Welcome

Current Status of Neutrino Oscillations

• David Wark (Oxford University / RAL)

First Results and Prospects of the NOvA Experiment

• Peter Shanahan (Fermilab)

Theory - neutrinos and dark matter

• Michal Malinský (Charles University (CZ))

Recent results from RENO and prospects with RENO-50

• Soo-Bong Kim (Seoul National University)

Reactor Experiment for Neutrino Oscillation(RENO) has observed the disappearance of reactor electron antineutrinos to measure the smallest neutrino mixing angle theta13. The experiment has analyzed roughly 800 days of data to make an accurate measurement of the reactor neutrino flux and spectral shape, and has found an excess in the region of 5 MeV relative to the most commonly used model. Based on energy and baseline dependent disappearance of reactor neutrinos, we have extracted the neutrino oscillation frequency. In this talk, I will present a new measured value of theta13 and our first measurement of |Dm_ee^2|, and introduce a future experiment of RENO-50 to determine the neutrino mass ordering.

Recent Results from the Daya Bay Reactor Neutrino Experiment

• En-Chuan Huang

The Daya Bay Reactor Neutrino Experiment is designed to precisely determine the mixing parameter theta13 via the relative measurements of antineutrino events by the eight identically designed antineutrino detectors at various baselines. The observation of non-zero theta13 is critical for the search of CP violation in neutrino physics. In this talk, I will present the latest results of the precise measurement of the parameters theta13 and |Dm^2_ee|, an independent measurement of theta13 via the neutron capture on hydrogen, the absolute measurement of the rate and energy spectrum of reactor neutrinos, and a search for sterile neutrino in the mass splitting range of 0.001 eV^2 < |Dm^2_41| < 0.3 eV^2.

Latest results from the Double Chooz experiment

• Marianne Göger-Neff

Double Chooz aims at a precise measurement of the neutrino mixing angle theta13 through the disappearance of reactor electron anti-neutrinos. The experiment relies on the measurement of neutrino flux and spectrum with two identical detectors at different distances from a nuclear power reactor: 1 km and 400 m from the reactor cores. Double Chooz has been running since 2011 with the far detector only, providing the first indication for non-zero theta13 with reactor neutrinos. Data taking with the near detector has finally started beginning of 2015. The talk will review the most recent results obtained with the far detector only, and discuss first data from the near detector.

DUNE: The Deep Underground Neutrino Experiment

• Mark Andrew Thomson (University of Cambridge (GB))

Fermilab is undertaking an ambitious program of long- and short-baseline neutrino oscillation experiments utilizing large Liquid Argon (LAr) TPC detectors. The flagship of this program is the DUNE/LBNF project, which is the highest priority of the US domestic particle physics program in the next decade. A high-power neutrino beam will be fired 1300 km from Fermilab towards a 40,000 ton LAr-TPC detector, located a mile underground at the Sanford Underground Research Facility in South Dakota. In this seminar, I will review the scientific goals of DUNE, focussing on neutrino physics and, in particular, the potential for the first definitive observation of CP violation in the leptonic sector. I will discuss the current status of the LBNF/DUNE and the recent rapid progress that has been made towards its realization as a truly international project.

T2K and Hyper Kamiokande

• Alain Blondel (Universite de Geneve (CH))

Features and goals of the JUNO neutrino oscillation experiment

• Gioacchino Ranucci (Istituto Nazionale di Fisica Nucleare)

The high, and somewhat unexpected, value of the mixing angle theta13 recently measured by Day Bay, Reno and Double Chooz makes experimentally accessible the method proposed over ten years ago by Piai and Petcov for determining the neutrino mass hierarchy through the measurement with a liquid scintillator detector, of large mass, of the spectrum of the anti-neutrinos from a high power nuclear reactor, located at medium distance (a few tens of km) from the detector itself. It is in this context that the proposal for the experiment JUNO in China, 50 km away from a dual nuclear complex under construction, has been formulated. In this talk, after the description of the physics capabilities of the experiment, which include the crucial measure of the mass hierarchy, as well as a rich astroparticle program, I will illustrate the technical characteristics of the set-up, with particular emphasis on the technological challenges which have to be addressed and resolved along the path towards the concrete assessment of the neutrino hierarchy.

The opportunity offered by the ESSnuSB project to exploit the larger leptonic CP violation signal at the second oscillation maximum and the requirements of this project on the ESS accelerator complex

• Tord Ekelöf (Uppsala University)

The ESS neutrino Super Beam, ESSnuSB, operated with a 2.0 GeV linac proton beam, together with a large underground Water Cherenkov detector located at 540 km from Lund, close to the second oscillation maximum, will make it possible to discover leptonic CP violation at 5 sigma significance level in 56 percent (65 percent for an upgrade to 2.5 GeV beam energy) of the leptonic Dirac CP-violating phase range after 10 years of data taking. The paper gives an overview of the proposed facility and presents the outstanding physics reach possible for CP violation with ESSnuSB.

The CERN Neutrino Platform

• Marzio Nessi (CERN)

The CERN Neutrino Platform is CERN’s undertaking to foster and contribute to fundamental research in neutrino physics at particle accelerators worldwide, as recommended by the 2013 European Strategy for Particle Physics. It includes the provision of a facility at CERN to allow the global community of neutrino experts to develop and prototype the next generation of neutrino detectors. It includes the active participation of CERN in Neutrino Experiments worldwide. The CERN Neutrino Platform is CERN’s main contribution to a globally coordinated programme of neutrino research.

PROSPECT- a precision short baseline reactor antineutrino experiment

• Karin Gilje (Illinois Institute of Technology)

Comparison of reactor antineutrino flux and spectrum measurements to model predictions have revealed an apparent deficit in the reactor antineutrino interaction rate and an unexpected spectral deviation. PROSPECT, the Precision Reactor Oscillation and Spectrum experiment, is designed to make a precision measurement of the antineutrino spectrum from a research reactor and search for signs of sterile neutrinos. PROSPECT will be located near the High Flux Isotope Reactor (HFIR) at the Oak Ridge National Laboratory. The Highly Enriched Uranium fuel used by HFIR will allow a measurement of the pure U-235 antineutrino spectrum providing constraints on reactor models and improving our understanding of the reactor antineutrino spectrum predictions. Additionally, the planned 2-ton 6Li-doped liquid scintillator detector is ideally suited to perform a search for sterile neutrinos on the eV-scale. This talk will focus on the sensitivity and discovery potential of PROSPECT and describe the current R&D efforts and the detector design needed to achieve these goals.

Beta-spectroscopic constraints on neutrino masses and status of KATRIN

• Otokar Dragoun

Precision measurements of the endpoint region of tritium beta-spectrum have provided the best upper limit of the effective mass of the electron antineutrino. The advantages and drawbacks of this kinematic, an almost model independent, method will be reviewed. The status of the KATRIN experiment aiming at ten times higher sensitivity will be described. Several new approaches will be outlined.

Theory and Phenomenology of the 0nbb-decay

• Fedor Šimkovic (Comenius University)

Double beta decay

• Ivan Štekl (Czech Technical University in Prague)

Experimental searches for neutrino-less double beta decay (0v beta beta) are one of the most active research topics in neutrino physics. The observation of such process is in fact of major importance since it will prove the Majorana nature of neutrinos and may give access to their absolute mass scale. The Majorana nature of the neutrino would have interesting implication in many extensions of the Standard Model of particle physics. On the other hand, two neutrino double beta decay (2v beta beta) provides needed information for further development of nuclear theory (nuclear matrix elements). During the talk, the subjects of 0v beta beta and 2v beta beta decays, the most important experiments in the field and the obtained results will be introduced.

Future Neutrino oscillation experiments - Round Table Discussion