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Premium member Presentation Transcript A105 Stars and Galaxies: A105 Stars and Galaxies Last units: 81, 82, 83, 84 NQ 13 now online LAST(!) homework & project due today Today’s APODPrinciples of Cosmology: Principles of Cosmology Homogeneity – Matter is spread uniformly through space Isotropy – The Universe looks the same in every direction Universality – The basic principles of physics are the same everywhere The Cosmological Principle: The universe will look more or less the same to observers everywhere, in every galaxy, no matter where it isApplying the Principles of Cosmology: Applying the Principles of CosmologySummary – Strong evidence supports the Big Bang Theory: Summary – Strong evidence supports the Big Bang Theory The Universe is expanding (and cooling) from an initial, dense state Radiation left over from the Big Bang is now detected in the form of microwaves—the cosmic microwave background—which we can observe with a radio telescope Observations of helium and other light elements agree with the predictions for fusion in the Big Bang theoryA brief history of the Universe: A brief history of the Universe Courtesy of Fred Adams University of MichiganSlide6: BIG BANG – 13.7 billion years ago, space, time, and energy burst into existence The part of the Universe that now comprises our “observable universe” was very small and very dense Why did the Universe suddenly appear????Slide7: INFLATION ERA – Regions of the universe rapidly expand from smaller than an atom to bigger than the Solar System. Because all of space was so compact, every part of the universe was in “contact” with every other part. Energy was uniformly distributed throughout the early universeSlide8: PHOTON ERA - energy in the form of electromagnetic radiation dominates the Universe - visible light, X rays, radio waves and ultraviolet rays. Energy transforms into matter: quarks the first nuclei: protons, neutrons,helium The density of energy was so great that matter could not exist. As the density was gradually reduced through expansion, matter began to form. Both matter and anti-matter formed, but for some reason, there was a slight excess of matter.Slide9: Originally, no stars Protons and electrons combined into atoms The Universe became opaque due to absorption of light by hydrogen atoms The First Dark EraOrigin of the CMB – the thermal radiation of the first atoms: Origin of the CMB – the thermal radiation of the first atoms Isotropic microwave radiationSlide11: STELLIFEROUS ERA – the current era Atoms condensed into the first generation of stars during the first 200 million years The first stars reheated the gas (reionization) The universe remains transparent because the density is so low Galaxies formed Sun, solar system formed 4.6 billion years ago Life appeared on Earth 3.8 billion years ago Modern humans show up just 100,000 years agoThe Universe in a Day: The Universe in a DaySlide13: DEGENERATE ERA – 10 trillion trillion trillion years after the Big Bang Planets detach from stars Stars and planets evaporate from galaxies Most ordinary matter in the universe is locked up in degenerate stellar remnants Eventually, even the protons themselves decaySlide14: BLACK-HOLE ERA - 10,000 trillion trillion trillion trillion trillion trillion trillion trillion years after the Big Bang The only large objects remaining are black holes Eventually even the black holes evaporate into photons and other types of radiation. Slide15: The Final DARK ERA – Only photons, neutrinos, electrons and positrons remain, wandering through a universe bigger than the mind can conceive. Occasionally, electrons and positrons meet and form "atoms" larger than the visible universe is today. From here into the infinite future, the universe remains cold, dark and empty. The History of the Universe in 200 Words or Less: The History of the Universe in 200 Words or Less Quantum fluctuation. Inflation. Expansion. Strong nuclear interaction. Particle-antiparticle annihilation. Deuterium and helium production. Density perturbations. Recombination. Blackbody radiation. Local contraction. Cluster formation. Reionization? Violent relaxation. Virialization. Biased galaxy formation? Turbulent fragmentation. Contraction. Ionization. Compression. Opaque hydrogen. Massive star formation. Deuterium ignition. Hydrogen fusion. Hydrogen depletion. Core contraction. Envelope expansion. Helium fusion. Carbon, oxygen, and silicon fusion. Iron production. Implosion. Supernova explosion. Metals injection. Star formation. Supernova explosions. Star formation. Condensation. Planetesimal accretion. Planetary differentiation. Crust solidification. Volatile gas expulsion. Water condensation. Water dissociation. Ozone production. Ultraviolet absorption. Photosynthetic unicellular organisms. Oxidation. Mutation. Natural selection and evolution. Respiration. Cell differentiation. Sexual reproduction. Fossilization. Land exploration. Dinosaur extinction. Mammal expansion. Glaciation. Homo sapiens manifestation. Animal domestication. Food surplus production. Civilization! Innovation. Exploration. Religion. Warring nations. Empire creation and destruction. Exploration. Colonization. Taxation without representation. Revolution. Constitution. Election. Expansion. Industrialization. Rebellion. Emancipation Proclamation. Invention. Mass production. Urbanization. Immigration. World conflagration. League of Nations. Suffrage extension. Depression. World conflagration. Fission explosions. United Nations. Space exploration. Assassinations. Lunar excursions. Resignation. Computerization. World Trade Organization. Terrorism. Internet expansion. Reunification. Dissolution. World-Wide Web creation. Composition. Extrapolation? Copyright 1996-1997 by Eric Schulman .Astronomy and Life in the Universe: Astronomy and Life in the Universe When did life arise on Earth? How did life arise on Earth? What are the necessities of life?Scientific Study of Life: Scientific Study of Life Goals: To present what observations of the physical world tell us about the origin and development of life To use that information to suggest what we might expect to find elsewhere in the Universe and how to search for life elsewhereWhen did life arise on Earth?: Life probably arose on Earth more than 3.85 billion years ago, shortly after the end of heavy bombardment Evidence comes from fossils and carbon isotopes When did life arise on Earth?Earliest Fossils: Earliest Fossils Oldest fossils show that bacteria-like organisms were present over 3.5 billion years ago Carbon isotope evidence pushes origin of life to more than 3.85 billion years agoThe Origin of Life on Earth: The Origin of Life on Earth Life on Earth is about 3.5 billion years old Life arose nearly as soon as conditions allowed surface conditions were too hostile before this point Early life was very simple single cell algae Multicelled life arrived about 1 billion years ago simple sponges Complexity increased More advanced forms seem to survive more easily Tree of Life: Tree of Life Mapping genetic relationships has led biologists to discover this new “tree of life.” Plants and animals are a small part of the tree. Suggests likely characteristics of common ancestor.Slide23: These genetic studies suggest that the earliest life on Earth may have resembled the bacteria today found near deep ocean volcanic vents (black smokers) and geothermal hot springs . Laboratory Experiments: Laboratory Experiments Miller-Urey experiment (and more recent experiments) show that building blocks of life form easily and spontaneously under conditions of early Earth. Origin of Oxygen: Origin of Oxygen Cyanobacteria paved the way for more complicated life forms by releasing oxygen into atmosphere via photosynthesis Brief History of Life: Brief History of Life 4.4 billion years - early oceans form 3.5 billion years - cyanobacteria start releasing oxygen. 2.0 billion years - oxygen begins building up in atmosphere 540-500 million years - Cambrian Explosion 225-65 million years - dinosaurs and small mammals (dinosaurs ruled) Few million years - earliest hominidsNecessities for Life: Necessities for Life Nutrient source Energy (sunlight, chemical reactions, internal heat) Liquid water (or possibly some other liquid) Hardest to findThe Habitable Zone: The Habitable Zone For liquid water to exist, a planet needs to be the right distance from the star. WHY? A habitable world contains the basic necessities for life as we know it, including liquid water. It does not necessarily have life. What else do we need?: What else do we need? The orbits of the planets must be stable, and not too eccentric The planet needs to have the right mass--too small and the atmosphere escapes--too large and the atmosphere is made of hydrogen The atmosphere needs to be of the right mix of greenhouse gases Anything else?: Anything else? A Jupiter-like neighbor is nice to catch most of the asteroids and comets that would otherwise hit the planet The planet needs the right tilt--currents mix nutrients--a Uranus tilt would not work A large Moon stabilizes the planet and creates water tides for sloshing around nutrients Our Solar System: Our Solar System Gas Giants Ice Giants Terrestrial PlanetsSearches for Life on Mars: Searches for Life on Mars Mars had liquid water in the distant past Still has subsurface ice; possibly subsurface water near sources of volcanic heat. Slide33: In 2004, NASA Spirit and Opportunity Rovers sent home new mineral evidence of past liquid water on Mars.The Martian Meteorite debate: The Martian Meteorite debate composition indicates origin on Mars 1984: meteorite ALH84001 found in Antarctica 13,000 years ago: fell to Earth in Antarctica 16 million years ago: blasted from surface of Mars 4.5 billion years ago: rock formed on MarsSlide35: Does the meteorite contain fossil evidence of life on Mars? … most scientists not yet convincedCould there be life on Europa or other jovian moons?: Could there be life on Europa or other jovian moons?Slide37: Ganymede, Callisto also show some evidence for subsurface oceans. Relatively little energy available for life, but still… Intriguing prospect of THREE potential homes for life around Jupiter alone… Ganymede CallistoTitan: Titan Surface too cold for liquid water (but deep underground?) Liquid ethane/methane on surfaceSaturn’s Moon Enceladus: Saturn’s Moon Enceladus Cassini spacecraft found water geysersCould life have migrated to Earth from elsewhere in the Solar System?: Could life have migrated to Earth from elsewhere in the Solar System? Venus, Earth, Mars have exchanged tons of rock (blasted into orbit by impacts) Some microbes can survive years in space...Slide41: Last units: 81, 82, 83, 84 You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
A105 025 Cosmo Marcell Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 149 Category: Education License: All Rights Reserved Like it (1) Dislike it (0) Added: January 24, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript A105 Stars and Galaxies: A105 Stars and Galaxies Last units: 81, 82, 83, 84 NQ 13 now online LAST(!) homework & project due today Today’s APODPrinciples of Cosmology: Principles of Cosmology Homogeneity – Matter is spread uniformly through space Isotropy – The Universe looks the same in every direction Universality – The basic principles of physics are the same everywhere The Cosmological Principle: The universe will look more or less the same to observers everywhere, in every galaxy, no matter where it isApplying the Principles of Cosmology: Applying the Principles of CosmologySummary – Strong evidence supports the Big Bang Theory: Summary – Strong evidence supports the Big Bang Theory The Universe is expanding (and cooling) from an initial, dense state Radiation left over from the Big Bang is now detected in the form of microwaves—the cosmic microwave background—which we can observe with a radio telescope Observations of helium and other light elements agree with the predictions for fusion in the Big Bang theoryA brief history of the Universe: A brief history of the Universe Courtesy of Fred Adams University of MichiganSlide6: BIG BANG – 13.7 billion years ago, space, time, and energy burst into existence The part of the Universe that now comprises our “observable universe” was very small and very dense Why did the Universe suddenly appear????Slide7: INFLATION ERA – Regions of the universe rapidly expand from smaller than an atom to bigger than the Solar System. Because all of space was so compact, every part of the universe was in “contact” with every other part. Energy was uniformly distributed throughout the early universeSlide8: PHOTON ERA - energy in the form of electromagnetic radiation dominates the Universe - visible light, X rays, radio waves and ultraviolet rays. Energy transforms into matter: quarks the first nuclei: protons, neutrons,helium The density of energy was so great that matter could not exist. As the density was gradually reduced through expansion, matter began to form. Both matter and anti-matter formed, but for some reason, there was a slight excess of matter.Slide9: Originally, no stars Protons and electrons combined into atoms The Universe became opaque due to absorption of light by hydrogen atoms The First Dark EraOrigin of the CMB – the thermal radiation of the first atoms: Origin of the CMB – the thermal radiation of the first atoms Isotropic microwave radiationSlide11: STELLIFEROUS ERA – the current era Atoms condensed into the first generation of stars during the first 200 million years The first stars reheated the gas (reionization) The universe remains transparent because the density is so low Galaxies formed Sun, solar system formed 4.6 billion years ago Life appeared on Earth 3.8 billion years ago Modern humans show up just 100,000 years agoThe Universe in a Day: The Universe in a DaySlide13: DEGENERATE ERA – 10 trillion trillion trillion years after the Big Bang Planets detach from stars Stars and planets evaporate from galaxies Most ordinary matter in the universe is locked up in degenerate stellar remnants Eventually, even the protons themselves decaySlide14: BLACK-HOLE ERA - 10,000 trillion trillion trillion trillion trillion trillion trillion trillion years after the Big Bang The only large objects remaining are black holes Eventually even the black holes evaporate into photons and other types of radiation. Slide15: The Final DARK ERA – Only photons, neutrinos, electrons and positrons remain, wandering through a universe bigger than the mind can conceive. Occasionally, electrons and positrons meet and form "atoms" larger than the visible universe is today. From here into the infinite future, the universe remains cold, dark and empty. The History of the Universe in 200 Words or Less: The History of the Universe in 200 Words or Less Quantum fluctuation. Inflation. Expansion. Strong nuclear interaction. Particle-antiparticle annihilation. Deuterium and helium production. Density perturbations. Recombination. Blackbody radiation. Local contraction. Cluster formation. Reionization? Violent relaxation. Virialization. Biased galaxy formation? Turbulent fragmentation. Contraction. Ionization. Compression. Opaque hydrogen. Massive star formation. Deuterium ignition. Hydrogen fusion. Hydrogen depletion. Core contraction. Envelope expansion. Helium fusion. Carbon, oxygen, and silicon fusion. Iron production. Implosion. Supernova explosion. Metals injection. Star formation. Supernova explosions. Star formation. Condensation. Planetesimal accretion. Planetary differentiation. Crust solidification. Volatile gas expulsion. Water condensation. Water dissociation. Ozone production. Ultraviolet absorption. Photosynthetic unicellular organisms. Oxidation. Mutation. Natural selection and evolution. Respiration. Cell differentiation. Sexual reproduction. Fossilization. Land exploration. Dinosaur extinction. Mammal expansion. Glaciation. Homo sapiens manifestation. Animal domestication. Food surplus production. Civilization! Innovation. Exploration. Religion. Warring nations. Empire creation and destruction. Exploration. Colonization. Taxation without representation. Revolution. Constitution. Election. Expansion. Industrialization. Rebellion. Emancipation Proclamation. Invention. Mass production. Urbanization. Immigration. World conflagration. League of Nations. Suffrage extension. Depression. World conflagration. Fission explosions. United Nations. Space exploration. Assassinations. Lunar excursions. Resignation. Computerization. World Trade Organization. Terrorism. Internet expansion. Reunification. Dissolution. World-Wide Web creation. Composition. Extrapolation? Copyright 1996-1997 by Eric Schulman .Astronomy and Life in the Universe: Astronomy and Life in the Universe When did life arise on Earth? How did life arise on Earth? What are the necessities of life?Scientific Study of Life: Scientific Study of Life Goals: To present what observations of the physical world tell us about the origin and development of life To use that information to suggest what we might expect to find elsewhere in the Universe and how to search for life elsewhereWhen did life arise on Earth?: Life probably arose on Earth more than 3.85 billion years ago, shortly after the end of heavy bombardment Evidence comes from fossils and carbon isotopes When did life arise on Earth?Earliest Fossils: Earliest Fossils Oldest fossils show that bacteria-like organisms were present over 3.5 billion years ago Carbon isotope evidence pushes origin of life to more than 3.85 billion years agoThe Origin of Life on Earth: The Origin of Life on Earth Life on Earth is about 3.5 billion years old Life arose nearly as soon as conditions allowed surface conditions were too hostile before this point Early life was very simple single cell algae Multicelled life arrived about 1 billion years ago simple sponges Complexity increased More advanced forms seem to survive more easily Tree of Life: Tree of Life Mapping genetic relationships has led biologists to discover this new “tree of life.” Plants and animals are a small part of the tree. Suggests likely characteristics of common ancestor.Slide23: These genetic studies suggest that the earliest life on Earth may have resembled the bacteria today found near deep ocean volcanic vents (black smokers) and geothermal hot springs . Laboratory Experiments: Laboratory Experiments Miller-Urey experiment (and more recent experiments) show that building blocks of life form easily and spontaneously under conditions of early Earth. Origin of Oxygen: Origin of Oxygen Cyanobacteria paved the way for more complicated life forms by releasing oxygen into atmosphere via photosynthesis Brief History of Life: Brief History of Life 4.4 billion years - early oceans form 3.5 billion years - cyanobacteria start releasing oxygen. 2.0 billion years - oxygen begins building up in atmosphere 540-500 million years - Cambrian Explosion 225-65 million years - dinosaurs and small mammals (dinosaurs ruled) Few million years - earliest hominidsNecessities for Life: Necessities for Life Nutrient source Energy (sunlight, chemical reactions, internal heat) Liquid water (or possibly some other liquid) Hardest to findThe Habitable Zone: The Habitable Zone For liquid water to exist, a planet needs to be the right distance from the star. WHY? A habitable world contains the basic necessities for life as we know it, including liquid water. It does not necessarily have life. What else do we need?: What else do we need? The orbits of the planets must be stable, and not too eccentric The planet needs to have the right mass--too small and the atmosphere escapes--too large and the atmosphere is made of hydrogen The atmosphere needs to be of the right mix of greenhouse gases Anything else?: Anything else? A Jupiter-like neighbor is nice to catch most of the asteroids and comets that would otherwise hit the planet The planet needs the right tilt--currents mix nutrients--a Uranus tilt would not work A large Moon stabilizes the planet and creates water tides for sloshing around nutrients Our Solar System: Our Solar System Gas Giants Ice Giants Terrestrial PlanetsSearches for Life on Mars: Searches for Life on Mars Mars had liquid water in the distant past Still has subsurface ice; possibly subsurface water near sources of volcanic heat. Slide33: In 2004, NASA Spirit and Opportunity Rovers sent home new mineral evidence of past liquid water on Mars.The Martian Meteorite debate: The Martian Meteorite debate composition indicates origin on Mars 1984: meteorite ALH84001 found in Antarctica 13,000 years ago: fell to Earth in Antarctica 16 million years ago: blasted from surface of Mars 4.5 billion years ago: rock formed on MarsSlide35: Does the meteorite contain fossil evidence of life on Mars? … most scientists not yet convincedCould there be life on Europa or other jovian moons?: Could there be life on Europa or other jovian moons?Slide37: Ganymede, Callisto also show some evidence for subsurface oceans. Relatively little energy available for life, but still… Intriguing prospect of THREE potential homes for life around Jupiter alone… Ganymede CallistoTitan: Titan Surface too cold for liquid water (but deep underground?) Liquid ethane/methane on surfaceSaturn’s Moon Enceladus: Saturn’s Moon Enceladus Cassini spacecraft found water geysersCould life have migrated to Earth from elsewhere in the Solar System?: Could life have migrated to Earth from elsewhere in the Solar System? Venus, Earth, Mars have exchanged tons of rock (blasted into orbit by impacts) Some microbes can survive years in space...Slide41: Last units: 81, 82, 83, 84