T2K experiment
T2K ("Tokai to Kamioka") is a particle physics experiment studying the oscillations of the accelerator neutrinos. The experiment is conducted in Japan by the international cooperation of about 500 physicists and engineers with over 60 research institutions from several countries from Europe, Asia and North America [1] and it is a recognized CERN experiment (RE13).[2][3]
T2K was the first experiment which observed the appearance of electron neutrinos in muon neutrino beam,[4] it also provided the world best measurement of oscillation parameter θ23 [5] and a hint of a significant matter-antimatter asymmetry in neutrino oscillations.[6][7] The measurement of the neutrino-antineutrino oscillation asymmetry may bring us closer to the explanation of the existence of our matter-dominated Universe.[8][9]
The intense beam of muon neutrinos is produced in the J-PARC facility (Japan Proton Accelerator Research Complex) in Tokai on the east coast of Japan. The beam is directed towards the Super-Kamiokande far detector located 295 km away in the city of Hida, Gifu prefecture. The properties and composition of the neutrino flux are first measured by a system of near detectors located 280 m from the beam production place at the J-PARC site, and then again in the Super-Kamiokande detector. Comparison of the content of different neutrino flavours in these two locations allows measurement of the oscillations probability on the way between near and far detectors. Super-Kamiokande is able to detect interactions of both, muon and electron neutrinos, and thus measure the disappearance of muon neutrino flux, as well as electron neutrino appearance in the beam.[10]
Physics program
T2K experiment was proposed in 2003 with the following measurement goals:[10]
- The discovery of the
ν
μ →
ν
e oscillations, and thus the confirmation that the last unknown mixing angle θ13 is not zero. - Precise measurement of the oscillation parameters Δm2
23 and θ23 via muon neutrino disappearance studies. - Search for sterile neutrino oscillations, which could be observed as a deficit of neutral current neutrino interactions.
- Measurements of various interaction cross-sections for different types of neutrinos and targets in an energy range of few GeV.
Since the start of the data taking in 2010, the T2K experiment succeeded to provide a list of world-class results:
- The confirmation of electron neutrino appearance in the muon neutrino beam (
ν
μ→
ν
e), which was the first time when neutrinos produced in one flavour was explicitly observed in another flavour.[4][11] - The most precise measurement of the θ23 parameter.[5]
- The first significant constraint on the δCP parameter, responsible for the matter-antimatter asymmetry in the neutrino sector.[7]
- Limits on a sterile neutrino oscillation parameters based on studies in the near ND280 [12] and far Super-Kamiokande [13] detectors.
- Various cross-section measurements of electron[14][15] and muon neutrino and antineutrino, including inclusive charged current (CC) interactions,[16] CC interactions without pions [17][18][19] and with single pion in the final state,[20] coherent pion production,[21] neutral current interactions,[22] etc. on different targets such as carbon, water and iron.[23]
Future upgrades of T2K is expected to provide further constrain on the δCP phase by comparing oscillations of neutrinos to those of antineutrinos, as well as more precise measurements of Δm2
23 and θ23 parameters, and cross-section measurements which will extend our understanding of neutrino interactions and thus improve theoretical models used in neutrino generators.[24][25]
Neutrino beam
T2K uses a muon neutrino or muon antineutrino beam produced at the J-PARC facility using a proton beam gradually accelerated to 30 GeV by a system of three accelerators: first to 400 MeV energy by the Linac linear accelerator, then up to 3 GeV by the RCS (Rapid Cycle Synchrotron), and finally up to 30 GeV by the MR synchrotron (Main Ring). Protons collide with a graphite target, producing mesons, mainly pions and kaons, which are then focused by a set of three magnetic horns and directed into a tunnel called the decay volume. Depending on the horns polarity, either positive or negative particles are focused. Positive pions and kaons decay mainly into
μ+
and
ν
μ, forming a muon neutrino beam, while negative pions and kaons decay mainly into
μ−
and
ν
μ, forming a muon antineutrino beam. All remaining hadrons and charged leptons are stopped by a 75-ton block of graphite (so-called beam dump) and in the ground, while neutrinos travel underground towards the far detector.[10]
Off-axis beam
T2K is the first experiment in which the concept of off-axis neutrino beam was realized. The neutrino beam at J-PARC is designed so that it can be directed 2 to 3 degrees away from the Super-Kamiokande far detector and one of the near detectors, ND280. The off-axis angle was chosen to 2.5° to maximize the probability of oscillation at a distance corresponding to the far detector, which for 295 km is maximal for around 600 MeV neutrinos. In this neutrino energy range, the dominant type of neutrino interactions are charged current quasielastic interactions, for which it is possible to reconstruct the energy of the interacting neutrino only on the basis of the momentum and direction of the produced charged lepton. The higher neutrino energies are suppressed by the off-axis configuration, decreasing the number of interactions with meson production, which are background in the oscillation analysis in the T2K experiment.[10][26]
Near detectors
The near detector complex[10] is located at a distance of 280 meters from the graphite target. Its purpose is to measure the neutrino flux before oscillations and to study neutrino interactions. The system consists of three main detectors:
- INGRID detector (Interactive Neutrino GRID) located on the axis of the neutrino beam,
- ND280 detector located 2.5° away from the beam axis, i.e. at the same angle as the far detector.
- Wagasci-BabyMIND (WAter Grid SCIntillator Detector - prototype Magnetized Iron Neutrino Detector) is a magnetised neutrino detector located at 1.5° off-axis angle, built to explore the energy spectrum variation with the off-axis angle and cross-sections at higher average neutrino energy.[27][28]
Signal readout
Except for the Time Projection Chambers in ND280, the entire active material (enabling particle tracking) of the near detectors is plastic scintillator. The light produced by traversing particles in the plastic scintillator bars and planes is collected by wavelength-shifting fibres and detected by Hamamatsu Multi-pixel photon counters located at one or both ends of the fibres. Scintillator bars are organised into layers, where bars in two neighbouring layers are perpendicular to each other providing together 3D information about traversing particles.[10]
INGRID detector
The main purpose of the INGRID detector is the monitoring of the direction and intensity of the beam on a daily basis by direct detection of neutrino interactions. The INGRID detector consists of 16 identical modules arranged in the shape of a cross, 7 in a vertical and 7 in a horizontal arm, plus 2 modules outside the cross. Height and width of the arms are 10 meters. A single module consists of alternating layers of iron and a plastic scintillator. An additional 4 veto layers of the scintillator surround the module on the sides to distinguish particles entering from the outside from those produced by interactions inside the module. The total mass of iron in one module is 7.1 tons and constitutes 96% of the module weight. On the neutrino beam axis, in the middle of the cross between the vertical and horizontal arm, there is an additional module built only from layers of the plastic scintillator (Proton Module) with a mass of 0.55 tons. Its purpose is to register quasielastic interactions and compare the obtained results with the simulations.[10]
ND280 detector
The ND280 detector is used to measure the flux, energy spectrum and electron neutrino beam pollution for the same off-axis angle as for the far detector. ND280 also investigates various types of muon and electron neutrino and antineutrino interactions. All this allows estimating the expected number and type of interactions in the far detector, reducing the systematic error in the neutrino oscillations analysis associated with models of neutrino interactions and flux.[10]
ND280 is composed of the set of inner sub-detectors: Pi-Zero detector and a tracker with 2 Fine-Grained Detectors interleaved with 3 Time Projection Chambers, placed inside of a metal frame called a basket. The basket is surrounded by the electromagnetic calorimeter and a magnet recycled from the UA1 experiment producing 0.2 T uniform horizontal field and instrumented with scintillator planes constituting the Side Muon Range Detector.[10]
Pi Zero detector
The Pi-Zero (
π0
) Detector (P0D) contains 40 plastic scintillator module planes, which in the central part are interleaved with 2.8 cm thick bags fillable of water and thick brass sheets, and in two peripheral regions scintillator modules are sandwiched with lead sheets. By comparison of the amount of interaction between modes with and without water in the bags, it is possible to extract the number of neutrino interactions occurring on the water - the target material inside the far detector Super-Kamiokande.
The size of the entire active P0D volume is around 2.1 m × 2.2 m × 2.4 m (X×Y×Z) and its mass with and without water is 15.8 and 12.9 tons respectively.
The main goal of the Pi-Zero Detector is measurement neutral pions production in neutral current neutrino interactions on water:
ν
μ + N →
ν
μ + N’ +
π0
This reaction can mimic electron neutrino interactions because photons from
π0
decay can be mis-reconstructed as an electron in the Super-Kamiokande detector, thus this reaction can mimic electron neutrino interactions and constitute an important background in electron neutrino appearance measurement.
[10][29]
Time projection chambers
Three time projection chambers (TPCs) are gas-tight rectangular boxes, with a cathode plane in the centre and readout MicroMegas modules at both sides parallel to the cathode. TPCs are filled with argon-based drift gas under atmospheric pressure. Charged particles crossing TPC ionise the gas along their track. The ionisation electrons drift from the cathode to the sides of the TPC, where they are detected by the MicroMegas providing a 3D image of a path of the traversing charged particle. Y and Z coordinates are based on the position of the detected ionisation electrons on the MicroMegas modules, and X coordinate is based on the electrons drift time. In the magnetic field, the curvature of this path allows to determine charge and momentum of the particle, and the amount of the ionisation electrons per unit distance is used to identify particles based on the Bethe-Bloch formula.[10][30]
Fine-grained detectors
Two fine-grained detectors (FGDs) are placed after the first and second TPCs. Together the FGDs and TPCs make up the tracker of ND280. The FGDs provide the active target mass for the neutrino interactions and are able to measure the short tracks of proton recoil. The first FGD is composed of scintillator layers only, while the second FGD is composed of alternating layers of scintillator and water. The second FGD is partially composed of water because the detector at Super-Kamiokande is water-based. Cross sections on carbon and on the water can be determined from a comparison of neutrino interactions in the two FGDs.[10][31]
Electromagnetic Calorimeter
The Electromagnetic Calorimeter (ECAL) surrounds the inner detectors (P0D, TPCs, FGDs) and consists of scintillator layers sandwiched with lead absorber sheets. Its role is to detect neutral particles, especially photons, and measure their energy and direction, as well as to detect charged particles providing additional information relevant for their identification.[10][32]
Side Muon Range Detector
The Side Muon Range Detector (SMRD) consists of scintillator modules which are inserted into the gaps in the magnet. The SMRD records muons escaping the inner parts of the detector at large angles with respect to the beam direction. It can also act as a trigger for cosmic rays. Finally, it can help identify beam interactions in the surrounding walls and in the magnet itself.[10][33]
WAGASCI-Baby MIND
WAGASCI-Baby MIND[27][28] is a new detector located next to the INGRID and ND280 detectors, devoted to neutrino interaction studies. It provided the first neutrino beam data using full detector setup during the 2019/2020 winter run.
The WAGASCI-Baby MIND consists of several sub-detectors:
- Two new water-scintillator detectors (WAGASCI, WAter-Grid-SCIntillator-Detector) that act as the main water targets and particle trackers. The 3D grid-like structure of scintillator bars creates hollow cavities filled with water (80% H2O + 20% CH). The acceptance is approximately constant in all directions.
- One Proton Module, the same as in the INGRID detector, made of plain plastic scintillator (CH) bars, that acts as the main CH target and particle tracker.
- Two WallMRD (Wall Muon Range Detector) that are non-magnetized muon spectrometers to detect side going muons. They are made of passive iron planes intertwined with active scintillator planes.
- One Baby MIND (prototype Magnetized Iron Neutrino Detector) that is a magnetized muon spectrometer to detect forward-going muons. Baby MIND sports an original configuration of scintillation modules intertwined with magnetized ferrite modules like a sandwich. The modules can be rearranged easily to adapt the magnetic field to the particular needs of the experiment. The magnetic field is created only inside the ferrite so it is very power efficient compared to magnets that have to magnetize empty spaces around them like the ND280 one. However, the magnetic field is not homogeneous over the travel volume of the muons, and this poses a still open challenge for momentum reconstruction.
All the active material in the detectors is made up of plastic scintillator and is read as explained in section Signal readout.
The main goal of the WAGASCI-Baby MIND detector is a reduction of the systematic error in the T2K oscillation analysis, which will be achieved thanks to its complementarity with respect to the ND280 detector:
- Different target material between ND280 (80% CH + 20% H2O) and SK (pure H2O) forces us to rely on cross-section models to disentangle the H2O cross-section estimate from the CH one. The fraction of water in WAGASCI water-scintillator modules is 80% enabling a measurement of the charged-current neutrino cross-section ratio between water (H2O) and plastic (CH) with 3% accuracy.
- The new detector will provide measurements of various charged-current neutrino interaction channels with high precision, lower momentum threshold and full angular acceptance. These will constrain flux and cross-section models uncertainties for the particles produced at high angles. These assets will also facilitate detection of low momentum hadrons produced in the interaction of the neutrino with bounded states of 2 nucleons or through reinteractions inside the target nucleus of particles produced by the neutrino, and thus better modelling of such interactions in the far detector.
- Location at the same distance of 280 meters from the graphite target as ND280 and INGRID detectors, but at a different off-axis angle of 1.5 degrees, causes that the energy spectrum of the neutrino beam is peaked around different energies for each of the off-axis angles corresponding to the detectors. Combination of measurements from these detectors will provide an improved constraint on the neutrino cross-sections as a function of their energy.
Super-Kamiokande
Super-Kamiokande detector is located 1000 m underground in the Mozumi Mine, under Mount Ikeno in the Kamioka area of Hida city. It is a stainless steel cylindrical tank of about 40 m height and diameter, filled with 50,000 tons of water and instrumented with around 13,000 photomultiplier tubes (PMT). It detects a cone of Cherenkov light emitted by charged particles moving in water faster than light in this medium.
Its goal is to measure muons and electrons produced in charged current quasielastic interactions (CCQE) of
ν
μ and
ν
e, respectively. Due to relatively large mass, muons usually do not change their direction and thus produce a well-defined cone of Cherenkov light observed by PMTs as a clear, sharp ring. In contrast, electrons, because of smaller mass, are more susceptible to scattering and almost always produce electromagnetic showers, observed by PMTs as a ring with fuzzy edges. Neutrino energy is calculated based on the direction and energy of a charged lepton produced in the CCQE interaction. In this way,
ν
μ and
ν
e spectra are determined, leading to the measurement of the oscillation parameters relevant for muon neutrino disappearance and electron neutrino appearance.[10][34]
History
T2K is a successor of the KEK to Kamioka (K2K) experiment, which ran from 1999 till 2004. In the K2K experiment, an accelerator beam of muon neutrinos was produced at KEK facility in Tsukuba (Japan) and sent towards the Super-Kamiokande detector, located 250 km away. The K2K experiment results confirmed at the confidence level of 99.9985% (4.3 σ) the disappearance of the muon neutrinos and were consistent with the previous measurements of oscillation parameters measured by the Super-Kamiokande detector for atmospheric neutrinos.[35][36]
The construction of the neutrino beamline started in 2004 and it was successfully commissioned in 2009. Construction of the entire INGRID detector and majority of the ND280 detector (without barrel part of the electromagnetic calorimeter) was completed in 2009. The missing part of the calorimeter was installed in the fall of 2010. T2K far detector is the large Super-Kamiokande detector, which has been running since 1996 and studying proton lifetime and oscillations of atmospheric, solar and accelerator neutrinos.[10]
T2K experiment started to take neutrino data for a physics analysis in January 2010, initially with an incomplete ND280 detector, and starting from November 2010 with the full setup. The data taking was interrupted for one year by the Great Tohoku Earthquake in March 2011. The proton beam power, and thus the neutrino beam intensity, was constantly growing, reaching by February 2020 the power of 515 kW and a total number of accumulated protons on target of 3.64×1021 protons [37] with 55% of data in neutrino-mode and 45% in antineutrino-mode.
In April 2020, T2K collaboration published results strongly constraining the δCP phase. The results reject at 95% confidence the hypothesis of no CP violation (including the possibility of δCP equal to π).[7][38] The results also reject at the 3σ (99.7%) significance level almost half of the possible values of this parameter and give a strong hint that CP violation may be large in the neutrino sector.[7][39]
Future plans
The T2K experiment is expected to operate in the current form until the end of 2020. In 2021 a major upgrade of the neutrino beamline and the ND280 near detector will be performed. From 2022 till 2026 neutrino data will be taken within the second phase of the T2K experiment (T2K-II).[24] In 2025, the successor of the T2K experiment will be launched, the Hyper-Kamiokande (HK) experiment, with the new, 250,000-ton water Cherenkov far detector - the Hyper-Kamiokande detector.[40][41] The building of an additional Intermediate Water Cherenkov detector at a distance of around 2 km is also considered for the HK experiment.[41]
T2K-II
The phase II of the T2K experiment is expected to start in 2022 and last until 2025 or 2026 following by the commencement of the HK experiment. The physics goals of T2K-II are a measurement of the oscillation parameters θ23 and Δm2
23 with a precision of 1.7° and 1%, respectively, as well as a confirmation at the level of 3 σ or more of the matter-antimatter asymmetry in the neutrino sector in a wide range of possible true values of δCP - the parameter responsible for the CP (matter-antimatter) asymmetry. Achievement of these goals requires reduction of the statistical and systematic errors, and thus a significant upgrade of the beamline and the ND280 detector, as well as improvements in the software and analysis methods.[24]
Beam upgrade
The beam upgrade plan requires one year long shut down of the J-PARC Main Ring accelerator in 2021, followed by a constant gradual increase of the proton beam power until the start of the HK experiment. The beam power should reach 750 kW in 2022 and then grow to 1.3 MW by 2029.[42]
In February 2020, the proton beam power reached 515 kW with 2.7x1014 protons per pulse and with 2.48 seconds between pulses (so-called repetition cycle). To reach 750 kW, the repetition cycle will be reduced to 1.32 s with 2.0x1014 protons per pulse, while for 1.3 MW the repetition cycle has to be further decreased to 1.16 s and the number of protons per pulse has to increase to 3.2x1014. In addition to increasing the primary proton beam power, the current in the horns focusing secondary particles (pions, kaons, etc.) with a chosen electric charge will also be increased from 250 kA to 320 kA. This will increase the amount of right-sign neutrinos (neutrinos in the neutrino mode beam and anti-neutrinos in the anti-neutrino mode beam) by 10%, and reduce the amount of wrong-sign neutrinos (anti-neutrinos in the neutrino-mode beam and neutrinos in the anti-neutrino mode beam) by around 5-10%.[42][43]
Reduction of the repetition cycle will require a series of hardware upgrades, including a major upgrade of the Main Ring power supplies and a minor upgrade of the focusing horn power supplies, all of which will be installed during the long shutdown in 2021. Increasing the horn current will require using an additional (third) horn power supply. Meanwhile, the higher proton beam power demands enhancement of the cooling capacity of the secondary beamline components such as the graphite target, the magnetic horns and the beam dump, as well as disposal of a larger amount of irradiated cooling water.[42][43]
ND280 Upgrade
The current design of the ND280 detector is optimized for the detection and reconstruction of forward-going leptons (muons and electrons), but it also has a number of limitations, like low reconstruction efficiency of particles produced almost perpendicular and backward w.r.t. the direction of the interacting neutrino, as well as too high momentum threshold to reconstruct a large part of produced pions and knocked-out nucleons (protons and neutrons). In Charged Current Quasi-Elastic (CCQE) interactions, the dominating interaction in the ND280 near detector, kinematics of produced lepton is enough in the reconstruction of the incoming neutrino energy. However, other types of neutrino interactions in which additional particles (pions, kaons, nucleons) were lost, may be mis-reconstructed as CCQE and introduce a bias in the reconstructed neutrino energy spectrum. Thus, it is essential to optimize the detector to be sensitive to additional particles and nuclear effects.
Three main measures need to be taken to address these issues:
- The detector needs to efficiently detect the nucleons in the final state of neutrino interactions. For this, the detection thresholds need to be lowered.
- High-angle and backwards-going tracks must be well-reconstructed. This is achieved by increasing the angular acceptance and the efficiency of the discrimination between backward from forward going tracks using timing information.
- Finally, the total fiducial volume (the mass available for neutrino interactions) of the tracker part of the ND280 detector, characterised with a better reconstruction ability, needs to be enlarged in order to increase the rate of neutrino interactions.
The Upgrade of the ND280 detector (ND280 Upgrade) addresses these requirements by replacing a part of the P0D sub-detector with three types of new sub-detectors. The existing downstream part, consisting of two Fine-Grained scintillation Detectors (FGDs) and three Time Projection Chambers (TPCs), will maintain their sandwiched structure and continue to detect forward going leptons and high momentum hardons. The upstream part which now hosts the P0D sub-detector will be replaced by three novel sub-detectors: a scintillating 3D target (Super Fine-Grained Detector or SuperFGD), two new TPCs on top and below the SuperFGD (High-Angle TPCs or HATPCs), and six Time-of-Flight (TOF) detectors surrounding the new structure. Each of these sub-detectors is briefly described below.[44]
SuperFGD
The SuperFGD is a 2m x 2m x 0.5m detector consisting of approximately 2 million 1 cm3 scintillating polystyrene cubes. The cubes are woven with a series of optical fibres designed to detect the light emitted by the particles produced during the interactions in the target. Unlike the current FGDs, the SuperFGD has a three-fold projective 2D readouts providing a quasi-3D readout. This readout configuration increases the detection of short tracks almost uniformly in all directions. Due to its geometry and coupled with the TOF and the HATPCs, the SuperFGD has the capability to detect fast-neutrons, which could be useful in the reconstruction of the antineutrino energy.[44]
HATPC
The High Angle Time Projection Chambers (HATPCs) will surround the SuperFGD in the plane perpendicular to the incoming neutrino beam. Their design is similar to that of the existing TPCs, as they both use the MicroMegas modules technology for track reconstruction. The main novel feature of the HATPCs, aside from their high angle coverage, is the use of the resistive MicroMegas technology. The latter consists of applying a layer of resistive material to increase the charge-sharing capabilities of the MicroMegas modules. This reduces the number of readout channels and allows for a spatial resolution which is as good as the one in the current TPCs.[44]
TOF
The six Time-of-Flight (TOF) detectors surrounding the HATPCs and SuperFGD are a series of plastic scintillator layers designed to identify the particle direction sense through the measurement of the time of flight for each crossing track with a timing resolution of the order of 600 ps. The capability to determine track direction sense has been proven in the actual ND280 to be critical to reduce background generated outside the active inner detectors.[44]
Impact on Neutrino Oscillation Physics
The impact the ND280 Upgrade will have on the analyses at T2K is two-fold. Firstly, an increase in statistics thanks to the 2 ton SuperFGD target will allow to nearly double the amount of data in certain samples. Secondly and more relevant, the new configuration will allow for better detection of additional final state particles: high angle particles thanks to the increased angular acceptance, and less-energetic particles because of lower detection thresholds. This detector acceptance improvement is important to cover almost the same phase space available at the far detector (SK). In addition, final state particles will allow probing nuclear effects which are essential for constraining the systematic effects of the oscillation analysis. It is an important step as well in the transition to using semi-inclusive or exclusive models in neutrino oscillation physics, as opposed to current inclusive models which use only the final state lepton in their predictions.[44]
Hyper-Kamiokande experiment
The successor of the T2K experiment, the Hyper-Kamiokande (HK) experiment, will use the upgraded system of the currently used accelerator and neutrino beamline and upgraded set of the near detector. Apart from that, a new far detector, the Hyper-Kamiokande detector, and possibly also a new intermediate detector will be built. Part of the beam related upgrade works and the upgrade of the ND280 detector will be performed yet before the start of phase II of the T2K experiment. The HK experiment is expected to start operation around the year 2027.[41][45][46]
Hyper-Kamiokande detector
The Hyper-Kamiokande detector will be a water Cherenkov detector, 5 times larger (258 kton of water) than the Super-Kamiokande detector. It will be a cylinder of 74 meters diameter and 60 meter height with 40000 photomultiplier tubes of 50 cm diameter and 6700 photomultiplier tubes of 20 cm diameter. It will be located 8 km south from the Super-Kamiokande detector in the Tochibora mine, 650 meters under the peak of Nijuugo mountain, at the same off-axis angle (2.5°) to the neutrino beam centre and in the same distance (295 km) from the beam production place at J-PARC. The start of the HK detector construction is planned for 2020 and the start of data collection is expected in 2027.[41][45]
Intermediate Water Cherenkov
The Intermediate Water Cherenkov Detector (IWCD) will be located at a distance of 0.7–2 km from the neutrino production place. It would be a cylinder filled with water of 10 m diameter and 50 m height with a 10 m tall structure instrumented with around 3000 photomultiplier tubes of a 20 cm diameter. The structure will be moved in a vertical direction by a crane system, providing measurements of neutrino interactions at different off-axis angles, spanning from 1° to 4°, and thus for different energy spectra. Combining the results from different off-axis angles it is possible to extract the results for nearly monochromatic neutrino spectrum without relying on theoretical models of neutrino interactions to reconstruct neutrino energy. Usage of the same type of detector as the far detector with almost the same angular and momentum acceptance allows comparing results from these two detectors without relying on detectors response simulations. These two facts, independence from the neutrino interaction and detector response models, will enable to minimise systematic error in the oscillation analysis. Additional advantages of such a design of the detector is a possibility to search for sterile oscillation pattern for different off-axis angles and to obtain a cleaner sample of electron neutrino interaction, whose fraction is larger for the larger off-axis angle.[41]: 47–50 [47][48]
It is planned that the IWCD will be finalised in 2024 and will start to take data from 2025, yet before launching the HK experiment.[49]
See also
Notes
- ^ "T2K experiment official page - T2K collaboration".
- ^ "Recognized Experiments at CERN". The CERN Scientific Committees. CERN. Retrieved 20 January 2020.
- ^ "RE13/T2K : The long-baseline neutrino experiment". The CERN Experimental Programme. CERN. Retrieved 20 January 2020.
- ^ a b T2K Collaboration (2011). "Indication of Electron Neutrino Appearance from an Accelerator-produced Off-axis Muon Neutrino Beam". Physical Review Letters. 107 (4): 041801. arXiv:1106.2822. Bibcode:2011PhRvL.107d1801A. doi:10.1103/PhysRevLett.107.041801. PMID 21866992.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ a b T2K Collaboration (2014). "Precise Measurement of the Neutrino Mixing Parameter \theta_{23} from Muon Neutrino Disappearance in an Off-Axis Beam". Phys. Rev. Lett. 112 (18): 181801. arXiv:1403.1532. doi:10.1103/PhysRevLett.112.181801. PMID 24856687.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ T2K Collaboration (2015). "Measurements of neutrino oscillation in appearance and disappearance channels by the T2K experiment with 6.6×10$^{20}$ protons on target". Phys. Rev. D91: 072010. arXiv:1502.01550. doi:10.1103/PhysRevD.91.072010.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ a b c d "Constraint on the matter–antimatter symmetry-violating phase in neutrino oscillations". Nature. 580: 339–344. 15 April 2020. arXiv:1910.03887. doi:10.1038/s41586-020-2177-0.
- ^ Fukugita, M.; Yanagida, T. (June 1986). "Barygenesis without grand unification". Physics Letters B. 174 (1): 45–47. Bibcode:1986PhLB..174...45F. doi:10.1016/0370-2693(86)91126-3.
- ^ Mohapatra, R N; et al. (1 November 2007). "Theory of neutrinos: a white paper". Reports on Progress in Physics. 70 (11): 1757–1867. arXiv:hep-ph/0510213. Bibcode:2007RPPh...70.1757M. doi:10.1088/0034-4885/70/11/R02.
- ^ a b c d e f g h i j k l m n o p T2K Collaboration (2011). "The T2K Experiment". Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment. 659 (1): 106–135. arXiv:1106.1238. Bibcode:2011NIMPA.659..106A. doi:10.1016/j.nima.2011.06.067.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ T2K Collaboration (5 August 2013). "Evidence of electron neutrino appearance in a muon neutrino beam". Physical Review D. 88 (3): 032002. arXiv:1304.0841. Bibcode:2013PhRvD..88c2002A. doi:10.1103/PhysRevD.88.032002.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ T2K Collaboration (16 March 2015). "Search for short baseline nue disappearance with the T2K near detector". Physical Review D. 91 (5): 051102. arXiv:1410.8811. Bibcode:2015PhRvD..91e1102A. doi:10.1103/PhysRevD.91.051102.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ T2K Collaboration (30 April 2019). "Search for light sterile neutrinos with the T2K far detector Super-Kamiokande at a baseline of 295 km". Physical Review D. 99 (7): 071103. arXiv:1902.06529. Bibcode:2019PhRvD..99g1103A. doi:10.1103/PhysRevD.99.071103.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ T2K Collaboration (27 February 2020). "Measurement of the charged-current electron (anti-)neutrino inclusive cross-sections at the T2K off-axis near detector ND280". arXiv:2002.11986 [hep-ex].
{{cite arXiv}}
: CS1 maint: numeric names: authors list (link) - ^ T2K Collaboration (19 June 2015). "Measurement of the electron neutrino charged-current interaction rate on water with the T2K ND280 pi0 detector". Physical Review D. 91 (11): 112010. Bibcode:2015PhRvD..91k2010A. doi:10.1103/PhysRevD.91.112010.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ T2K Collaboration (7 May 2013). "Measurement of the inclusive numu charged current cross section on carbon in the near detector of the T2K experiment". Physical Review D. 87 (9). arXiv:1302.4908. doi:10.1103/PhysRevD.87.092003.
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