Part I: The Dawn of Time Topics within Part I. 1. Origins of the Universe: from the Infinite to the Subatomic. 2. Planets and Meteorites: Neighbors in Space 3. Birth of the Earth and Moon: a Coupled System 4. Segregation of Earth Layers: Building a Dynamic System 5. Radioactive Clocks and Geological Time: Absolute and Relative Time Origins of the Universe Thematic Questions Beginnings of the Universe How was it formed? The Age of the Universe How old is it? How can its age be determined? History of the Universe How has the universe changed over time? Composition of the Universe What is it made of? How is it configured? Dimensions of the Universe How expansive is it? Is it finite or growing? 1
Origins of the Universe From the Infinite to the Sub-Atomic The Big Bang theory Evidence for the origins of time The Age of the Universe Approaches to dating the universe History of the Universe Sequence of events that created matter Evidence for these events Size of the Universe Assessment of its finite dimensions Origins: The Big Bang Theory Evidence for Expansion Expansion and age of the universe Evidence from recession of distant galaxies Hubble s law Systematic Expansion: growth like the 2-D surface of a Balloon 2
Doppler Effect: Wavelength Shift A: Approaching wavelengths are blueshifted (shortened) B: Receding wavelengths are redshifted (lengthened) Absorption lines of stars are shifted A B Each absorption line is red shifted Reference spectrum Absorption lines from star Expansion of the Universe: Red Shift Wavelengths of discrete spectral lines are shifted by stretching (Doppler effect) Blue red Red infrared. Shift increases with distance of object from observer 3
Evidence for Universe Expansion Hubble s Law V = H o r V is recessional velocity (calc.from Doppler red shift) H o is Hubble constant r is distance (in megaparsecs) Assumes Expansion is uniform throughout the universe Recessional velocity is proportional to distance Hubble Analogy for Expansion Raisin Bread Distance between the raisins increases uniformly as the bread expands Changes are proportional to original distances 4
Age of the Universe Observations Velocities Red shift Distance Cepheid variables Stars that blink Luminosity is related to period Distance can be calculated from luminosity and measured brightness Recession Velocity (10 7 m/s) 40 30 20 10 0 Distance from our galaxy (10 25 m) 0 4 8 12 Hubble s law Image from Hubble telescope Billion years (Ga) after Big Bang 5 10 13.7 15 Events at the Beginning of Time Sequence of Events Singularity Single, infinitely small point of infinite mass or energy Cannot be observed, surrounded by event horizon Planck era (10-43 s) Quantum physics begins Spacetime foam Black holes and wormholes Spatial variability Forces and subatomic particles Spacetime foam: Spatial variability 5
Energy and Matter Sequence of Events (continued) Primordial fireball (1s; temperature >10 10 K) Radiation era Only elementary particles Protons (p), electrons (e), positrons, photons, neutrons (n) Formation of matter (1s; temperature 4000K) Simplest atom H (1e,1p) from neutron decay Deuterium 2 H (1p, 1e, 1n), 3 He, 4 He (2p, 2e, 1n or 2n) Cosmic Microwave Background Radiation Atom formation; ~0.5Ma after Big Bang (afterglow) Expanding gas cloud of H and He, gathers in gravitational clusters to form galaxies Physics of the Beginning of Time quarks, leptons created; inflation spacetime foam 4 forces established; leptons split into neutrinos & electrons; gravity governs expansion quarks make protons and neutrons neutrinos decouple gravitons electrons/positrons annihilate; photons few electrons survive black neutrinos/anti-neutrinos fusion of H and He leptons holes electrons electrons/positrons galaxies, quarks protons 76% H stars, neutrons 24% He planets form gravitational force photons supergravity electroweak weak force decouple grand force = CMB electromagnetic force unified force strong nuclear force Time (s) 10-43 10-35 10-11 10-6 Temp. (K) 10 31 10 27 10 15 10 12 1 10 9 15 10 7 60 500k 10 7 3000 10G 3 6
Cosmic Microwave Background Radiation (CMB) Remnant Radiation from Formation of Atoms Original image Milky Way Enhanced image, with irregularities Events in the Early Universe Sequence of Events Inflation Formation of 2H and He Cosmic Microwave Background Matter forms Last Scattering of CMB Temperature decreases with time 7
Vision of Cosmic Microwave Background Radiation (CMB) Analogy: Surface of Last Scattering The cosmic microwave background radiation s surface of last scatter is analogous to light passing through clouds Present day Big Bang + 13.7Ga Only the surface of the cloud where light was last scattered is visible History of Universe Expansion Non-Uniform Rate of Expansion Initial Rapid Expansion (Inflation) Subsequent Progressive Growth 8
Galaxies and Star Clusters Formation of Stars and Galaxies Evidence for early firestorm of star birth Galaxies created by merging of gas clouds and star clusters or perhaps remnant colossal clumps from the break-up of the early universe? What was the role of gravity? Gathered early stars? Spiral galaxy (Andromeda) Elliptical galaxy Star cluster (Omega centauri) Dimensions of the Universe Olber s Paradox Night sky is not uniformly bright Conclusion: the number of stars cannot be infinite If infinite a star would occur in every direction observer universe of stars night sky 9
Dimensions of the Universe Olber s Paradox (continued) Light blocked by dust? the dust would glow Non-uniform distribution? perhaps, but no direct evidence in support of this idea Expanding? distant stars red-shifted into obscurity Young? light from distant galaxies hasn t reached Earth Finite number of active stars? limits on available light Hubble telescope deep field image: early galaxies and star clusters Observation of Ancient Galaxies Hubble Ultra Deep Field Image Young Galaxies Formed in a universe only 0.4 to 0.7 Ga old 10