RUPAC2018 - List of Authors (Lalayan, M.V.)

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MOXMH04

Current Results of the 4th Generation Light Source USSR (Former SSRS4) Development

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S.M. Polozov, I.A. Ashanin, S.V. Barabin, Y.A. Bashmakov, A.E. Blagov, D.K. Danilova, A.A. Dementev, V.V. Dmitriyeva, N.S. Dudina, V.S. Dyubkov, A.M. Feshchenko, Ye. Fomin, A. Gogin, M. Gusarova, Yu.D. Kliuchevskaia, V. Korchuganov, T. Kulevoy, M.V. Lalayan, D.A. Liakin, Y. Lozeev, T.A. Lozeeva, A.A. Makhoro, N.V. Marchenkov, S.V. Matsievskiy, V.Yu. Mekhanikova, O.A. Mosolova, A.Y. Orlov, A.V. Popova, A.I. Pronikov, V.I. Rashchikov, A.A. Savchenko, R.A. Senin, V.L. Shatokhin, A.S. Smygacheva, A.A. Tishchenko, V. Ushakov, A.G. Valentinov
NRC, Moscow, Russia
I.A. Ashanin, Y.A. Bashmakov, D.K. Danilova, A.A. Dementev, V.V. Dmitriyeva, V.S. Dyubkov, A.M. Feshchenko, M. Gusarova, Yu.D. Kliuchevskaia, T. Kulevoy, M.V. Lalayan, Y. Lozeev, T.A. Lozeeva, A.A. Makhoro, S.V. Matsievskiy, V.Yu. Mekhanikova, O.A. Mosolova, A.S. Panishev, S.M. Polozov, A.V. Popova, A.I. Pronikov, V.I. Rashchikov, A.V. Samoshin, A.A. Savchenko, V.L. Shatokhin, A.A. Tishchenko
MEPhI, Moscow, Russia
S.V. Barabin, A. Bolshakov, T. Kulevoy, D.A. Liakin, A.Y. Orlov
ITEP, Moscow, Russia
Y.A. Bashmakov
LPI, Moscow, Russia
J.C. Biasci, J.M. Chaize, G. Le Bec, S.M. Liuzzo, C. Maccarrone, H.P. Marques, P. Raimondi, J.-L. Revol, K.B. Scheidt, S.M. White
ESRF, Grenoble, France

Funding: Project is supported by Ministry of Science and Education of Russian Federation, Agreements 14.616.21.0086 from 24.11.2017, ID RFMEFI61617X0086, 14.616.21.0088 from 24.11.2017, ID RFMEFI61617X0088
The new project of 4th generation synchrotron light source called Ultimate Source of Synchrotron Radiation (USSR) today is under development at NRC Kurchatov Institute. A number of Russian institutions also take part in this project: NRNU MEPhI, NRC "Kurchatov Institute" - ITEP and others. The European Synchrotron Radiation Facility (ESRF, Grenoble, France) is the main international collaborator of the project. It is proposed that USSR include both a storage ring and soft FEL, and one linac will be used for injection in the storage ring and as a driver for the FEL. The preliminary design of 6 GeV storage ring with transverse emittance of 50-70 pm*rad is done. The general concept of the top-up linac is proposed and the beam dynamics is simulated. The injection system and the vacuum systems are studied. Current results of the USSR R&D will be presented in this report.

Slides MOXMH04 [5.520 MB]

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WECBMH01

Superconducting Linacs Development for Current and Future Russian Accelerator Projects: Progress and Problems

S.M. Polozov, W.A. Barth, M. Gusarova, T. Kulevoy, M.V. Lalayan, A.V. Samoshin, S. Yaramyshev, V. Zvyagintsev
MEPhI, Moscow, Russia
W.A. Barth, S. Yaramyshev
GSI, Darmstadt, Germany
W.A. Barth
HIM, Mainz, Germany
A.V. Butenko, A.S. Fomichev, L.V. Grigorenko, B.Y. Sharkov, E. Syresin, G.V. Trubnikov
JINR, Dubna, Moscow Region, Russia
T. Kulevoy
ITEP, Moscow, Russia
V. Zvyagintsev
TRIUMF, Vancouver, Canada

Superconducting linac is nowadays a standard technology to generate high-energy proton and ion beams especially for CW operation mode. Starting from SNS at ORNL * superconducting radio frequency (SRF) technology and superconducting (SC) linacs are changed from the exotic to classical technology of today. Many ion accelerator complexes developed in USA, EU, Japan, China, Korea and other countries for spallation neutron sources, production of radioactive ion beams and ADS (Accelerator Driven System) drivers use SC cavities. Currently, the mega-science accelerator project NICA ** (Nuclotron-based Ion Collider fAcility, JINr) as well as new proposed projects DERICA *** (Dubna Electron-Radioactive Ion Collider fAcility), NEPTUN, BELA ****(Based on ECR and Linear Accelerator multidisciplinary facility), etc. cannot be constructed without SRF technologies development in Russia. New ambitious program of SRF technology has been started few years ago by JINR in collaboration with MEPhI, NRC KI ITEP, BSU, PTI NANB, TRIUMF and GSI. Current progress in general conceptual design of new SC linacs, beam dynamics simulation of SC cavities and related issues will be discussed in this presentation.
* N. Holtkamp. Proc. of EPAC'2006, 29-33.
** G. Trubnikov, N. Agapov, V. Alexandrov et al., Proc. of IPAC'10, 693 (2010).
*** http://aculina.jinr.ru/derica.php

Slides WECBMH01 [10.811 MB]

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WEPSB05

Beam Dynamics Simulation Results in the 6 GeV Top-Up Injection Linac of the 4th Generation Light Source USSR

285

S.M. Polozov, I.A. Ashanin, Yu.D. Kliuchevskaia, M.V. Lalayan, A.I. Pronikov, V.I. Rashchikov
MEPhI, Moscow, Russia
I.A. Ashanin, Yu.D. Kliuchevskaia, M.V. Lalayan, S.M. Polozov, A.I. Pronikov, V.I. Rashchikov
NRC, Moscow, Russia

Funding: Project is supported by the Ministry of Science and Education of Russian Federation, Agreement No 14.616.21.0086 from 24.11.2017, ID RFMEFI61617X0086
The new project of 4th generation synchrotron light source USSR (Ultimate Source of Synchrotron Radiation) is under development today. It was proposed that USSR will include both storage ring and soft FEL and one linac will used for injection in synchrotron and as a driver for FEL. The general concept of the top-up linac is proposed and the beam dynamics was simulated. It is suggested to use two RF-guns in this linac similar to Super-KEKB, MAX-IV and CERN FCC. One of the RF-guns should be classical with thermionic cathode and will be used for injection. The second one having photogun will use to generate a bunch train (for FEL. Current results of the top-up linac general scheme development and first results of the beam dynamics simulation will present.

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEPSB05

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WEPSB46

QWR and HWR SC Cavities R&D for New Superconducting Linac for JINR Nuclotron-NICA Injection

M. Gusarova, T. Kulevoy, M.V. Lalayan, T.A. Lozeeva, S.V. Matsievskiy, R.E. Nemchenko, S.M. Polozov, A.V. Samoshin, V.L. Shatokhin, N.P. Sobenin, D.V. Surkov, K.V. Taletskiy, V. Zvyagintsev
MEPhI, Moscow, Russia
A.A. Bakinowskaya, V.S. Petrakovsky, I.L. Pobol, A.I. Pokrovsky, D.A. Shparla, A. Shvedau, S.V. Yurevich, V.G. Zaleski
Physical-Technical Institute of the National Academy of Sciences of Belarus, Minsk, Belarus
M.A. Baturitski, S.A. Maksimenko
INP BSU, Minsk, Belarus
A.V. Butenko, N. Emelianov, M. Gusarova, A.O. Sidorin, E. Syresin, G.V. Trubnikov
JINR, Dubna, Moscow Region, Russia
S.E. Demyanov
Scientific-Practical Materials Research Centre of the National Academy of Sciences of Belarus, Minsk, Belarus
V.A. Karpovich
BSU, Minsk, Belarus
T. Kulevoy
ITEP, Moscow, Russia
V.N. Rodionova
Belarussian State University, Scientific Research Institute of Nuclear Problems, Minsk, Belarus
A.O. Sidorin
Saint Petersburg State University, Saint Petersburg, Russia
V. Zvyagintsev
TRIUMF, Vancouver, Canada

A superconducting or partially superconducting linac is discussed as new injector for Nuclotron-NICA complex. New linac will accelerate protons up to 25 MeV (and up to 50 MeV at the second stage of the project) and light ions to ~7.5 MeV/u. The progress in R&D of QWR and HWR superconducting cavities is discussed in this report. The design of QWR and its normal conducting copper model is finished and PTI NANB is ready to manufacture of the prototype. Two designs of HWR were discussed: one with a cylindrical central conductor and another with the conical one. The electrodynamics design of HWR had been finished before now but it should be corrected taking into account some manufacture problems. Current results of the development of the RF coupler and the test cryostat will also present .

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WEPSB48

Input Power Coupler for NICA Injector Coaxial Half Wave SC Cavity

375

S.V. Matsievskiy, M. Gusarova, M.V. Lalayan
MEPhI, Moscow, Russia

Nuclotron-based Ion Collider fAcility (NICA) is being built in Dubna, Russian Federation. Usage of the accelerator superconducting HWR cavities for the injector part of the accelerator is considered. According to technical requirements power coupler is able to withstand 13 kW of RF average transmitting power. Additionally, coupling tuning in small range should be possible. In this paper results of the 325 MHz HWR power coupler R&D are presented and discussed.

Poster WEPSB48 [1.507 MB]

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reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEPSB48

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Paper	Title	Page
MOXMH04	Current Results of the 4th Generation Light Source USSR (Former SSRS4) Development
THPSC02	use link to see paper's listing under its alternate paper code
	S.M. Polozov, I.A. Ashanin, S.V. Barabin, Y.A. Bashmakov, A.E. Blagov, D.K. Danilova, A.A. Dementev, V.V. Dmitriyeva, N.S. Dudina, V.S. Dyubkov, A.M. Feshchenko, Ye. Fomin, A. Gogin, M. Gusarova, Yu.D. Kliuchevskaia, V. Korchuganov, T. Kulevoy, M.V. Lalayan, D.A. Liakin, Y. Lozeev, T.A. Lozeeva, A.A. Makhoro, N.V. Marchenkov, S.V. Matsievskiy, V.Yu. Mekhanikova, O.A. Mosolova, A.Y. Orlov, A.V. Popova, A.I. Pronikov, V.I. Rashchikov, A.A. Savchenko, R.A. Senin, V.L. Shatokhin, A.S. Smygacheva, A.A. Tishchenko, V. Ushakov, A.G. Valentinov NRC, Moscow, Russia I.A. Ashanin, Y.A. Bashmakov, D.K. Danilova, A.A. Dementev, V.V. Dmitriyeva, V.S. Dyubkov, A.M. Feshchenko, M. Gusarova, Yu.D. Kliuchevskaia, T. Kulevoy, M.V. Lalayan, Y. Lozeev, T.A. Lozeeva, A.A. Makhoro, S.V. Matsievskiy, V.Yu. Mekhanikova, O.A. Mosolova, A.S. Panishev, S.M. Polozov, A.V. Popova, A.I. Pronikov, V.I. Rashchikov, A.V. Samoshin, A.A. Savchenko, V.L. Shatokhin, A.A. Tishchenko MEPhI, Moscow, Russia S.V. Barabin, A. Bolshakov, T. Kulevoy, D.A. Liakin, A.Y. Orlov ITEP, Moscow, Russia Y.A. Bashmakov LPI, Moscow, Russia J.C. Biasci, J.M. Chaize, G. Le Bec, S.M. Liuzzo, C. Maccarrone, H.P. Marques, P. Raimondi, J.-L. Revol, K.B. Scheidt, S.M. White ESRF, Grenoble, France
	Funding: Project is supported by Ministry of Science and Education of Russian Federation, Agreements 14.616.21.0086 from 24.11.2017, ID RFMEFI61617X0086, 14.616.21.0088 from 24.11.2017, ID RFMEFI61617X0088 The new project of 4th generation synchrotron light source called Ultimate Source of Synchrotron Radiation (USSR) today is under development at NRC Kurchatov Institute. A number of Russian institutions also take part in this project: NRNU MEPhI, NRC "Kurchatov Institute" - ITEP and others. The European Synchrotron Radiation Facility (ESRF, Grenoble, France) is the main international collaborator of the project. It is proposed that USSR include both a storage ring and soft FEL, and one linac will be used for injection in the storage ring and as a driver for the FEL. The preliminary design of 6 GeV storage ring with transverse emittance of 50-70 pm*rad is done. The general concept of the top-up linac is proposed and the beam dynamics is simulated. The injection system and the vacuum systems are studied. Current results of the USSR R&D will be presented in this report.
	Slides MOXMH04 [5.520 MB]
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WECBMH01	Superconducting Linacs Development for Current and Future Russian Accelerator Projects: Progress and Problems
	S.M. Polozov, W.A. Barth, M. Gusarova, T. Kulevoy, M.V. Lalayan, A.V. Samoshin, S. Yaramyshev, V. Zvyagintsev MEPhI, Moscow, Russia W.A. Barth, S. Yaramyshev GSI, Darmstadt, Germany W.A. Barth HIM, Mainz, Germany A.V. Butenko, A.S. Fomichev, L.V. Grigorenko, B.Y. Sharkov, E. Syresin, G.V. Trubnikov JINR, Dubna, Moscow Region, Russia T. Kulevoy ITEP, Moscow, Russia V. Zvyagintsev TRIUMF, Vancouver, Canada
	Superconducting linac is nowadays a standard technology to generate high-energy proton and ion beams especially for CW operation mode. Starting from SNS at ORNL * superconducting radio frequency (SRF) technology and superconducting (SC) linacs are changed from the exotic to classical technology of today. Many ion accelerator complexes developed in USA, EU, Japan, China, Korea and other countries for spallation neutron sources, production of radioactive ion beams and ADS (Accelerator Driven System) drivers use SC cavities. Currently, the mega-science accelerator project NICA (Nuclotron-based Ion Collider fAcility, JINr) as well as new proposed projects DERICA * (Dubna Electron-Radioactive Ion Collider fAcility), NEPTUN, BELA ***(Based on ECR and Linear Accelerator multidisciplinary facility), etc. cannot be constructed without SRF technologies development in Russia. New ambitious program of SRF technology has been started few years ago by JINR in collaboration with MEPhI, NRC KI ITEP, BSU, PTI NANB, TRIUMF and GSI. Current progress in general conceptual design of new SC linacs, beam dynamics simulation of SC cavities and related issues will be discussed in this presentation. N. Holtkamp. Proc. of EPAC'2006, 29-33. G. Trubnikov, N. Agapov, V. Alexandrov et al., Proc. of IPAC'10, 693 (2010). * http://aculina.jinr.ru/derica.php
	Slides WECBMH01 [10.811 MB]
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WEPSB05	Beam Dynamics Simulation Results in the 6 GeV Top-Up Injection Linac of the 4th Generation Light Source USSR	285
	S.M. Polozov, I.A. Ashanin, Yu.D. Kliuchevskaia, M.V. Lalayan, A.I. Pronikov, V.I. Rashchikov MEPhI, Moscow, Russia I.A. Ashanin, Yu.D. Kliuchevskaia, M.V. Lalayan, S.M. Polozov, A.I. Pronikov, V.I. Rashchikov NRC, Moscow, Russia
	Funding: Project is supported by the Ministry of Science and Education of Russian Federation, Agreement No 14.616.21.0086 from 24.11.2017, ID RFMEFI61617X0086 The new project of 4th generation synchrotron light source USSR (Ultimate Source of Synchrotron Radiation) is under development today. It was proposed that USSR will include both storage ring and soft FEL and one linac will used for injection in synchrotron and as a driver for FEL. The general concept of the top-up linac is proposed and the beam dynamics was simulated. It is suggested to use two RF-guns in this linac similar to Super-KEKB, MAX-IV and CERN FCC. One of the RF-guns should be classical with thermionic cathode and will be used for injection. The second one having photogun will use to generate a bunch train (for FEL. Current results of the top-up linac general scheme development and first results of the beam dynamics simulation will present.
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEPSB05
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WEPSB46	QWR and HWR SC Cavities R&D for New Superconducting Linac for JINR Nuclotron-NICA Injection
	M. Gusarova, T. Kulevoy, M.V. Lalayan, T.A. Lozeeva, S.V. Matsievskiy, R.E. Nemchenko, S.M. Polozov, A.V. Samoshin, V.L. Shatokhin, N.P. Sobenin, D.V. Surkov, K.V. Taletskiy, V. Zvyagintsev MEPhI, Moscow, Russia A.A. Bakinowskaya, V.S. Petrakovsky, I.L. Pobol, A.I. Pokrovsky, D.A. Shparla, A. Shvedau, S.V. Yurevich, V.G. Zaleski Physical-Technical Institute of the National Academy of Sciences of Belarus, Minsk, Belarus M.A. Baturitski, S.A. Maksimenko INP BSU, Minsk, Belarus A.V. Butenko, N. Emelianov, M. Gusarova, A.O. Sidorin, E. Syresin, G.V. Trubnikov JINR, Dubna, Moscow Region, Russia S.E. Demyanov Scientific-Practical Materials Research Centre of the National Academy of Sciences of Belarus, Minsk, Belarus V.A. Karpovich BSU, Minsk, Belarus T. Kulevoy ITEP, Moscow, Russia V.N. Rodionova Belarussian State University, Scientific Research Institute of Nuclear Problems, Minsk, Belarus A.O. Sidorin Saint Petersburg State University, Saint Petersburg, Russia V. Zvyagintsev TRIUMF, Vancouver, Canada
	A superconducting or partially superconducting linac is discussed as new injector for Nuclotron-NICA complex. New linac will accelerate protons up to 25 MeV (and up to 50 MeV at the second stage of the project) and light ions to ~7.5 MeV/u. The progress in R&D of QWR and HWR superconducting cavities is discussed in this report. The design of QWR and its normal conducting copper model is finished and PTI NANB is ready to manufacture of the prototype. Two designs of HWR were discussed: one with a cylindrical central conductor and another with the conical one. The electrodynamics design of HWR had been finished before now but it should be corrected taking into account some manufacture problems. Current results of the development of the RF coupler and the test cryostat will also present .
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WEPSB48	Input Power Coupler for NICA Injector Coaxial Half Wave SC Cavity	375
	S.V. Matsievskiy, M. Gusarova, M.V. Lalayan MEPhI, Moscow, Russia
	Nuclotron-based Ion Collider fAcility (NICA) is being built in Dubna, Russian Federation. Usage of the accelerator superconducting HWR cavities for the injector part of the accelerator is considered. According to technical requirements power coupler is able to withstand 13 kW of RF average transmitting power. Additionally, coupling tuning in small range should be possible. In this paper results of the 325 MHz HWR power coupler R&D are presented and discussed.
	Poster WEPSB48 [1.507 MB]
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEPSB48
Export •	reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)