RUPAC2018 - List of Authors (Korchuganov, V.)

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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TUXMH02	The Main Problems and Its Solutions in Modern SR Sources	22
	V. Korchuganov NRC, Moscow, Russia
	This report is an attempt to consider the main experimental requirements for modern sources of synchrotron radiation based on electron storage rings, the accelerating problems arising from these requirements and their technologically available solutions for today.
	Slides TUXMH02 [0.160 MB]
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-TUXMH02
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WEZMH01	Status of the Kurchatov Synchrotron Radiation Source	81
	A.G. Valentinov, A. Belkov, Ye. Fomin, E.V. Kaportsev, V. Korchuganov, Y.V. Krylov, V.I. Moiseev, K. Moseev, N.I. Moseiko, D.G. Odintsov, S.G. Pesterev, A.S. Smygacheva, A.I. Stirin, V. Ushakov, V.L. Ushkov, A. Vernov NRC, Moscow, Russia
	The Kurchatov synchrotron radiation source goes on to operate in the range of synchrotron radiation from VUV up to hard X-ray. An electron current achieved 200 mA at 2.5 GeV, up to 12 experimental stations may function simultaneously. An improvement of an injection process allowed to minimize injection time and to increase injection efficiency. A production of two new superconducting wigglers is now in progress in BINP (Novosibirsk). They will be installed on the main ring in next year. Great modernization of the whole facility is planned for 2020. The present status and future plans of the Kurchatov synchrotron radiation source is presented in the report.
	Slides WEZMH01 [4.947 MB]
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEZMH01
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WEZMH02	Kurchatov Synchrotron Radiation Source - From the 2nd to the 4th Generation	84
	Ye. Fomin, V. Korchuganov NRC, Moscow, Russia
	Funding: Work is supported by the Ministry of Science and Education of Russian Federation, Agreement No 14.616.21.0086 from 24.12.2017, ID RFMEFI61617X0086 The inauguration of the only dedicated synchrotron radiation source in Russia was held at NRC "Kurchatov Institute" in 1999. At present according to its main parameters it is a "2+" generation synchrotron light facility. In this article we consider the possibility of the Kurchatov synchrotron radiation source upgrade up to compact 3rd generation facility with keeping of all experimental stations at the same places. Also we present the conceptual design of the new diffraction limited synchrotron radiation source (4th generation facility) for NRC "Kurchatov Institute".
	Slides WEZMH02 [8.347 MB]
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEZMH02
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WEPSB28	Em Fields in a Metal in an External Magnetic Field at Low Temperatures	340
	V.I. Moiseev, V. Korchuganov NRC, Moscow, Russia
	Radio waves do not penetrate deep into the metal due to the high density of charge carriers in the metal. In the shorter-wave part of the spectrum, metals can be "transparent" only starting from ultraviolet, since the plasma frequencies in metals lie in the ultraviolet range. However, for a metal cooled to a low temperature and placed in an external magnetic field, the situation may change. Under these conditions, cyclotron orbits can be formed, and the relaxation time can significantly exceed the period of cyclotron motion of the charge carriers. For an electromagnetic wave with polarization normal to the induction vector of an external magnetic field, the exchange of energy with charge carriers in the metal turns out to be suppressed. Such a wave can propagate in the metal for relatively large distances (in comparison with the skin layer). In this connection, in electron storage rings at the azimuths, for example, of superconducting strong-field wigglers, with the magnetic field rise, the effect in the surface impedance change of the wiggler vacuum chamber metal can be manifested. This report is a brief review of some of results known in solid state physics applicable to these conditions and of interest to accelerator technology.
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEPSB28
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THPSC04	New Superconducting Wigglers for KSRS	407
	A.G. Valentinov, V. Korchuganov, V. Ushakov NRC, Moscow, Russia S.V. Khrushchev, N.A. Mezentsev, V.A. Shkaruba, V.M. Tsukanov BINP SB RAS, Novosibirsk, Russia
	Presently a program of incorporation of two new superconducting wigglers into main ring of Kurchatov synchrotron radiation source is implemented in NRC Kurchatov Institute. The wigglers are intended for new experimental stations "Belok-2" (biology studies) and "VEU" (exploration of materials in extreme conditions). The wigglers are designed for maximal magnetic field 3 T with 48 mm period and contain 50 pairs of poles with maximum field. Technical details of wigglers' construction are presented in the report along with a description of testing and mounting procedures. An influence of the wigglers on beam dynamic is described.
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-THPSC04
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THPSC06	New Automated Control System for the Kurchatov Synchrotron Radiation Source	414
	N.I. Moseiko, Y.V. Efimov, Ye. Fomin, E.V. Kaportsev, V. Korchuganov, Y.V. Krylov, K. Moseev, A.S. Smygacheva, A.G. Valentinov NRC, Moscow, Russia L.A. Moseiko, A.V. Shirokov RRC, Moscow, Russia
	The paper describes the new automated control system (ACS) for the Kurchatov syncrotron radiation source (KSRS), which is based on the modern servers and network equipment, VME equipment, National Instruments modules, time server, power equipment with built in intelligent controllers. The new system includes around 2300 control channels and 5900 measuring channels. Control programs that provide user interfaces, monitoring of the system operation, data acquisition, data processing and data storage, were developed using Citect SCADA 7.2, SCADA Historian Server, LynxOS Runtime, LabVIEW-2013, OC ARTX166, PCAN-Evaluation. The new ACS KSRS has allowed to increase the number of control and measuring channels, to increase the speed and accuracy of the measurements, to increase the speed of data processing and data transmitting. As a result, the main parameters of the KSRS have been improved and its work efficiency increased.
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-THPSC06
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THPSC19	The Bunch Size Measurements in the Storage Ring SIBERIA-2	446
	A.S. Smygacheva, V. Korchuganov, A.I. Stirin NRC, Moscow, Russia
	An interaction of particles with each other and electromagnetic fields produced by an external source and the bunch in the vacuum chamber defines the electron bunch sizes in the storage ring. To research the influence of the bunch-chamber interaction on the longitudinal motion of electrons and to estimate the relative contribution of the observed effects, the measurements of bunch sizes and a bunch current spectrum were carried out in the storage ring SIBERIA-2. Results of measurements and analytical estimations are presented at this article.
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-THPSC19
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Paper

Title

Page

MOXMH04

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

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]

Export •

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TUXMH02

The Main Problems and Its Solutions in Modern SR Sources

22

V. Korchuganov
NRC, Moscow, Russia

This report is an attempt to consider the main experimental requirements for modern sources of synchrotron radiation based on electron storage rings, the accelerating problems arising from these requirements and their technologically available solutions for today.

Slides TUXMH02 [0.160 MB]

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-TUXMH02

Export •

reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)

WEZMH01

Status of the Kurchatov Synchrotron Radiation Source

81

A.G. Valentinov, A. Belkov, Ye. Fomin, E.V. Kaportsev, V. Korchuganov, Y.V. Krylov, V.I. Moiseev, K. Moseev, N.I. Moseiko, D.G. Odintsov, S.G. Pesterev, A.S. Smygacheva, A.I. Stirin, V. Ushakov, V.L. Ushkov, A. Vernov
NRC, Moscow, Russia

The Kurchatov synchrotron radiation source goes on to operate in the range of synchrotron radiation from VUV up to hard X-ray. An electron current achieved 200 mA at 2.5 GeV, up to 12 experimental stations may function simultaneously. An improvement of an injection process allowed to minimize injection time and to increase injection efficiency. A production of two new superconducting wigglers is now in progress in BINP (Novosibirsk). They will be installed on the main ring in next year. Great modernization of the whole facility is planned for 2020. The present status and future plans of the Kurchatov synchrotron radiation source is presented in the report.

Slides WEZMH01 [4.947 MB]

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEZMH01

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reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)

WEZMH02

Kurchatov Synchrotron Radiation Source - From the 2nd to the 4th Generation

84

Ye. Fomin, V. Korchuganov
NRC, Moscow, Russia

Funding: Work is supported by the Ministry of Science and Education of Russian Federation, Agreement No 14.616.21.0086 from 24.12.2017, ID RFMEFI61617X0086
The inauguration of the only dedicated synchrotron radiation source in Russia was held at NRC "Kurchatov Institute" in 1999. At present according to its main parameters it is a "2+" generation synchrotron light facility. In this article we consider the possibility of the Kurchatov synchrotron radiation source upgrade up to compact 3rd generation facility with keeping of all experimental stations at the same places. Also we present the conceptual design of the new diffraction limited synchrotron radiation source (4th generation facility) for NRC "Kurchatov Institute".

Slides WEZMH02 [8.347 MB]

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEZMH02

Export •

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WEPSB28

Em Fields in a Metal in an External Magnetic Field at Low Temperatures

340

V.I. Moiseev, V. Korchuganov
NRC, Moscow, Russia

Radio waves do not penetrate deep into the metal due to the high density of charge carriers in the metal. In the shorter-wave part of the spectrum, metals can be "transparent" only starting from ultraviolet, since the plasma frequencies in metals lie in the ultraviolet range. However, for a metal cooled to a low temperature and placed in an external magnetic field, the situation may change. Under these conditions, cyclotron orbits can be formed, and the relaxation time can significantly exceed the period of cyclotron motion of the charge carriers. For an electromagnetic wave with polarization normal to the induction vector of an external magnetic field, the exchange of energy with charge carriers in the metal turns out to be suppressed. Such a wave can propagate in the metal for relatively large distances (in comparison with the skin layer). In this connection, in electron storage rings at the azimuths, for example, of superconducting strong-field wigglers, with the magnetic field rise, the effect in the surface impedance change of the wiggler vacuum chamber metal can be manifested. This report is a brief review of some of results known in solid state physics applicable to these conditions and of interest to accelerator technology.

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-WEPSB28

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THPSC04

New Superconducting Wigglers for KSRS

407

A.G. Valentinov, V. Korchuganov, V. Ushakov
NRC, Moscow, Russia
S.V. Khrushchev, N.A. Mezentsev, V.A. Shkaruba, V.M. Tsukanov
BINP SB RAS, Novosibirsk, Russia

Presently a program of incorporation of two new superconducting wigglers into main ring of Kurchatov synchrotron radiation source is implemented in NRC Kurchatov Institute. The wigglers are intended for new experimental stations "Belok-2" (biology studies) and "VEU" (exploration of materials in extreme conditions). The wigglers are designed for maximal magnetic field 3 T with 48 mm period and contain 50 pairs of poles with maximum field. Technical details of wigglers' construction are presented in the report along with a description of testing and mounting procedures. An influence of the wigglers on beam dynamic is described.

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-THPSC04

Export •

reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)

THPSC06

New Automated Control System for the Kurchatov Synchrotron Radiation Source

414

N.I. Moseiko, Y.V. Efimov, Ye. Fomin, E.V. Kaportsev, V. Korchuganov, Y.V. Krylov, K. Moseev, A.S. Smygacheva, A.G. Valentinov
NRC, Moscow, Russia
L.A. Moseiko, A.V. Shirokov
RRC, Moscow, Russia

The paper describes the new automated control system (ACS) for the Kurchatov syncrotron radiation source (KSRS), which is based on the modern servers and network equipment, VME equipment, National Instruments modules, time server, power equipment with built in intelligent controllers. The new system includes around 2300 control channels and 5900 measuring channels. Control programs that provide user interfaces, monitoring of the system operation, data acquisition, data processing and data storage, were developed using Citect SCADA 7.2, SCADA Historian Server, LynxOS Runtime, LabVIEW-2013, OC ARTX166, PCAN-Evaluation. The new ACS KSRS has allowed to increase the number of control and measuring channels, to increase the speed and accuracy of the measurements, to increase the speed of data processing and data transmitting. As a result, the main parameters of the KSRS have been improved and its work efficiency increased.

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-THPSC06

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THPSC19

The Bunch Size Measurements in the Storage Ring SIBERIA-2

446

A.S. Smygacheva, V. Korchuganov, A.I. Stirin
NRC, Moscow, Russia

An interaction of particles with each other and electromagnetic fields produced by an external source and the bunch in the vacuum chamber defines the electron bunch sizes in the storage ring. To research the influence of the bunch-chamber interaction on the longitudinal motion of electrons and to estimate the relative contribution of the observed effects, the measurements of bunch sizes and a bunch current spectrum were carried out in the storage ring SIBERIA-2. Results of measurements and analytical estimations are presented at this article.

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-THPSC19

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