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The American Physical Society's Multi-Divisional Neutrino Study explores the broad field of neutrino physics, focusing on neutrino oscillations, experiments, and the search for new physics. This study aims to create a scientific roadmap for neutrino physics and lay the groundwork for future discoveries and advancements in the field. The study also examines the potential connections between cosmology/astrophysics and neutrino physics. Join this pioneering venture in neutrino physics.
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American Physical Society MultiDivisional Neutrino Study DOE-OS Briefing January 7, 2005 Washington DC Stuart Freedman Boris Kayser
Part I Why study neutrinos? Super KamiokANDE PMT Matrix
Pioneering venture in Neutrino Physics Ray Davis
Neutrino Ocillations E2 = m2c2 B. Pontecorvo E1 = m1c2 In the rest frame Boosted to the lab frame
LMA: m2 = 5.5x10-5 eV2 sin2 2 = 0.833 Reactor Antineutrino Experiments KamLAND
Terrestrial Version of Atmospheric Neutrino Experiment 818 events if no oscillation 56 events observed MINOS (FNAL Soudan) 2005 If no oscillation: 151 11 Observe: 108
KamLAND Is the Neutrino Spectrum Distorted?
Excerpts from the Charge “…response to the remarkable recent series of discoveries in neutrino physics…” “…build on the 2002 long range plans developed by NSAC and HEPAP.” “…examine the broad sweep of neutrino physics…” “…create a scientific roadmap for neutrino physics.” “…move towards agreement on the next steps…” The Study will lay scientific groundwork for the choices that must be made during the next few years.
Neutrino Study Organization • Chairpersons Organizing Committee • Solar and Atmospheric Neutrino Experiments • Reactor Neutrino Experiments • Superbeam Experiments and Development • Neutrino Factory and Beta-Beam Experiments and Development Neutrinoless Double Beta Decay and Direct Searches for Neutrino Mass • What Cosmology/Astrophysics and Neutrino Physics can Teach Each Other Theory Discussion Group Writing Committee
APS Neutrino Study: Midcourse Correction April 1-2, 2004 Berkeley Final General Meeting Snowmass June 28-30 www.aps.org/neutrino
Present US Program in Neutrino Physics NSF NSF DOE NP/HEP DOE NP/HEP DOE NP DOE HEP DOE HEP NASA DOE HEP NSF NP NSF DOE NP DOE HEP
Underground Facilities Many of the past experiments and many of the future experiments we feel are particularly important rely on suitable underground facilities. The availability of these facilities will be crucial to future neutrino research.
Part II The Story SNO
From neutrino flavor change (oscillation) experiments, we have learned that — • Neutrinos have nonzero rest masses • Leptons mix • Neutrino masses — There is some spectrum of 3 or more neutrino mass eigenstates i: 4 3 (Mass)2 2 1 Mass (i) mi
We do not know how many different neutrinos there are. Just 3, the partners of the 3 charged leptons?? If the Liquid Scintillator Neutrino Detector (LSND) experiment is confirmed, there are more than 3. If LSND is not confirmed, nature may contain only 3 neutrinos. Then, from the existing neutrino oscillation data, the neutrino spectrum looks like —
3 3 m2atm 2 2 m2sol m2sol } } 1 1 Normal Inverted or (Mass)2 m2atm ~ ~ m2sol = 8 x 10–5 eV2, m2atm = 2.5 x 10–3 eV2
A grand goal of elementary particle physics is to unify all the forces of nature into a single force. The Grand Unified Theories, which do this for all the forces of nature save gravity, favor — Grand Unified Theories relate the Leptons to the Quarks. is un-quark-like, and would probably involve a lepton symmetry with no quark analogue.
le e, l, l Leptonic mixing — • When W+ l+ + , • the produced neutrino state |> is • |> = U*i |i> . • Neutrino offlavor Neutrino of definite mass mi Unitary Leptonic Mixing Matrix • Flavor- fraction of i = |< |i>|2 = |Ui|2 . e, , or i
Bounded by reactor exps. with L ~ 1 km From max. atm. mixing, { From (Up) oscillate but (Down) don’t { In LMA–MSW, Psol(e e) = e fraction of 2 From distortion of e(solar) and e(reactor) spectra { From max. atm. mixing, 1+ 2 includes (–)/√2 3 m2atm (Mass)2 2 } m2sol 1 [|Ui|2] [|Ui|2] e [|Uei|2]
The Mixing Matrix Solar Atmospheric Cross-Mixing cij cos ijsij sin ij Majorana CP phases 12 ≈ sol ≈ 32°,23 ≈ atm ≈ 36-54°, 13 < 15° would lead to P() ≠ P().CP But note the crucial role of s13 sin 13. ~
Poof! Are Neutrinos the Reason We Exist? The universe contains Matter, but essentially no antimatter. Good thing for us: Matter Antimatter This preponderance ofMatteroverantimattercould not have developed unless the two behave differently. (CP) The observed difference betweenQuarkandantiquarkbehavior, as described by the Standard Model, is inadequate. Could the interactions of Matterandantimatterwith neutrinos provide the crucial difference?
There is a natural way in which they could. The most popular theory of why neutrinos are so light is the — See-Saw Mechanism { Familiar light neutrino } Very heavy neutrino N The heavy neutrinos N would have been made in the hot Big Bang.
In time, they would have decayed into lighter particles. If Matter and antimatter interact differently with these heavy neutrinos N, then we can have — Probability [ Ne- + … ] ≠ Probability [ Ne+ + … ] Matterantimatter in the early universe. This phenomenon (leptogenesis) would have led to a universe containing unequal amounts of Matter and antimatter.
We cannot repeat the early universe. But we can lend credibility to the hypothesis of leptogenesis by showing that Matter and antimatter interact differently with the light neutrinos . A neutrino flavor change involving Matter: - e- Source Detector A neutrino flavor change involving antimatter: + e+ Source Detector If these two flavor changes have different probabilities, then quite likely so do — Ne- + … andNe+ + …
If N decays led to the present preponderance of Matter over antimatter, then we are all descendants of heavy neutrinos.
In Pursuit of 13 If sin2213 < 0.01, a neutrino factory will be needed to study both of these issues. Both CP violation and our ability to tell whether the spectrum is normal or inverted depend on 13. How may 13 be measured?
sin213 3 m2atm (Mass)2 2 } m2sol 1 sin213 is the small e piece of 3. 3 is at one end of m2atm. We need an experiment sensitive to m2atm, and involving e.
Complementary Approaches Reactore disappearance while traveling L ~ 1.5 km. L/E ~ 500 km/GeV. This process depends on 13 alone. Accelerator e while traveling L > Several hundred km. L/E ~ 400 km/GeV. This process depends on 13 and other neutrino properties, including whether the spectrum is normal or inverted.
How To Determine If The Spectrum Is Normal Or Inverted In the experiments we will do with earth-born neutrinos, the neutrinos will travel through earth matter. Exploit the fact that, in matter, e – e interactions raise the effective mass of e.
sin213 sin213 2 3 } m2sol 1 m2atm vs. (Mass)2 m2atm 2 } m2sol 3 1 e If m2atm shrinks (grows) in matter, 13 grows (shrinks).
The effect of matter increases as the neutrino distance of travel within it, L, does. Using larger L to determine whether the spectrum is normal or inverted could be a unique contribution of the U.S. program.
Are Neutrinos Their Own Antiparticles? Does — • i = i (Majorana neutrinos) • or • i ≠ i (Dirac neutrinos) ? • e+ ≠ e– since Charge(e+) = – Charge(e–). • But neutrinos may not carry any conserved charge-like quantum number. • A conserved Lepton Number L defined by—L() = L(l–) = –L() = –L(l+) = 1 may not exist. • If it does not, then i=iand we can have —
i Neutrinoless Double Beta Decay (0) e– e– i W– W– Nuclear Process Nucl’ Nucl • Observation would establish that — • Lepton number L is not conserved • Neutrinos are Majorana particles ( = ) • The origin of neutrino mass is not the same as the origin of the masses of charged leptons, quarks, nucleons, humans, the earth, galaxies Then neutrinos and their masses are very distinctive.
The Quest for the Origin of Mass Neutrino experiments and the search for the Higgs boson both probe the origin of mass. The see-saw mechanism suggests that the physics behind neutrino mass resides at 1015 GeV, the extremely high energy where Grand Unified Theories say all the forces of nature, save gravity, become one.
Neutrinos and the New Paradigm • What are the masses of the neutrinos? • What is the pattern of mixing among the different types of neutrinos? • Are neutrinos their own antiparticles? • Do neutrinos violate the symmetry CP?
Neutrinos and the Unexpected • Are there “sterile” neutrinos? • Do neutrinos have unexpected or exotic properties? • What can neutrinos tell us about the models of new physics beyond the Standard Model?
Neutrinos and the Cosmos • What is the role of neutrinos in shaping the universe? • Is CP violation by neutrinos the key to understanding the matter – antimatter asymmetry of the universe? • What can neutrinos reveal about the deep interior of the earth and sun, and about supernovae and other ultra high energy astrophysical phenomena?
Part III Recommendations for future experiments KamLAND
