To contents
Large JINR Research Infrastructure
02-1-1065-2007/2026en
02-1-1065-2007/2026ru
02-2-1148-2010/2028en
02-2-1148-2010/2028ru
06-6-1118-2014/2030en
06-6-1118-2014/2030ru
03-5-1129-2017/2028en
03-5-1129-2017/2028ru
04-4-1149-2024/2028en
04-4-1149-2024/2028ru
Theoretical Physics
01-3-1135-2019en
01-3-1135-2019ru
01-3-1136-2019en
01-3-1136-2019ru
01-3-1137-2019en
01-3-1137-2019ru
01-3-1138-2019en
01-3-1138-2019ru
Elementary Particle Physics
and High-Energy
Heavy-Ion Physics
Participation in internat.experiments
02-1-1066-2007en
02-1-1066-2007ru
02-2-1081-2009en
02-2-1081-2009ru
02-1-1083-2009en
02-1-1083-2009ru
02-2-1085-2009en
02-2-1085-2009ru
02-1-1087-2009en
02-1-1087-2009ru
02-1-1088-2009en
02-1-1088-2009ru
02-1-1096-2010en
02-1-1096-2010ru
Experiments at the NICA accelerator complex
02-1-1086-2009en
02-1-1086-2009ru
02-1-1097-2010en
02-1-1097-2010ru
Neutrino physics and astrophysics
02-2-1099-2010en
02-2-1099-2010ru
02-2-1144-2021en
02-2-1144-2021ru
Nuclear Physics
03-4-1146-2024en
03-4-1146-2024ru
03-5-1130-2017en
03-5-1130-2017ru
03-2-1100-2010en
03-2-1100-2010ru
Condensed Matter Physics
04-4-1147-2024en
04-4-1147-2024ru
Radiation Research in Life Sciences
05-7-1077-2009en
05-7-1077-2009ru
05-2-1132-2017en
05-2-1132-2017ru
Information Technology
06-6-1119-2014en
06-6-1119-2014ru
Applied Innovation Activities
07-1-1107-2011en
07-1-1107-2011ru
07-5-1131-2017en
07-5-1131-2017ru
Physics and Technology of Charged Particle Accelerators
08-2-1126-2015en
08-2-1126-2015ru
08-2-1127-2016en
08-2-1127-2016ru
Organization of Scientific Activities and International Cooperation. Strengthening Human Resources. Educational Programme
09-8-1037-2001en
09-8-1037-2001ru
09-9-1139-2019en
09-9-1139-2019ru
09-3-1117-2014 en
09-3-1117-2014 ru

02-2-1144-2021


Search for New Physics in the Lepton Sector

  

Theme leader:

Z. Tsamalaidze


Participating countries and international organizations:

Belarus, Bulgaria, Czech Republic, France, Georgia, Germany, Italy, Japan, Kazakhstan, Russia, Switzerland, United Kingdom, USA.


The problem under study and the main purpose of the research: 

Search for evidence of new physics beyond the Standard Model by measuring the neutrinoless, coherent transition of a muon to an electron (μ → e conversion) in the field of an aluminum nucleus.

 

Project in the theme:


 

Name of the project

Project Leader

Project code

1.

COMET

Z. Tsamalaidze

02-2-1144-1-2021/2024


Project:

 

Name of the project

Project Leader

Status

 

Laboratory (Subdivision)

Responsible from laboratories

1.

COMET

Z. Tsamalaidze

R&D
Realization


 

DLNP

G. Adamov, A.M. Artikov, A.V. Boikov, D.Sh. Chokheli, V.N. Duginov, P.G. Evtukhovich, I.L. Evtukhovich, V.A. Kalinnikov, E.S. Kaneva,
Kh. Khubashvili, A.V. Pavlov, B.M. Sabirov, A.G. Samartsev, 
A.V. Simonenko, V.V. Tereschenko, S.V. Tereschenko, N. Tsverava,
I.I. Vasilyev, E.P. Velicheva, A.D. Volkov, I.Yu. Zimin

 

BLTP

D. Aznabaev, A. Issadykov, G.A. Kozlov

 

MLIT

D. Goderidze, A. Khvedelidze

 

VBLHEP

D. Baigarashev, T.L. Enik

 

Brief annotation and scientific rationale:

Charged-lepton flavour-violating (CLFV) processes offer deep probes for new physics with discovery sensitivity to a wide range of new physics models – SUSY, Higgs Doublets, Extra Dimensions, and, particularly, models explaining the neutrino mass hierarchy and the matter- antimatter asymmetry in the Universe via leptogenesis. The most sensitive exploration of CLFV process is provided by experiments that utilize high intensity muon beams to search for CLFV  μ → e transitions:  μ+→e+γ (experiment MEG at PSI);  μ+→e+e-e+(experiment Mu3e at PSI), and coherent neutrinoless conversion of a muon into an electron in the field of a nucleus μN → eN, COMET (COherent Muon to Electron Transition) experiment at J-PARC.

COMET experiment will be implemented in two phases, Phase-I and Phase-II. The experimental sensitivity goal for this process in the Phase-I experiment is 3.1 × 10-15, or the 90% upper limit of the branching ratio of 7 × 10-15, which is a factor of 100 improvement over the existing limit. The expected number of background events is 0.032. To achieve the target sensitivity and background level, the 3.2 kW 8 GeV proton beam from J-PARC will be used. Two types of detectors, CyDet and StrECAL, will be used for detecting the µ-e conversion events and for measuring the beam-related background events in view of the Phase-II experiment, respectively.

The goal of the full experiment is a SES of 2.6×10-17, which we refer to as Phase-II. This ultimate sensitivity goal is a factor of about 10,000 better than the current experimental limit B(μ + Au → e + Au) ≤ 7×10-13 from SINDRUM-II at PSI.

Scientists from JINR are successfully participating in the preparation stage of the COMET experiment. For the COMET Phase-I experiment, JINR scientists produced and tested in accordance with the requirements the whole set about 2700 of 9.8-mm straw tubes. For Phase – II JINR scientists will make a full set of 5-mm straw tubes and will also take an active part in the development of the entire straw tracker, electromagnetic calorimeter and Cosmic Ray Veto (CRV) system as well as in assembly and maintanance of detectors and in further data analysis.

Expected results upon completion of the project:

1. Production of all thin-wall straw tubes. Different procedures of the tube tests for pressure, gas leakage and elongation, in accordance with the COMET requirements.

2. R&D for straw tubes with the diameter fo 5 mm and wall thickness of 12μm for the COMET Phase-II. For this purpose, we prepared a new straw line at DLNP.

3. Assembling, testing and installation of the 2nd and 3rd straw tracker stations for Phase-I.

4. Production of a full-scale straw station with a new type of straw tubes for Phase-I.

5. Development and optimization of a crystal calibration method for the calorimeter to be used in COMET Phase‑I and Phase-II.

6. Assembling, testing, installation and operation of the calorimeter.

7. Implementation of a full-scale R&D program to create a cosmic veto system (CRV), providing determination of principles and parameters for the construction of complete CRV system. Manufacturing, assembling, testing of the CRV for Phase-α.

Expected results of the project in the current year:

1. Participation in the preparation, engineering and physics run of Phase-α.

2. R&D program for production of the straw tubes with the wall thickness of 12 μm and diameter of 5 mmwall. Measurement of all mechanical properties and development of standards for quality control of manufactured brand-new 5 mm diameter straw tubes.

3. Completion of assembly, testing, calibration, installation, cosmic test and maintenance of 2-3 straw detector stations for
Phase-I.

4. Production of straw tubes (about 1000) for the full-scale prototype.

5. Production of a full-scale straw station at JINR with new tubes (12 μm, 5 mm).

6. Preparation for mass production and testing of straw tubes for Phase-II.

7. Development and optimization of a crystal calibration method for a COMET calorimeter, with allpwance the features of the experiment: the presence of a magnetic field and high-resolution calorimeter.

8. Participation in the full calorimeter assembling, installation, cosmic test and maintenance.

9. Participation in the assembling and testing of the CRV for Phase-I.

10. Participation in the beam tests of the detector components for Phase-I.

11. Integrated detector system (tracker, calorimeter, etc.) simulation.

12. Participation in the engineering and physics run in Phase-α.

 

Activities:


 

 Name of the activity

Leaders

Status

 

Laboratory (Subdivision)

Responsible from laboratories

1.

T2К-II

Yu.I. Davydov

R&D
Realization


 

DLNP
 

A.M. Artikov, V.Yu. Baranov, A.V. Boikov, D.L. Demin,
V.V. Glagolev, N.V. Khomutov, N.V. Kirichkov, V.I. Kiseeva,
A.O. Kolesnikov, A.V. Krasnoperov, V.L. Malyshev, B.A. Popov, A.V. Shaikovskiy, I.A. Suslov, V.V. Tereschenko, S.V. Tereschenko, I.I. Vasilyev

 

BLTP
 

G.A.Kozlov

2.

Mu2e

Yu.I. Davydov

R&D
Realization


 

DLNP
 

A.M. Artikov, N.V. Atanov, O.S. Atanova, V.Yu. Baranov,
A.V. Boikov, V.V. Glagolev, V.I. Kiseeva, V.L. Malyshev,
A.O.
Kolesnikov, A.V. Sazonova, A.N. Shalyugin, I.A. Suslov,
V.V. Tereschenko, S.V. Tereschenko, I.I. Vasilyev, I.Yu. Zimin

 

BLTP
 

D.I. Kazakov, G.A.Kozlov

3.

MEG-II

N.V. Khomutov

Realization
Data taking
Data processing


 

DLNP
 

K. Afanasiev, Yu.I. Davydov, A.O. Kolesnikov, N.P. Kravchuk,
V.A. Krylov, N.A. Kuchinsky, V.L. Malyshev,
A.M. Rozhdestvensky 

4.

CERN Neutrino platform

B.A. Popov

Data taking
Data processing


 

DLNP
 

N.V. Atanov, A.O. Kolesnikov, A.V. Krasnoperov, V.V. Lyubushkin, V.L. Malyshev, V.V. Tereschenko, S.V. Tereschenko

Collaboration

Country or International Organization

City

Institute or laboratory

Belarus

Minsk

BSU



INP BSU

 

 

IP NASB



SPMRC NASB

Bulgaria

Sofia

SU

Czech Republic

Prague

CU

France

Paris

IN2P3

 

 

LPTHE

Georgia

Tbilisi

GTU

 

 

HEPI-TSU

 

 

UG

Germany

Dresden

TU Dresden

Italy

Frascati

INFN LNF

 

Pisa

INFN

 

 

UniPi

Japan

Fukuoka

Kyushu Univ.

 

Osaka

Osaka Univ.

 

Tokai

JAEA


Tokyo

UT

 

Tsukuba

KEK

Kazakhstan

Almaty

INP

Russia

Moscow

LPI RAS

 

 

PIN RAS

 

Moscow, Troitsk

INR RAS

 

Novosibirsk

BINP SB RAS

 

 

NSU

Switzerland

Villigen

PSI


Zurich

ETH

United Kingdom

London

Imperial College

USA

Batavia, IL

Fermilab


Charlottesville, VA

UVa

 

Lemont, IL

ANL

 

Pasadena, CA

Caltech