GADZOOKS! project at Super-Kamiokande

Similar documents
Super-K Gd. M.Ikeda(ICRR) for Super-K collaboration Workshop for Neutrino Programs with facilities in Japan

Status of the Gadolinium project for. Super-Kamiokande. Lluís Martí Magro. Conca Specchiulla, Italy. 5 th of September, 2010.

C02: Investigation of Supernova Mechanism via Neutrinos. Mark Vagins Kavli IPMU, UTokyo

Detection of supernova Neutrinos

Gadolinium Doped Water Cherenkov Detectors

Fossil Records of Star Formation: John Beacom, The Ohio State University

Super-Kamiokande (on the activities from 2000 to 2006 and future prospects)

Super-Kamiokande ~The Status of n Oscillation ~

Recent results from Super-Kamiokande

Neutrino June 29 th Neutrino Probes of Extragalactic Supernovae. Shin ichiro Ando University of Tokyo

Recent results from Super-Kamiokande

Showering Muons in Super Kamiokande. Scott Locke University of California, Irvine August 7 th, 2017

UNO: Underground Nucleon Decay and Neutrino Observatory

The Hyper-Kamiokande project

KamLAND. Studying Neutrinos from Reactor

TIPP Technology and Instrumentation in Particle Physics Research and Development for a Gadolinium Doped Water Cherenkov Detector

M.Nakahata. Kamioka observatory ICRR/IPMU, Univ. of Tokyo. 2016/11/8 M. Nakahata: Neutrino experiments - 30 years at Kamioka 1

PoS(FPCP2017)024. The Hyper-Kamiokande Project. Justyna Lagoda

Search for Astrophysical Neutrino Point Sources at Super-Kamiokande

PoS(NEUTEL2015)009. Recent Results from Super-Kamiokande. Masayuki Nakahata for the Super-Kamiokande collaboration

Diffuse Supernova Neutrino Background

GADZOOKS! How to Detect SN Neutrinos in SK... Next Year!

The Hyper-Kamiodande Project A New Adventure in n Physics

Proton Decays. -- motivation, status, and future prospect -- Univ. of Tokyo, Kamioka Observatory Masato Shiozawa

Searching for Supernova Relic Neutrinos. Dr. Matthew Malek University of Birmingham HEP Seminar 11 May 2011

Radio-chemical method

Detection of Supernova Neutrinos

Neutrinos and Supernovae

Introduction to Super-K and Hyper-K. Roger Wendell Kyoto U. High-Energy Group Meeting

Super-Kamiokande. Roger Wendell, Duke University NNN 2010 Toyama, Japan

Astrophysical Neutrino at HK

Neutrino observatories

Far-field Monitoring of Rogue Nuclear Activity with an Array of Large Antineutrino Detectors

The Hyper-Kamiokande Experiment

Diffuse SN Neutrino Background (DSNB)

Background study for solar neutrino measurement in Super Kamiokande

Introduction Core-collapse SN1987A Prospects Conclusions. Supernova neutrinos. Ane Anema. November 12, 2010

Supernova Neutrino Detectors: Current and Future. Kate Scholberg, Duke University June 24, 2005

Impression of NNN05. Kenzo NAKAMURA KEK. April 7-9, 2005 NNN05 Aussois, Savoie, France. K. Nakamura NNN05, Aussois, April 7-9,

Study of a 200 ton Gadolinium-loaded Water Cherenkov Detector for Super-KamiokaNDE Gadolinium Project

Current Results from Reactor Neutrino Experiments

Outline. (1) Physics motivations. (2) Project status

Supernova Neutrinos in Future Liquid-Scintillator Detectors

NEW νe Appearance Results from the. T2K Experiment. Matthew Malek Imperial College London. University of Birmingham HEP Seminar 13 June 2012

Study of solar neutrino energy spectrum above 4.5 MeV in Super Kamiokande I

Status and Neutrino Oscillation Physics Potential of the Hyper-Kamiokande Project in Japan

Multi-Megaton Water Cherenkov Detector for a Proton Decay Search TITAND (former name: TITANIC)

Potential of Hyper-Kamiokande at some non-accelerator Physics and Nucleon Decay Searches

This is a repository copy of Astroparticle Physics in Hyper-Kamiokande.

Neutrino Oscillation and CP violation

( Some of the ) Lateset results from Super-Kamiokande

PoS(NOW2016)003. T2K oscillation results. Lorenzo Magaletti. INFN Sezione di Bari

Spectrum of the Supernova Relic Neutrino Background

Solar Neutrinos & MSW Effect. Pouya Bakhti General Seminar Course Nov IPM

Neutrinos. Why measure them? Why are they difficult to observe?

The future of neutrino physics (at accelerators)

The Double Chooz reactor neutrino experiment

LOW ENERGY SOLAR NEUTRINOS WITH BOREXINO. Lea Di Noto on behalf of the Borexino collaboration

Topics in Nuclear Astrophysics. John Beacom, Theoretical Astrophysics Group, Fermilab

UNIT1: Experimental Evidences of Neutrino Oscillation Atmospheric and Solar Neutrinos

Tsuyoshi Nakaya (Kyoto Univ.)

The ICARUS Project FRONTIERS IN CONTEMPORARY PHYSICS II. Vanderbilt University, March 5-10, Sergio Navas (ETH Zürich) " Atmospheric neutrinos

Supernova neutrinos and their implications for supernova physics

Recent Results from K2K. Masashi Yokoyama (Kyoto U.) For K2K collaboration 2004 SLAC Summer Institute

LENA. Investigation of Optical Scintillation Properties and the Detection of Supernovae Relic Neutrinos. M. Wurm. January 18, 2006 LENA. M.

章飞虹 ZHANG FeiHong INTERNATIONAL SCHOOL OF SUBNUCLEAR PHYSICS Ph.D. student from Institute of High Energy Physics, Beijing

SciBar and future K2K physics. F.Sánchez Universitat Aútonoma de Barcelona Institut de Física d'altes Energies

EXPLORING PARTICLE-ANTIPARTICLE ASYMMETRY IN NEUTRINO OSCILLATION. Atsuko K. Ichikawa, Kyoto University

Solar Neutrinos: Status and Prospects. Marianne Göger-Neff

Neutrino oscillation physics potential of Hyper-Kamiokande

Daya Bay and joint reactor neutrino analysis

Hyper-Kamiokande. Kenzo NAKAMURA KEK. August 1-2, 2005 Neutrino Meeting IIT-Bombay, Mumbai, India

The Factors That Limit Time Resolution for Photon Detection in Large Cherenkov Detectors

Directional Measurement of Anti-Neutrinos with KamLAND

Recent Results from T2K and Future Prospects

Neutrino Physics with SNO+ Freija Descamps for the SNO+ collaboration

Neutrino Experiments with Reactors

reνolution Three Neutrino Oscillation Lecture Two Lindley Winslow Massachusetts Institute of Technology

Astroparticle physics

XMASS: a large single-phase liquid-xenon detector

Proton Decay searches -- sensitivity, BG and photo-coverage. Univ. of Tokyo, Kamioka Observatory Masato Shiozawa

Applications of nuclear physics in neutrino physics

Reactor On/Off Monitoring with a Prototype of Plastic Anti-neutrino Detector Array (PANDA)

Oak Ridge National Laboratory, TN. K. Scholberg, Duke University On behalf of the COHERENT collaboration August 2, 2017 DPF 2017, Fermilab

Neutrino Oscillations

Recent results on neutrino oscillations and CP violation measurement in Neutrinos

Galactic Supernova for neutrino mixing and SN astrophysics

Astroparticle physics

Neutrinos From The Sky and Through the Earth

Neutrino Experiments: Lecture 2 M. Shaevitz Columbia University

Solar Neutrino Oscillations

The Daya Bay Reactor Neutrino Experiment

The Long-Baseline Neutrino Experiment Kate Scholberg, Duke University NOW 2012

Oklahoma State University. Solar Neutrinos and their Detection Techniques. S.A.Saad. Department of Physics

The T2K experiment Results and Perspectives. PPC2017 Corpus Christi Mai 2017 Michel Gonin On behalf of the T2K collaboration

Observation of Reactor Antineutrino Disappearance at RENO

Recent Discoveries in Neutrino Physics

Solar spectrum. Nuclear burning in the sun produce Heat, Luminosity and Neutrinos. pp neutrinos < 0.4 MeV

Observation of Reactor Antineutrinos at RENO. Soo-Bong Kim for the RENO Collaboration KNRC, Seoul National University March 29, 2012

N u P J-PARC Seminar August 20, 2015

Transcription:

GADZOOKS! project at Super-Kamiokande M.Ikeda (Kamioka ICRR, U.of Tokyo) for Super-K collaboration 2015,6,9@WIN2015 Contents GADZOOKS! project Supernova Relic Neutrino search R&D status and Plan Summary 1

Captures on Gd GADZOOKS! project Identify n ē p events by neutron tagging with Gadolinium in SK. Gadolinium has large neutron capture cross section and emit 8MeV gamma cascade. n e p e + n Gd 8 MeV ΔT~30μs Vertices within 50cm Physics targets: (1) Supernova relic neutrino (SRN) (2) Improve pointing accuracy for galactic supernova (3) Precursor of nearby supernova by Si-burning neutrinos (4) Reduce proton decay background (5) Neutrino/anti-neutrino discrimination (6) Reactor neutrinos γ Gadolinium Antineutrino Detector Zealously Outperforming Old Kamiokande, Super! Beacom & Vagins PRL.93, (2004) 171101 100% 80% 60% 40% 20% 0.1% Gd gives ~90% efficiency for n capture In Super-K this means ~100 tons of water soluble Gd 2 (SO 4 ) 3 0% 0.0001% 0.001% 0.01% 0.1% 1% Gd in Water 2

Supernova Relic Neutrino (SRN) NOW Neutrinos from past SNe 1billion years ago 10 billion years ago Beginning of the universe S.Ando, Astrophys.J. 607, 20(2004) 3 Theoretical flux prediction : 0.3~1.5 /cm2/s (17.3MeV threshold)

Supernova Relic Neutrino (SRN) NOW Neutrinos from past SNe First goal is discovery of SRN 1billion years ago 10 billion years ago Beginning of the universe S.Ando, Astrophys.J. 607, 20(2004) 4 Theoretical flux prediction : 0.3~1.5 /cm2/s (17.3MeV threshold)

Search for SRN at Super-K Search window for SRN at SK : From ~10MeV to ~30MeV Now SRN search is limited by BG. We need BG reduction by the neutron tagging which can be achieved by GADZOOKS! 5

6 EGADS Evaluating Gadolinium s Action on Detector Systems 200 m 3 tank with 240 PMTs Transparency measurement (UDEAL) 15m 3 tank to dissolve Gd Gd water circulation system (purify water with Gd)

EGADS detector: Baby-Kamiokande One of main goals for EGADS is to study the Gd water quality with actual detector materials. Thus, the detector fully mimic Super-K detector. : SUS frame, PMT and PMT case, black sheets, etc. Gd dissolving test has been performed since Oct.2014. (see next page) 7

Transparency of Gd water with PMTs The light left at 15 m in the 200m 3 tank was ~75% for 0.2% Gd 2 (SO 4 ) 3, which corresponds to ~92% of SK-IV pure water average. 8

Where we are now? Now, we are summarizing the R&D results and making a proposal. A committee which was formed to review and evaluate the proposal has started the review. After the review of the committee, we will start collaboration wide discussion in this June. If the proposal is approved, more detailed plan will be made also with T2K members. 9

Summary GADZOOKS! is a project to upgrade Super-K, so that SRN ν ē can be tagged by the delayed coincidence signal from a neutron capture of Gd. EGADS detector was build for R&D of Gd water purification system and check Gd effect to Super-K. EGADS has been keeping a good water quality with the target Gd concentration after PMT installation. Collaboration wide discussion to decide the Gd installation to Super-K will start in June (two weeks). 10

Improvement for Proton decay Neutron multiplicity for P e + p 0 MC 92.5% Zero n Atmospheric n BG Accompany many n If one proton decay event is observed at Super-K after 10 years Current background level: 0.58 events/10 years Background with neutron anti-tag: 0.098 events/10 years Background probability will be decreased from 44% to 9%. 11

Number of supernovae Supernova burst case W/O n-tag n+e ne+p With n-tag n+e ne+p By identifying ne+p events enhance n+e events in angular distribution. Also, it enables us to extract n e + n x spectrum. Pointing accuracy (1000 simulations for 10kpc supernova) tag eff. = 1.0 tag eff. = 0.8 tag eff. = 0.0 Improve pointing accuracy e.g. 4~5 3 (90%C.L.) for 10kpc. 10 kpc supernova 12

13

14

SRN upper limit from SK PRD 85, 052007 (2012) SK combined 90% C.L. (SK4 is not included yet) < 5.1 ev / yr / 22.5 ktons = < 2.7 /cm 2 /s (>16 MeV) (using LMA model spectrum (Ando et.al, 2005) data ν μ CC ν e CC NC elastic μ/π > C. thr. all background relic E (MeV) Low angle events μ, π Signal region p n 42 o e e + n (invisible) E (MeV) E (MeV) Isotropic region 20-38 degrees 38-50 degrees 78-90 degrees n N n reconstructed angle near 90 o 15

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback