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Explore the history, importance, and implications of solar neutrinos, the neutrino mass, oscillations, and the Solar Neutrino Problem, highlighting experiments like Super-K, SNO, and Kamland. Learn about Neutrino Oscillations and Detection methods in this comprehensive overview.
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The Solution to the Solar n Problem Jordan A. Goodman University of Maryland January 2003 • Solar Neutrinos • MSW Oscillations • Super-K Results • SNO Results • Kamland Results • Overall Results
Our current view of underlying structure of matter • P is uud • N is udd • p+ is ud • k+ is us • and so on… }Baryons (nucleons) }Mesons The Standard Model
Neutrinos are only weakly interacting 40 billion neutrinos continuously hit every cm2 on earth from the Sun (24hrs/day) Interaction length is ~1 light-year of steel 1 out of 100 billion interact going through the Earth 1931 – Pauli predicts a neutral particle to explain energy and momentum non-conservation in Beta decay. 1934 - Enrico Fermi develops a comprehensive theory of radioactive decays, including Pauli's particle, Fermi calls it the neutrino (Italian: "little neutral one"). 1959 - Discovery of the neutrino is announced by Clyde Cowan and Fred Reines Facts about Neutrinos
Neutrinos They only interact weakly If they have mass at all – it is very small Why do we care about neutrinos? • They may be small, but there sure are a lot of them! • 300 million per cubic meter left over from the Big Bang • with even a small mass they could be most of the mass in the Universe!
Solar Neutrino Experiment History • Homestake - Radiochemical • Huge tank of Cleaning Fluid • ne + 37Cl e- + 37Ar • Mostly 8B neutrinos + some 7Be • 35 years at <0.5 ev/day • ~1/3 SSM • (Davis - 2002 Nobel Prize) • Sage/Gallex - Radiochemical • “All” neutrinos • ne + 71Ga e- + 71Ge • 4 years at ~0.75 ev /day • ~2/3 SSM • Kamiokande-II and -III • 8B neutrinos only • ne Elastic Scattering • 10 years at 0.44 ev /day • ~1/2 SSM • (Koshiba 2002 Nobel Prize)
Disappearing Neutrinos? • All of these experiments (except SNO) are sensitive mostly to ne • The energies are too low to produce m or t so they can only see neutral current interactions from other flavors • If neutrinos could transform from electron type to muon or tau type the data might be understood • Neutrinos can only “oscillate” if they have different masses • This implies that they have mass! • This would have significant cosmological importance • A neutrino mass of ~20ev would close the Universe • It would also imply violation of lepton flavor conservation
Detecting Neutrino Mass • If neutrinos of one type transform to another type they must have mass: • The rate at which they oscillate will tell us the mass difference between the neutrinos and their mixing
=Electron n =Muon n n1n2 n1n2 Muonn Electronn Neutrino Oscillations
Neutrino Oscillations • Could Neutrino Oscillations solve the solar neutrino problem? • Simple oscillations would require a cosmic conspiracy • The earth/sun distance would have to be just right to get rid of Be neutrinos • Another solution was proposed – Resonant Matter Oscillations in the sun (MSW- Mikheev, Smirnov, Wolfenstein) • Because electron neutrinos “feel” the effect of electrons in matter they acquire a larger effective mass • This is like an index of refraction
MSW Oscillations (Mikheev, Smirnov, Wolfenstein)
Oscillation Parameter Space LMA SMA LOW VAC
Solar Neutrinos in Super-K • The ratio of NC/CC cross section is ~1/6.5
Cherenkov Radiation Aircraft moves through air faster than speed of sound. Sonic Boom Sonic boom
Cherenkov Radiation When a charged particle moves through transparent media faster than speed of light in that media. Cone of light Cherenkov radiation
Detecting neutrinos Cherenkov ring on the wall Electron or muon track The pattern tells us the energy and type of particle We can easily tell muons from electrons
Solar Neutrinos in Super-K • 1496 day sample (22.5 kiloton fiducial volume) • Super-K measures: • The flux of 8B solar neutrinos • Energy spectrum and direction of recoil electron • Energy spectrum is flat from 0 to Tmax • The zenith angle distribution • Day / Night rates • Seasonal variations
Combined Results netonm,t SK+Gallium+Cholrine - flux only allowed 95% C.L. 95% excluded by SK flux-independent zenith angle energy spectrum 95% C.L allowed. - SK flux constrained w/ zenith angle energy spectrum
Combined Results netonsterile SK+Gallium+Cholrine - flux only allowed 95% C.L. 95% excluded by SK flux-independent zenith angle energy spectrum 95% C.L allowed. - SK flux constrained w/ zenith angle energy spectrum
SNO CC Results Fne= (35 ± 3 )% Fssm
Combining SK and SNO • SNO measures Fne= (35 ± 3 )% Fssm • SK Measures Fes= (47 ± .5 ± 1.6)% Fssm • No Oscillation to active neutrinos: • ~3s difference • If Oscillation to active neutrinos: • SNO Measures just Fne • This implies that Fnm,t= ~65% Fssm (~2/3 have oscillated) • SK measures Fes =(Fne + (Fnm,t)/6.5) • Assuming osc. SNO predicts that SK will see Fes ~ (35%+ 65%/6.5) Fssm = 45% ± 3% Fssm
SNO Results (NC/CC) • SNO Results