a)! 0-10 miles b)! miles c)! miles d)! miles

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How far away from this classroom will you be for Thanksgiving? a)! 0-10 miles b)! 10-100 miles c)! 100-1000 miles d)! 1000+ miles This Class (Lecture 33): The Early Universe HW 11 due on Dec 5 th Music: The Universe is You Sophie Ellis-Bextor! The Early Universe! Making the first Atoms

These small perturbations in temperature are the fluctuations (smaller than 1 in a 100,000) that caused the large scale structures we see today. This is what formed galaxies. All of this happened only 400,000 years after the Big Bang.! The CMB looks very much the same all over the sky! Thus, regions A and B were very similar to each other when the radiation we observe left them! But there has not been enough time since the Big Bang for them ever to have interacted physically with one another! Why then do they look the same? THE VERY EARLY UNIVERSE Since Big Bang works well so far, we have confidence to think about very early times: t << 1 sec!! Temperature and energies are ultrahigh Q: How to probe such high energies? Hint: it s in the Great State of Illinois Fermilab (okay and also Cern)

INNER SPACE / OUTER SPACE Fermilab is a telescope! Probes conditions in Universe at 10-12 s Universe was 10 12 K hot! but also To better understand the early Universe, we need to talk about a few topics first: 1.! Basic Particles 2.! Matter and Anti-matter The Universe is the poor man s accelerator Probes conditions inaccessible at laboratories! There are three types of basic particles in nature! Quarks - matter! Building blocks of protons and neutrons! Leptons - matter! Electrons and neutrinos! Force Carriers - energy! Photons, gluons, gravitons?! There are three types of basic particles in nature! Quarks - matter! Building blocks of protons and neutrons! Leptons - matter! Electrons and neutrinos! Force Carriers - energy! Photons, gluons, gravitons? http://sol.sci.uop.edu/~jfalward/elementaryparticles/elementaryparticles.html http://sol.sci.uop.edu/~jfalward/elementaryparticles/elementaryparticles.html

! You, and I, and the Earth are all made of matter not anti-matter! The Moon is made of matter, not anti-matter! Local neighborhood in Milky Way is matter, gas between the stars! The Universe is made of matter! How did this come to be?! Partner for each type of matter particle! Anti-electron=positron, anti-quarks, anti-neutrinos! Anti-matter is stable by itself! Can have anti-protons, anti-atoms, anti-rocks, anti-people, anti-stars, anti-galaxies! But when matter & anti-matter partners combine! Annihilation matter converted to energy E=mc 2! Example: paperclip + anti-paperclip annihilation Energy release equal to a small nuclear bomb!! The basic particles that make up protons and neutrons (held together by gluons ) 10-15 m Proton (charge +1) = 2 up quarks (+4/3) + 1 down quark (-1/3) Neutron (charge 0) = 1 up quark (+2/3) + 2 down quarks (-2/3)

! H is made up of a proton and an electron.! Electrons are around at this point, but no protons yet.! So, we have to get the quarks to cool down and get together! A social for particles! Incredibly hot (more that 10 32 K)! Want a Nobel Prize? Develop a theory to describe this era of the Universe!! GUT = Grand Unified Theory! Sea of free quarks (and antiquarks) + photons + other basic particles! Random fluctuations in density http://www.powersof10.com/powers/power/-16.html

! In the early Universe, the photons were so energetic that photons could convert into matter/ anti-matter pairs! The particles created would soon annihilate and convert back to energy! Universe went through a period of extremely rapid expansion! Expansion by more than a factor of 10 50!!! Areas that were close before inflation were now separated by millions of parsecs! Regions that were close enough to interact in the early Universe were separated by inflation!! Early Universe: a sea of particles & energy! Density was constantly fluctuating on microscopic scales! Inflation: blew up microscopic fluctuations to galaxy-size 10-25 cm Before inflation 10 25 cm = 3 Mpc After inflation

! 10-6 seconds: free quarks condensed into protons and neutrons After Protons and neutrons Before Free quarks PROTON COUNTY JAIL J. Gluon, Sheriff 10 31 years to life Little chance of parole The seeds of Galaxies were due to? a)! Large super structures in the early Universe. b)! Nuclear strong force fields. c)! Quantum fluctuations in quark density. d)! Gravitational instabilities in the fabric of spacetime. e)! Unclear reasons.! Began with a Big Bang! 13.7 billion years ago! Still expanding and cooling! The rate of expansion is known and something weird going on there! It is BIG! As far as we are concerned, it is infinite in any direction! The universe is homogeneous and isotropic! Homogeneous - The same stuff everywhere! Isotropic - The same in all directions! Our place in the Universe is not special! Extension of the Copernican revolution! The center of the Universe is everywhere!! Big Bang: 13.7 billion years ago! GUT era: +10-35 second, energy and quarks! Inflation: 10-35 to 10-32 seconds, Universe expands by more than 10 50!! Quark confinement: 10-32 to 10-6 seconds, protons and neutrons form

! 10-4 seconds:! Temperature dropped below the level at which photons have enough energy to create proton-anti-proton pairs! Remaining pairs annihilated! radiation! 1 proton in 10 9 had no partner! That s us.! The first hydrogen atoms (ionized no electrons but there) When the Universe was 1 sec to 3 mins old, the temperature fell to 10 9 K and protons and neutrons can shack-up to form the first light elements. p p (a proton) Before After Also: Deuterium End Result: Big Bang Correctly Predicts Abundances Nutrition Facts Serving Size 1 g Servings Per Universe many many Amount Per Serving Hydrogen 0.75 g Helium. 0.25 g Deuterium... 10-4 g Lithium, etc.... 10-10 g! In early Universe, photons were energetic, kept atoms ionized! protons and electrons couldn t make neutral hydrogen atoms! After 380,000 years, photons couldn t ionize hydrogen anymore! Expansion of space stretched photons wavelengths! Not enough energy to ionize hydrogen! Universe became transparent to photons! This radiation is the source of the Cosmic Microwave Background!! The first H atoms proper!

How did Hydrogen first appear in the Universe? a)! When the Universe cooled and quarks combined to form the first protons, eventually gaining an electron. b)! When the Universe cooled and the melted protons reformed, eventually gaining an electron. c)! When the Universe cooled and the antimatter turned into matter, eventually gaining an electron. d)! When the Universe cooled and the hydrogen atoms fused into helium atoms, eventually gaining an electron. e)! They always existed. These small perturbations in temperature are the fluctuations (smaller than 1 in a 100,000) that caused the large scale structures we see today. This is what formed galaxies. All of this happened only 380,000 years after the Big Bang. ct c(t 3.8x105 yr) t = age of Universe Surface of last scattering

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