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The Ghostly Neutrino Steve Boyd, University of Warwick
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“If we are to understand “why we are here” and the basic properties of the universe we live in, we must understand the neutrino.” American Physical Society Report - 2004
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A little bit of history What are they? Where do they come from? Why study them? A recent surprise The T2K Project
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CRISIS
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Energy(Ra) ≠ Energy(Ac)+Energy(e)
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“At the present stage of atomic theory we have no arguments for upholding the concept of energy balance in the case of b-ray disintegrations.” Neils Bohr
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Wolfgang Pauli “Desperate remedy.....” “I do not dare publish this idea....” “I admit my way out may look improbable....” “Weigh it and pass sentence....” “You tell them. I'm off to a party”
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Energy(Ra) ≠ Energy(Ac)+Energy(e)
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Energy(Ra) = Energy(Ac)+Energy(e) + Energy(Neutrino)
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What are neutrinos?
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Electron, e Tiny mass ( 1 ) -
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Electron Neutrino, n e 0 Very tiny mass (<0.0000001) Electron, e Tiny mass ( 1 ) -
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x 500
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Very tiny mass (<0.0000001) e nene e nene Electron Neutrino, n e 0 Very tiny mass (<0.0000001) Electron, e Tiny mass ( 1 ) -
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In experiments neutrinos are NEVER seen. We can only detect them through the byproducts of their interactions with matter. Type of the charged particle detected used to infer the type of incoming neutrino. e e
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Electron Neutrino, n e Electron, e mass ( 1 ) - Muon Neutrino, n m Muon, m mass ( 200 ) - Tau Neutrino, n t Tau, t mass ( 3500 ) - 3 Lepton Types
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m nene t nene
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Electron Antineutrino, n e Positron, e + mass ( 1 ) + 3 Antiparticles Muon Antineutrino, n m Muon, m + mass ( 200 ) + Tau Antineutrino, n m Tau, t + mass ( 3500 ) +
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Where do they come from?
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Everywhere
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From the Big Bang Artist's conception
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From the Big Bang Artist's conception One cubic foot of space contains about 10,000,000 neutrinos left over from the Big Bang.
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From Astrophysical Objects Supernovae created the heavy elements (us) and neutrinos appear to be important to the explosion dynamics.
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From the Sun ≈ 70 million per cm 2 per second at the Earth
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From Cosmic Rays.
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Geoneutrinos
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From Us.
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So why don't we notice? n are almost ghosts. They interact extremely weakly with matter. To a neutrino a planet is mostly empty space.
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"The chances of a neutrino actually hitting something as it travels through all this howling emptiness are roughly comparable to that of dropping a ball bearing at random from a cruising 747 and hitting, say, an egg sandwich." Douglas Adams
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500,000,000,000,000 solar n just went through you
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enpnenpn enpnenpn enpnenpn enpnenpn enpnenpn enpnenpn enpnenpn
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Why do we study them?
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Probes of environments that we otherwise cannot see Probes of objects too far away for anything else Cosmological and astrophysical implications Matter/Antimatter imbalance
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Probes of environments that we otherwise cannot see Probes of objects too far away for anything else Cosmological and astrophysical implications Matter/Antimatter imbalance NEUTRINO ASTROPHYSICS
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Probes of environments that we otherwise cannot see Probes of objects too far away for anything else Cosmological and astrophysical implications Matter/Antimatter imbalance
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Universal Structure m eVm eV m eVm eV
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Probes of environments that we otherwise cannot see Probes of objects too far away for anything else Cosmological and astrophysical implications Matter/Antimatter imbalance
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Why is there more matter than antimatter? =
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Sub-Atomic Talk Show Disasters
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CP Violation Q. Is there a difference between the physics of matter and antimatter? A.Yes there is. We study this here with an experiment called BaBar “B 0 / B 0 mixing”
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Q. Is there a difference between the physics of matter and antimatter? A.Yes there is. We've never seen it in neutrinos, though. Matter-Antimatter Asymmetry n n n n n n n n n n n n “Leptogenesis”
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How to study this?
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Neutrino Oscillations THE discovery in neutrinos of the last 20 years l nlnl l nlnl A typical neutrino experiment
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The Sun is Broken!!! Ray Davis – Early 1970s
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An atom a day 1 Ar atom every two days Only
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Less than expected Expected Measured Number n observed
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Neutrino Oscillations THE discovery in neutrinos of the last 20 years e nene m nmnm Neutrinos were changing flavour between sun and detector!
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Distance Travelled Prob. It is n e 0 1 e nene m nmnm
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Eh? Q. How can a n e spontaneously turn into a n m ?
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Eh? Q. How can a n e spontaneously turn into a n m ? A. The n e isn't a particle. It's three! n e ≡ “that thing which was always produced/detected with an electron” e nene
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Quantum Stuff e nene e n1n1 e n2n2 e n3n3 = or 60% 30% 10%
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e nene m nmnm Original n 1,n 2,n 3 mixture Different n 1,n 2,n 3 mixture n 1,n 2,n 3 travels at different speeds This can only happen if n 1,n 2,n 3 have different masses Only gives us differences in masses Long journey
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Why so important? The Standard Model of Particle Physics has no explanation for a non-zero, but tiny, neutrino mass – so we are in “unknown physics” territory. Neutrino masses link to GUT theories. Has cosmological implications (mass balance, structure)
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The T2K Experiment
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University of Warwick University of Sheffield Imperial College, University of London Oxford University University of Liverpool University of Lancaster Queen Mary College, University of London Rutherford-Appleton Laboratories
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295 km
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JPARC Facility
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TARGET nmnm
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295 km
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Super-Kamiokande nmnm nene
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Water Cerenkov
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Electron-like : has a fuzzy ring Muon-like : has a sharp edged ring and particle stopped in detector.
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Open Questions How much do n 1,n 2 and n 3 weigh? Why are they so much lighter than all the other massive particles? Are neutrinos the same as antineutrinos? Are neutrinos the reason we are here at all?
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‘‘...these kind of findings have implications that are not limited to the laboratory. They affect the whole of society — not only our economy, but our very view of life, our understanding of our relations with others, and our place in time.’’ Bill Clinton
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L sin 2 (2q) Dm 2 = m 1 2 -m 2 2
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Why do blue sky research? 5% of jobs in UK are in physics-based sectors Gross added value from physics sectors was estimated to be 70 billion pounds in 2005 Synergy between PP projects and industry – industry acquires added skills base for other applications Training - 50% of PP PhDs go into other sectors Radioisotope production Sensors for medical applications High level computing for biological modelling Spin off tools for other science (e.g. DIAMOND) Nuclear fusion research Muon tomography in border security Airport scanners Rock Imaging Cancer treatment using next gen cyclotrons
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