Recent Discoveries in Neutrino Physics

Recent Discoveries in Neutrino Physics Experiments with Reactor Antineutrinos Karsten Heeger http://neutrino.physics.wisc.edu/

Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Standard Model and Particle Physics Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Neurinos have been with us since the Early Universe

Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Why neutrinos? Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Fig: Murayama neutrinos are the most abundant particles in the Universe besides photons Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

330 neutrinos/cm 3. One billion more neutrinos than protons. Fig: Murayama neutrinos are the most abundant particles in the Universe besides photons Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Heavy Elements: 0.03% Ghostly Neutrinos: ~0.3% Matter in the Universe Stars: 0.5% Free Hydrogen and Helium: 4% Dark Energy: 70% Dark Matter: 25% neutrinos are highly abundant but with little mass What is their nature? What is the role of neutrinos in the Universe? Why is there only matter in the Universe?

Neutrinos and the Early Universe c at T ~ 1 MeV (~ 1 sec) neutrinos decouple relic neutrino spectrum left over at T < 100 kev deuterium formation, followed by BBN n+p d+γ at T < 1 ev (380,000 yrs) photons decouple, cannot break up atoms no more free charges to scatter photons Universe becomes transparent p+e - H+γ

Neutrinos and the Early Universe c 380,000 yrs now

s Massive Neutrinos Play a Role in Large Scale Structure of the Universe Even small neutrino mass influences power spectrum of galaxy correlations Neutrinos that are more massive cause more clustering on large scales. Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

The Big Questions in Neutrino Physics Are neutrinos their own antiparticles? What is the absolute neutrino mass? Is there CP violation? Where did all the antimatter go?

Neutrinos from the Big Bang ~330 neutrinos per cm 3 0.5 proton per cm 3 Supernova Neutrinos Atmospheric Neutrinos High Energy Cosmic Neutrinos Geo Neutrinos Accelerator&Reactor Neutrinos Solar Neutrinos

Neutrino Energies Big-Bang neutrinos ~ 0.0004 ev Neutrinos from the Sun "< 20 MeV depending of their origin. Atmospheric neutrinos" ~ GeV Antineutrinos from nuclear reactors < 10.0 MeV Neutrinos from accelerators up to GeV (10 9 ev)

History of the Neutrino Pauli, 1930 N N + e - electrons! some nuclei emit Chadwick, 1914 Fermi, 1934

First Proposal For Direct Detection of Neutrino

Nuclear Reactors as a Neutrino Source Reactors are intense and pure sources of νe B. Pontecorvo Natl.Res.Council Canada Rep. (1946) 205 Helv.Phys.Acta.Suppl. 3 (1950) 97

Reactor Antineutrinos > 99.9% of νe are produced by fissions in 235 U, 238 U, 239 Pu, 241 Pu pure νe source

Reactor Antineutrinos rule of thumb: ~ 1 event per day per ton of LS per GWth at 1km

1953: Project Poltergeist Experiment at Hanford

Hanford Experiment inverse beta decay ν e + p e + + n Reines, Cowan 300 liters of liquid scintillator loaded with cadmium

Hanford Experiment inverse beta decay ν e + p e + + n Reines, Cowan 300 liters of liquid scintillator loaded with cadmium

Hanford Experiment inverse beta decay ν e + p e + + n Reines, Cowan 300 liters of liquid scintillator loaded with cadmium shielding and background reduction is important

The First 70 Years of Neutrino Physics 3 ν flavors Upper limits on m ν from kinematic studies. Massless ν (ad hoc assumption in SM)

Birth of Neutrino Astrophysics 1938 " Bethe & Critchfield " p + p 2 H + e + + ν e 1947 " Pontecorvo,1949 Alvarez " propose neutrino detection through " 37Cl + ν e 37 Ar + e - Light Element Fusion Reactions p + p 2 H + e + + ν e p + e - + p 2 H + ν e 99.75% 0.25% 2H + p 3 He + γ 85% ~15% ~10-5 % 3He + 3 He 4 He + 2p 3He + p 4 He + e + +ν e 3He + 4 He 7 Be + γ 1960 s Ray Davis builds chlorine detector. John Bahcall, generates first solar model calculations and ν flux predictions. 15.07 % 7Be + e - 7 Li + γ +ν e 7Li + p α + α 0.02% 7Be + p 8 B + γ 8B 8 Be* + e + + ν e to see into the interior of a star and thus verify directly the hypothesis of nuclear energy generation in stars... (Bahcall, 1964)

Cl-Ar Solar Neutrino Experiment at Homestake ν e + 37 Cl 37 Ar + e - 1970-1994 SSM only sensitive to ν e

Sudbury Neutrino Observatory 2092 m to Surface (6010 m w.e.) PMT Support Structure, 17.8 m 9456 20 cm PMTs ~55% coverage within 7 m Acrylic Vessel, 12 m diameter 1000 Tonnes D 2 O Experiment that measures 5300 Tonnes H 2 O, Outer Shield ν e and ν e,µ,τ separately. Urylon Liner and Radon Seal Solar model-independent measurement.

Sudbury Neutrino Observatory

Construction of the Sudbury Neutrino Observatory

The Solution to the Solar Neutrino Problem: Neutrinos Change Flavor 2.0 Neutral Current (NC) Elastic Scattering (ES) Charged Current (CC) CC Neutral-Current shape Elastic Scattering Charged-Current constrained 1.5 Neutrino Signal (SSM/BP00) 1.0 0.5 SSM 5.3 σ 0.0 CC shape unconstrained ν e + ν µ +ν τ Total Neutrino flux ν e + 0.15 (ν µ +ν τ ) ν e Electron Neutrino flux Results from SNO, 2002 2/3 of initial solar ν e are observed at SNO to be ν µ,τ

Neutrinos Oscillate between Three Flavors Electron neutrino Muon neutrino Tau neutrino

Neutrino Oscillation Fermi, 1934 Neutrino States First Mass States Mass states Second First Weak States Weak states Second First Second First Second ν 1 ν 2 ν e ν µ Time Evolution ν 2 ν µ sinθ cosθ ν ν e e a = cos 1 sin 2 ν e b = sin 1 θ + cos 2 θ ν 1 Pure ν µ µ cosθ sinθ ν ( = ) =( )( ν 1 1 ν ) cosθ 2 ν e cosθ sinθ ν µ 2sinθ cosθ ν µ 2sinθ ν 2 Pure ν µ µ Pure ν µ ν 2 2 ν 1 Pontecorvo, 1968 0 Time, t Time, t L P i i = sin 2 2θ sin 2 1.27Δm 2 E

Neutrino Mixing Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Neutrino Oscillation KamLAND 2003 Survival Probability 1 0.8 0.6 0.4 Data - BG - Geo ν e Expectation based on osci. parameters determined by KamLAND 0.2 0 20 30 40 50 60 70 80 90 100 L 0 /E νe (km/mev)

Neutrino Mixing how much? Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Measuring θ13 at Daya Bay Near Far νe νe,x νe,x near 1.1 distance L ~ 1.5 km far θ13 N osc /N no_osc 1 0.9 0.8 0.7 0.6 0.5 0.4 θ 13 detector 1 detector 2 0.3 0.1 1 10 100 Baseline (km)

Nuclear Reactors in the World

Daya Bay Nuclear Power Plant Daya Bay Lind Ao Ling Ao II Daya Bay A Powerful Neutrino Source Among the top 5 most powerful reactor complexes in the world, producing 17.4 GW th (6 x 2.95 GW th ) Hong Kong All 6 reactors are in commercial operation Adjacent to mountains; convenient to construct tunnels and underground labs with sufficient overburden to suppress cosmic rays Reactors produce ~2 10 20 antineutrinos/sec/gw

Daya Bay Experiment Layout RPCs outer and inner water shields (IWS and OWS) automated calibration units (ACU) AD Gd-LS target concrete antineutrino detectors (AD)

Daya Bay Experiment Layout Hall 3: began 3 AD operation on Dec. 24, 2011 Hall 2: began 1 AD operation on Nov. 5, Hall 20112: began 1 AD operation on Nov. 5, 2011 Hall 1: began 2 AD operation on Sep. 23, Hall 2011 1: began 2 AD operation on Sep. 23, 2011

Antineutrino Detector Assembly detector assembly in pairs Jan 2010

Antineutrino Detector Installation - Near Hall Karsten Heeger, Univ. of Wisconsin NUSS, July 13, 2009

Antineutrino Rate vs. Time Detected rate strongly correlated with reactor flux expectations IBD rate (/day) 800 600 400 EH1 Predicted (sin 2 13 = 0) 2 Predicted (sin 2 13 = 0.089) Measured 2 D1 off IBD rate (/day) 800 600 400 EH2 L2 on L1 off L1 on L4 off IBD rate (/day) 100 EH3 80 60 40 Dec 27 Jan 26 Feb 25 Mar 26 Apr 25 Run time Predicted Rate assumes no oscillation. Normalization is determined by fit to near detector data.

Rate Deficit & Near/Far Ratio N detected / N expected 1.15 1.1 1.05 1 2 70 60 50 40 30 20 10 0 5 3 1 0 0.05 0.1 0.15 sin 2 2 13 0.95 EH1 EH2 θ 13 0.9 EH3 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 Weighted Baseline [km] sin 2 2θ 13 = 0.089 ± 0.010 (stat) ± 0.005 (syst) Most precise measurement of sin 2 2θ13 to date.

One of 10 Breakthroughs of the Year 2012 Science Magazine

The Big Questions in Neutrino Physics Neutrino mass and mixing # # Evidence for Physics beyond Standard Model Are neutrinos their own antiparticles? What is the absolute neutrino mass? Is there CP violation? Where did all the antimatter go?