Astronomers measure the motion of stars swirling around the black hole to determine the mass. A Black Hole A black hole is an object with a gravitational pull so intense that not even light can escape. It pulls in other stars and gas with its gravitational force. 31.1 The Milky Way Galaxy Objectives: Determine the size and shape of the Milky Way, as well as Earth’s Location within it. Describe how the Milky Way was formed. Variable Stars By measuring a star's period of pulsation, astronomers can determine its luminosity and calculate how far away a variable star must be to appear as dim or as bright as it does. Variable stars comparing and contrasting Both are variable stars that have a relationship between its luminosity and its pulsation period. RR Lyrae variables • have periods of pulsations between 1.5 hours and 1 day and, on average, have the same luminosity Cepheid variables • have pulsation periods between 1 day and more than 100 days. • the longer the pulsation period the greater the luminosity The Shape of the Milky Way Astronomers have determined the shape of the Milky Way by using radio waves because they penetrate the interstellar gas and dust without being scattered or absorbed. Discovering Other Galaxies Other galaxies were first believed to be nebulae or star clusters within the Milky Way. Discovering Other Galaxies – cont. Edwin Hubble's discovery of Cepheid variable stars in the Great Nebula in the Andromeda constellation proved the existence of galaxies outside the Milky Way. Mass of the Milky Way Studies provide evidence that there is a great amount of unseen matter called dark matter composed of dim stellar remnants that have mass. Estimates vary from 200 billion x , up to 1,000 billion x the Mass of our Sun. Dark Matter The strongest evidence that the universe contains a larger amount of dark matter than visible matter is that by analyzing the motion of member galaxies, the mass of galaxy clusters can be determined. This mass of whole galaxy clusters is always much larger than the sum of only the visible masses of the galaxies. Formation and Evolution of the Milky Way The halo and bulge of the Milky Way are made of old stars which suggests that the halo and bulge formed first. Quiz – 31.1 The Shape of the Milky Way 31.2 Other Galaxies in the Universe Objectives: Describe how astronomers classify galaxies. Identify how galaxies are organized into clusters and super clusters. Describe the expansion of the universe. Superclusters Gigantic formation of clusters of galaxies hundreds of millions of light-years in size are called superclusters. Active Galaxies Core of a galaxy in which highly energetic objects or activities are located. (also known as AGNs!) Quasars The redshift in many quasars is very large, which means that those quasars are far away. The Expanding Universe – Hubble’s Law The farther away from Earth a galaxy is, the faster it is moving. Hubble Constant - A value of approximately 70 kilometers per second per megaparsec Elliptical Galaxy Please copy illustration This is an elliptical galaxy. Galaxies that are not flattened into disks and do not have spiral arms. Their shapes range from round ellipticals to very elongated ellipticals. Possible example: Virgo A Elliptical Galaxy – cont. Elliptical galaxies are divided into subclasses based on the ratio of their major and minor axes. Spiral Galaxy Please copy illustration This is a spiral galaxy. Disklike galaxy with spiral arms consisting of interstellar matter and young star clusters. A bulge consists of an old stellar population. There are normal and barred spirals. Possible example: Milky Way. Irregular Galaxy Please copy illustration This is an irregular galaxy. These galaxies do not fit the elliptical or spiral classification. They typically have no distinct shape. Possible example: Large and Small Magellanic Clouds. Galaxy Cluster Please copy illustration This is a galaxy cluster. These groups of galaxies may have from a few to hundreds of member galaxies and may range in sizes up to 30 million ly. In a cluster, most of the inner region galaxies are ellipticals. Galaxies in the outer portions are a mix of ellipticals and spirals. The galaxies often merge to form strangely shaped galaxies with more than one nucleus. Possible example: Local Group. Galaxy Clusters – cont. Most galaxies in the inner region of a large cluster are ellipticals. Galaxy Shapes M74 Spiral Galaxy An Sc galaxy is a normal spiral with loosely wound arms and a small, dim nucleus. Galaxy shapes Galaxy Shapes – Cont. a Tightly wound arm and large, bright nucleus c Loosely wound arms and a small, dim nucleus E7 Very elongated elliptical EO Round elliptical Irr Irregular galaxy S Normal spiral SB Barred spiral SO Flat disks that do not have spiral arms Quiz – 31.2 Other Galaxies in the Universe (10pts) 31.3 Cosmology Objectives: Explain the different theories about the formation of the universe. Describe the possible outcomes of universal expansion. Models of the Universe Steady-state theory - Proposes that the universe looks the same on large scales to all observers and that it has always looked that way Cosmic background radiation Has a wavelength of approximately 1 mm, which makes it microwave radiation. Cosmic background radiation Provides information about conditions very early in the expansion of the universe. The Hubble Constant Recent observations show that the rate of expansion of the universe is speeding up. Models of the Universe – cont. Big Bang Theory States that the universe began as a point and has been expanding ever since The Big Bang – cont. The theory does not suggest an explosion into space, but instead that there is an expansion of space with matter going along for the ride. Models of the Universe – cont. Inflationary Universe Theory - Model says the universe began as a fluctuation in a vacuum and expanded very rapidly for a fraction of a second before settling into a more orderly expansion Inflationary Universe Theory – cont. A flat universe was first predicted in the 1980’s by the inflationary universe model. The Critical Density Average density and Critical Density are factors in the expansion of the universe. The Critical Density – cont. The average density is the total matter of the universe. The Critical Density – cont. Critical density is the dividing point between a closed or an open universe. The Critical Density – cont. If the average density is higher than the critical density, the universe is closed. The Critical Density – cont. If the average density is lower than the critical density, the universe is open. The Critical Density – cont. If the average density equals the critical density, the universe is flat. Quiz – 31.2 Other Galaxies in the Universe (10pts) Quiz – 31.3 Cosmology (10pts)