The Angra Neutrino Detector

The Angra Neutrino Detector Edgar Casimiro Linares João dos Anjos Centro Brasileiro de Pesquisas Físicas Workshop From Neutrinos to Dark Matter IFUG, Leon, Guanajuato, Mexico 24 25 Aug, 2006

The Angra dos Reis Reactor Neutrino Experiment Neutrino oscillations investigations Safeguards tools development

Angra collaborators UNICAMP CBPF PUC RJ ANL SANDIA LLNL 17 Researchers 14 Physicists 2 Engineers 1 Post Doc 2 Students 1 PhD 1 Undergraduate Several Post docs and students applying

Collaborators João dos Anjos (CBPF) Ronald Shellard (PUC CBPF) Fernando Simão (CBPF) Javier Magnin (CBPF) Ademarlaudo Barbosa (CBPF) Edgar C. Linares (CBPF) Anderson Schilitz (CBPF) Hiroshi Nunokawa (PUC RJ) Ernesto Kemp (UNICAMP) Orlando L. G. Peres (UNICAMP) Marcelo Guzzo (UNICAMP) Renata Z. Funchal (USP) Nathaniel Bowden (SANDIA) Adam Bernstein ( LLNL) David Reyna (ANL) Walter Fulgione (INFN, IFSI Torino)

Topics Motivation for an experiment in Angra The Angra dos Reis Nuclear Plant The Detectors Construction Costs Comparison with other projects Safeguards Concluding Remarks

Angra dos Reis RJ Brazil MG SP RJ Angra II Angra I Angra III

ANGRA III preview

Motivations for the Angra Neutrino Detector Frontier Physics in Latin America Frontier experimental Physics taking advantage of existing nuclear reactors Angra I and Angra II. A third reactor, Angra III is expected to be added in the near future Cost relatively low Possibility to use site to host other future experiments (e.g. GRAVITON Project) Frontier Applied Physics: nuclear safeguards

Physics Motivations: A descoberta do fenômeno de oscilações de neutrinos implica que neutrinos têm massa e que o Modelo Padrão que descreve as interações entre partículas elementares está incompleto. Estas observações podem ter consequências profundas para a astrofísica: violação de CP no setor leptônico pode ser a chave para entendermos a assimetria matéria antimatéria no universo. A extensão mínima do Modelo Padrão requer 3 auto estados de massa, ν 1, ν 2, ν 3 e uma matriz unitária U que relacione a base de estados de massa à base de estados de sabor.

Extensão do Modelo Padrão: A extensão mínima do Modelo Padrão requer sete parametros: 3 massas de neutrinos m 1, m 2 e m 3 3 ângulos de mistura θ 12, θ 23, e θ 13 1 fase δ associada à violação de CP. As probabilidades de oscilação dependem das diferenças de massas ao quadrado m 2 12 = m 2 2 m 1 2 e m 2 23 = m 3 2 m 2 2

Extensão do Modelo Padrão: O desafio experimental no estudo de oscilações de neutrinos é medir com a maior precisão possível os parâmetros θ 12, θ 23, θ 13, m 2 12, m 2 23, e δ. Dados das experiências SNO, KamLAND e Super Kamiokande determinaram θ 12 com precisão de 10% e m 2 12 de 10 20%. Dados de neutrinos atmosféricos de Super Kamiokande e do experimento c/ acelerador K2K determinaram θ 23 e m 2 23 (~10% ) Só existe limite superior para θ 13 pelo experimento de reator nuclear CHOOZ. Medida de θ 13 é fundamental: fase δ de violação de CP só pode ser medida se θ 13 0

Neutrino Mixing Matrix Experimental status 1 0 0 0 c osθ sin θ 0 sinθ cos i δ cosθ13 0 e sin θ 13 cosθ12 sinθ 12 0 0 1 0 si nθ 12 cosθ 12 0 0 0 1 23 23 i δ 23 θ 23 e sinθ 13 0 cos θ 13 Atmospheric Reactores and LBL Solar The parameters θ 23 e m 2 23 can be determined using atmospheric neutrino data observed with the detector SuperKamiokande and in the accelerator experiment K2K (precision ~10% ) Data from experiments SNO, KamLAND and SuperKamiokande can be used to determine θ 12 e m 2 12 within 10 20% precision. So far there exists only an upper limit for θ 13 obtained by an experiment performed with the nuclear reactor CHOOZ. sin 2 (2 θ 13 ) < 0.2

Atmospheric + Accelerator: Θ 23 = (45 ± 7) Solar + KamLand: Θ 12 = (33 ± 3) Neutrino Mixing Matrix = 3 2 1 12 12 12 12 13 13 13 13 23 23 23 23 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 ν ν ν ν ν ν δ δ τ µ c s s c c e s e s c c s s c i i e θ sol θ 13, δ θ atm Reactor (CHOOZ): Θ 13 < 13 (sin 2 (2Θ 13 ) < 0.2)

Motivations for the Angra experiment Scientific Interest : Measurement of θ 13 is important for the investigation of CP violation in the leptonic sector: CP violation phase δ can be measured only if θ 13 0 Physics Advantages of Angra Pure measurement of θ 13, with no matter effects or parameter degeneracy Low cosmic background: shielding of 2.000 m.w.e. High luminosity: (4 GW reactor, 50 and 500 tons detectors) Precise measurement of the energy spectrum

θ 13 & reactor experiments The oscillation signal <E ν > ~ a few MeV only disappearance experiments sin 2 (2θ 13 ) measurement independent of δ-cp 1-P(ν e ν e ) = sin 2 (2θ 13 )sin 2 ( m 2 31 L/4E) + O( m 2 21 / m 2 31 ) weak dependence in m 2 21 Few-MeV ν e + short baselines negligible matter effects (O[10-4 ] ) sin 2 (2θ 13 ) measurement independent of sign( m 2 13 ) @1,05 km

Motivations for the Angra experiment Support from the Nuclear community ELETRONUCLEAR (Company Operating the reactor) CNEN (Comissão Nacional de Energia Nuclear)

Neutrino Reactor Experiments Nuclear Reactors give offν e resulting from the β decay of neutrons coming from fission fragments Copious source: about 10 20 νe s 1 per nuclear core Nuclear Reactor E < 10 MeV Onlyν e produced at reactors Only disappearance experiments possible

How to look for oscillations and measure θ? 13 Oscillation effects are to be observed by comparing the neutrino flux measurements in two detectors installed at different distances from the reactor core The observation of disappearance of electron antineutrinos is the signature of the oscillation and it provides a measure of θ 13

The Concept P(ν e ν e ) = 1-sin 2 (2θ 13 )sin 2 ( m 2 31 L/4E) Mesurement of θ 13 Near detector Far detector Nuclear Reactor Cores Near Detector Far Detector ν e ν e,µ,τ Source of electron antineutrinos 10 21 ν e /s e.g. 280 m e.g. 1050 m

The oscillation signal Far Spectrum Near Spectrum sin 2 (2θ 13 )=0,12 m 2 atm =3.0 10-3 ev 2 @1,05 km Far/Near ratio

Antineutrino Flux Data: Thermal Power: 4 GW Mean Energy per fision: ~ 203.87 MeV Fision Rate: N f =1.22x10 20 fisions/s Number of free protons in a 1 ton scintillator detector: n p = 9.3x 10 28 Mean cross section <σ> E : 5.825x10 43 cm 2 /fision Event rate at a distance L of the core of the reactor N= N f <σ> E n p /(4 π L 2 )

Antineutrino Flux Antineutrino Flux: Φ ν = 1 21 P th [ GW ] 1 2 6. 241 10 s cm 2 4 π D W [ MeV ] D = distance from reactor core [50 m] P th = delivered thermal power [4 GW] W = energy release per fission [203.87 MeV] Φ ν = 0. 4 10 12 s 1 cm 2

Angra dos Reis RJ Brazil MG SP RJ Angra II Angra I Angra III

The Angra dos Reis Nuclear Reactors 3 reactors: 2 in operation + 1 planned Reactor (start of operation) Thermal Power (GW) Duty Cycle Fuel Cycle Angra I (1985) 1.8 80 % ~1,5 years Angra II (2000) 4.0 ~ 1.2 x 10 20 f/s 90 % ~1,3 years Angra III Planned > 2010 4.0

View of the Experimental Layout Morro do Frade Zoom Out Far Site L = 1500 m Tunnel Entrance Angra I Near Site (100m underground)

Configuration Morro do Frade reactors Near Detector (reference): 50 ton (7.2 m diameter) 300 m from reactor 250 mwe. Far Detector (oscillation): 500 ton (12.5 m diameter) 1.500 m from reactor 1.800 mwe. (under morro do Frade ) Very Near Detector: 1 ton (prototype) < 70 m from reactor Detector Design: 3 volumes

Far Site Sites Near Site Reactor Very Near Detector

Protoype (Very Near) Detector D = 66 110 m from core Shielding: 20 < d < 50 mwe reactor detector High rate: ~ 10 3 events /day Little shielding for µ ~ 5 10% dead time with active veto

Configuration Morro do Frade reactors Near Detector (reference): 50 ton (7.2 m diameter) 300 m from reactor 250 mwe. Far Detector (oscillation): 500 ton (12.5 m diameter) 1.500 m from reactor 1.800 mwe. (under morro do Frade ) Very Near Detector: 1 ton (prototype) < 70 m from reactor Detectores Design: 3 volumes

Antineutrino Detection Antineutrino interactions are observed through the inverse beta decay process: + ν e + p e + n Antineutrinos coming from the reactor interact with protons from target (Liquid Scintillator + Gadolinium) The signature of the neutrino interaction is the detection of a prompt positron signal and a (different) neutron delayed (~150 µs) signal

The Detection Principle ν e γ e + γ n Muon veto (plastic scintillator paddles) Central Volume (target) scintillator + Gd (~0.5 g/l) External Volume Gamma catcher (liquid scintillator) PMT s

ν + p e + + e n Prompt event E prompt E ν E n 0.8 MeV Q~1.8 MeV Threshold n + Gd Delayed event Gd * + γ ' s (~ 8 MeV) 0.7-9 MeV 6-11 MeV Prompt e+, E P =1-8 MeV, visible energy Delayed neutron capture on Gd, E D =8 MeV Time correlation: τ 30µsec Space correlation: < 1m 3 Prompt Delayed signals some pulse shape discrimination possible Directionality: weak & statistical (to be studied for the future: R&D)

Very Near (prototype) Detector: 3 volume Design A) Target Liquid Scintillator + Gd B) Gamma Catcher Liquid Scintillator C) Buffer Mineral Oil (8 ) D) Vert Scint Paddles (veto) E) X Y Hor Scint Paddles (veto)

Protoype Detector Status: Proposal submitted to the CNEN (within the framework of cooperation program with IAEA) Installation and localization under discussion with ELETRONUCLEAR (safety considerations) Design and Project: Argonne + CBPF + INFN + LLNL + Saclay + UNICAMP Estimated cost: ~ KUSD 500

Muon Background Intensity vs Depth 10 0 µ vertical intensity (cm 2 s 1 str 1 ) 10 1 10 2 10 3 1x10 4 1x10 5 10 6 10 7 Bugey Palo Verde D Chooz / Braidwood Kaska Daya Bay Angra Kamioka Gran Sasso 10 1 10 2 10 3 10 4 Far Detector Depth (m.w.e.)

Expected Event Rates Detectors Very Near Near Far Signal (Events/Day) 1.800 (50m) 2.500 (300m) 1.000 (1500m) Muon Rate 150 ~ 30 0.3 (Hz)

Background Correlated from cosmic muon induced neutrons. More insidious when neutrons are produced by cosmic muon spallation and capture on materials outside the veto counter protection Uncorrelated hits from cosmic rays and natural radioactivity

ANGRA II: Probability ofν survival E min = 1.8 MeV; 95%@5MeV (Far Detector) e ) ν e P ( ν 1,0 0,9 0,8 0,7 0,6 0,5 0,4 0,3 0,2 0,1 Near Detector: 0.3 km Far Detector: 1.5 km E = 1.8 MeV E = 5.0 MeV E = 1.8 MeV 0,0 0,1 1 10 100 L/E [km/mev]

Costs: civil engineering

Costs: detectors Near 1 ton Detector detector (~1m 3 ) Near Far Detector Far Acrílico (2 esferas concentricas) (scaling from SNO) Aço / Suporte Estrutural (esfera exterior + suportes PMT) Eletronica ($100/canal + $1K/PMT) Óleo Mineral ($553 / ton) $3M $200K $1.2M (1054 Canais) $70K $11.5M $600K $3.6M (3293 Canais) $232K Cintilador Liquido (sem Gadolinium) ($1190 / ton) SubTotal $100K $4.6M $730K $16.7M Total / Detector (design, contingência, etc..ie. X 2) $9.2M $33.4M

h3 Comparison with other ν Reactor Experiments

Diapositiva 41 h3 hepvb, 19/09/2005

2006: 2004: Detector sites Penly Chooz Double Cruas Chooz Braidwood Krasnoyarsk Daya bay Reno Diablo Canyon Kashiwasaki Kaska Taiwan 2002-2004 2006 Angra 1 st generation: sin 2 (2θ 13 )~0.02-0.03 Un complexe de réacteurs 2 cavités @500 m & ~1-2 km 2 nd generation: sin 2 (2θ 13 )~0.01-0.02

2006: Non Proliferation detectors Double Chooz San Onofre Angra 2006

h2 Comparison with other ν Reactor experiments Power <Power> Location Detectors GW th GW th km/ton/mwe Angra 6.0 5.3 Brazil 0.3/50/250 1.5/500/2000 Braidwood 7.2 6.5 Illinois US 0.27/130/450 1.51/130/450 Daya Bay 11.6 (17.4 after 2010) 9.9 (14.8 after 2010) China 0.36/40/260 0.50/40/260 ~1.75/80/910 Double Chooz 8.9 6.8 France 0.15/10.2/60 1067/10.2/300 KASKA 24.3 19.4 Japan 0.35/6/90 [ 2] 1.6/12/260 RENO 17.3 16.4 Korea 0.150/20/230 1.5/20/675

Diapositiva 44 h2 hepvb, 19/09/2005

Comparison with other ν Reactor experiments Reactor Optimistic start date GW t yr (yr) Sin 2 2θ sensitivity for m 2 (10 3 ev 2 ) Efficiencies Far event rate ANGRA 2013(full) 3900(1) 9000(3) 15000(5) 0.0070 0.0060 0.0055 2.5 0.8 0.9 350,000/yr Braidwood 2010 845(1) 2535(3) 7605(9) 0.007 0.005 0.0035 2.5 0.75 41,000/yr Daya Bay 08(fast) 09(full) 3700(3) 0.01 2.5 0.75 0.83 70,000/yr 110,000/yr (before/after 2010) Double Chooz Oct 07(far) Oct 08(near) 29(1) 29(1+1) 80(1+3) 0.08 0.04 0.025 2.5 0.8 0.9 15,000/yr KASKA Mar 08 493(3) 0.015 2.5 0.8 0.88 24,000/yr RENO Late 09 340(1) 0.03 2.0 0.8 18,000/yr

Institutional Responsibilities Experimental Groups construction operation ELETRONUCLEAR approval Communication established! CNEN regulatory submission Support from CNEN and ELETRONUCLEAR Support from CNEN and ELETRONUCLEAR CNEN (Comissão Nacional de Energia Nuclear) ELETRONUCLEAR (company operating the plant)

Motivations for the Angra Experiment Interaction with Industry Área de microeletrônica: desenvolvimento de circuitos para o trigger de múons que serão usados em Angra e Double Chooz: encomendas à indústria Mecânica pesada: construção do vaso do detector e estruturas de suporte Construção civil: construção de laboratório subterrâneo para instalação do detector

Next Steps Geological survey Eletronuclear will help to perform the study Simulations for Detector design: 2 vs. 3 zones Calibration requirements Prototype Site Proposal for testing scintillator and detector development submitted Necessary to understand background effects possible prototype location discussed with Eletronuclear: 66m from reactor

Protoype Detector Test of detector components and Performance studies Geometry, PMT s, scintillators, electronics, backgrounds Understand systematic errors Special Bonus: Neutrino Applied Physics! Nuclear safeguards monitoring for non proliferation of nuclear weapons

non-proliferation

non-proliferation (of nuclear fissile material)

Neutrino Detectors: a new safeguards tool? Antineutrinos have very small interaction cross section, so they easily escape from a reactor ( they cannot be blocked! ). Nuclear reactors are powerful sources of antineutrinos Antineutrinos interact feebly, so detectors need to be big and close to reactor

Non intrusive method to monitor reactor activity Reactor core Flux of antineutrinos Antineutrino detector

Reactor Monitoring Remote, Integral Continuous Real time Non intrusive Unattended

Reactor Monitoring Antineutrinos have specific energy spectrum that varies depending on the reactor fuel composition. Rate and energy spectrum are sensitive to the fissile content of the core (fuel composition). Real data and detailed reactor simulations show a reduction in the antineutrino rate of about 12% through a 600 day cycle - caused by Pu ingrowth and U fission. 200-300 kg of new plutonium is generated in a typical cycle. IAEA and reactor operators the principal customers Counting rate of a detector linearly depends on the reactor power N ν ~ γw th

Safeguards Applications A mission of IAEA (International Atomic Energy Agency) : Safeguard & Verification: control that member states do not use civil installations with military goals (e.g. production of plutonium). Neutrino detector can track unauthorized production of plutonium outside of declarations IAEA interested in the use of neutrino detectors for nuclear reactor monitoring. Recommended a feasibility study on neutrinos. (Meeting with USA, France, Russia authorities in Viena in 2002). Cost problem: inspector::us$ 9.000 /day. One such a detector already in operation: SANDS

SANDS: Safeguards AntiNeutrino Detector System Sandia & Lawrence Livermore National Laboratories in the San Onofre Nuclear Generation Station

An Experimental Test at a Reactor Site 25 meters standoff from core 20 meter overburden San Onofre Nuclear Generating Station Unit II 3.46 GWt

How Does The IAEA Monitor Fissile Material Now? (1 1.5 years) (months to years) (months) (forever) 1. Check Input and Output Declarations 2. Verify with Item Accountancy 3.Containment and Surveillance 1 Gross Defect Detection 2 Continue Item Accountancy 3. Containment and Surveillance 1 Check Declarations 2 Verify with Bulk Accountancy: Operators Report Fuel Burnup and Power History No Direct Pu Inventory Measurement is Made Unless and Until Fuel is Reprocessed

Safeguards Verification Determination of Isotopic Composition of the Spent Fuel is based on the comparison of Simulations (of Initial Composition + Thermal History) and Inventory of Final Composition. Based on Reactor Operator Declarations

Non-proliferation effort Short-Term Goals Perform antineutrino spectrum measurement at Angra Use Very Near Detector as the Prototype for nuclear reactor monitoring Collaboration with Los Alamos, Livermore, Sandia, DoubleChooz, Byproduct for industry: measurement of thermal power @1% precision

The safeguards detector 50 m selected possible localizations

Measure: Burn up ( 239 Pu accumulation) Thermal power

Antineutrino Detectors Have Potential Advantages for Reactor Safeguards This approach provides real time thermal power measurements and Bulk Accountancy of plutonium at the earliest possible moment in the regime Antineutrino detection might replace or complement current techniques, or provide a new capability

Monitoring Reactors with Antineutrino Detectors Cubic meter active volume detector a few tens of meters from reactor core Compare measured and predicted total daily or weekly antineutrino rates (or spectrum) to search for anomalous changes in the total fission rate Identify changes in fissile content based on changes in antineutrino rate (the burnup effect). Measured in several previous experiments

Concept of Operation: Track Power and Changes in Plutonium Loading Through the Antineutrino Rate Predicted daily antineutrino count rate (% of rate at startup) 100% of rate 90 95% of rate Reactor power is proportional to count rate with known fuel loading/geometry shutdown startup days The systematic shift in plutonium inventory is reflected by the changing antineutrino count rate over time Typically there is a 2 3% systematic drop in antineutrino count rate over 6 months

Large amounts of antineutrinos from beta decays of fission products Emission Spectra for different fissile materials

Burn up effect on fuel composition

Antineutrino Rate Varies with Time and Isotope Fuel Composition Antineutrino Fission Rate varies with Isotope Relative Fission Rate vary in Time Pu 241 U 238

The Basic Idea A. Monitor operating reactors with ~1 m 3 antineutrino detectors placed a few tens of meters from the reactor core B. Compare measured and predicted antineutrino rate or spectra to identify changes in fissile content. Pu 241 U 238 Antineutrino count rate relative to beginning of cycle 0.98 0.96 0.94 0.92 0.9 0.88 100 200 300 400 500 600 Full power days

How Does it Work Operationally? The systematic shift in inventory is reflected in the changing antineutrino count rate over time

Daily Power Monitoring Using Only Antineutrinos Antineutrino counts per day 600 500 400 300 200 100 0 2/23/05 2/27/05 3/3/05 3/7/05 3/11/05 3/15/05 3/19/05 Date Predicted count rate using reported reactor power Observed count rate, 24 hour average Reported reactor power 100 80 60 40 20 0 20 Reactor Power (%)

Some experiments to monitor nuclear reactors with neutrino detectors: Rovno (1988-90), Bugey (1994) San-Onofre (2004) Chooz (2002?)

Some Previous and Ongoing experiments Rovno (Ukraine) San Onofre (USA)

Some previous and Ongoing experiments (cont ): Rovno San Onofre 1050 liters of liquid scintillator on mineral oil base + 0.5 g/l Gd, central volume 510 liters 84 PMTs 1 m 3 Liquid scintillator central detector (Gd loaded) 8 PMTs on top side of 4 tanks Passive water shield + Active muon shield

Successful checkings of reactor activity: A n tin e u trin o c o u n ts p e r d a y 600 500 400 300 200 100 0 2/23/05 2/27/05 3/3/05 3/7/05 3/11/05 3/15/05 3/19/05 Date Predicted count rate using reported reactor power Observed count rate, 24 hour average Reported reactor power 100 80 60 40 20 0 20 R e a c to r P o w e r (% ) Rovno (Ukraine) San Onofre (USA)

Reactor Thermal Power and Antineutrino flux Relation between reactor thermal power and antineutrino flux: N ν = γ (1 + k) P th Dependence on detector features Dependence on fuel composition

Remarks (safeguards) Previous experiments demonstrate a good capability of using Antineutrinos for Nuclear reactor distant monitoring. Uncertainty of thermal power measurement can be decreased by accounting fuel composition.

Some International Contacts France Thierry Lasserre CEA/Saclay Double Chooz and AIEA safeguards Italy Walter Fulgione INFN (Torino) Liquid Scintillator doped with Gd, R&D detector USA. David Reyna Argonne Nat Lab Background studies, Detector Design, R&D Adam Bernstein Lawrence Livermore Nat Lab Prototype Design and R&D Nathaniel Bowden Sandia Nat Lab open

Concluding Remarks Fase I Prototype Detector: To develop neutrino detection techniques in Latin America To develop novel technique for nuclear reactor monitoring Science development in Latin America Industry involvement Internacional collaboration with IAEA, ABACC and research labs in USA, France, Italy, Germany and Argentina. ABACC:Agencia Brasileiro Argentina de Contabilidade e Controle de Materiais Nucleares

ABACC + ANGRA Project ASSESSMENT of the TECHNICQUE + IAEA!

Conclusions fase II: Experimental Reach of the Angra Project Até o momento só limite superior para ângulo de mistura θ 13 foi medido pelo experimento de reator nuclear Chooz na França: sin 2 (2 θ 13 ) < 0.2 O experimento de Angra será capaz de alcançar uma sensitividade ao desaparecimento dos antineutrinos da ordem de sin 2 (2 θ 13 ) = 0.006 Angra poderá melhorar o limite estabelecido por Chooz por mais de uma ordem de grandeza! Com o conhecimento de θ 13 será possível medir o parametro δ de violação de CP no setor leptônico (se θ13 0), talvez a chave para entender a assimetria matéria antimatéria no universo!