Status of “ZELENOGRAD” storage ring
In 2000, after a long break, works on creation of a technological storage ring complex (TSC) have been renewed in ZELENOGRAD. TSC was developed at Budker INP of Siberian Branch of Russian Academy of Science. It consists of a linear accelerator on the electron energy up to 80 MeV, a small storage rin...
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| Zitieren: | Status of “ZELENOGRAD” storage ring / V. Arbuzov, K. Chernov, A. Chernyakin, I. Churkin, B. Dovzhenko, E. Gorniker, A. Kondakov, V. Kozak, S. Krutikhin, G. Kulipanov, E. Kuper, I. Kuptsov, G. Kurkin, A. Medvedko, G. Ostreiko, V. Petrov, A. Philipchenko, A. Pilan, I. Sedlyarov, G. Serdobintsev, S. Sinyatkin, A. Steshov, S. Tararyshkin, S. Vasichev, V. Veremeenko, V. Ushakov, D. Shvedov, V. Yudin // Вопросы атомной науки и техники. — 2008. — № 5. — С. 3-7. — Бібліогр.: 2 назв. — англ. |
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Digital Library of Periodicals of National Academy of Sciences of Ukraine| _version_ | 1860266518007250944 |
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| author | Arbuzov, V. Chernov, K. Chernyakin, A. Churkin, I. Dovzhenko, B. Gorniker, E. Kondakov, A. Kozak, V. Krutikhin, S. Kulipanov, G. Kuper, E. Kuptsov, I. Kurkin, G. Medvedko, A. Ostreiko, G. Petrov, V. Philipchenko, A. Pilan, A. Sedlyarov, I. Serdobintsev, G. Sinyatkin, S. Steshov, A. Tararyshkin, S. Vasichev, S. Veremeenko, V. Ushakov, V. Shvedov, D. Yudin, V. |
| author_facet | Arbuzov, V. Chernov, K. Chernyakin, A. Churkin, I. Dovzhenko, B. Gorniker, E. Kondakov, A. Kozak, V. Krutikhin, S. Kulipanov, G. Kuper, E. Kuptsov, I. Kurkin, G. Medvedko, A. Ostreiko, G. Petrov, V. Philipchenko, A. Pilan, A. Sedlyarov, I. Serdobintsev, G. Sinyatkin, S. Steshov, A. Tararyshkin, S. Vasichev, S. Veremeenko, V. Ushakov, V. Shvedov, D. Yudin, V. |
| citation_txt | Status of “ZELENOGRAD” storage ring / V. Arbuzov, K. Chernov, A. Chernyakin, I. Churkin, B. Dovzhenko, E. Gorniker, A. Kondakov, V. Kozak, S. Krutikhin, G. Kulipanov, E. Kuper, I. Kuptsov, G. Kurkin, A. Medvedko, G. Ostreiko, V. Petrov, A. Philipchenko, A. Pilan, I. Sedlyarov, G. Serdobintsev, S. Sinyatkin, A. Steshov, S. Tararyshkin, S. Vasichev, V. Veremeenko, V. Ushakov, D. Shvedov, V. Yudin // Вопросы атомной науки и техники. — 2008. — № 5. — С. 3-7. — Бібліогр.: 2 назв. — англ. |
| collection | DSpace DC |
| container_title | Вопросы атомной науки и техники |
| description | In 2000, after a long break, works on creation of a technological storage ring complex (TSC) have been renewed in ZELENOGRAD. TSC was developed at Budker INP of Siberian Branch of Russian Academy of Science. It consists of a linear accelerator on the electron energy up to 80 MeV, a small storage ring on the energy 450 MeV, a main storage ring on the energy 2 GeV and two electron transfer lines (TL-1 and TL-2). The Main Ring (MR) with energy of electrons 2 GeV is the dedicated synchrotron radiation source intended for the decision of problem of submicron technologies and realization of various researches in a range of wavelengths of 0.2…2000 Å. Linac was mounted and put into operation during 2000-2002. The circulating electron current was received in small storage ring in 2005. Currently, the assembling of TL-2 is being completed. The inspection of the main storage ring equipment made before is carried out. Besides, a modification of all control and power supply system MR is done and a modern electronic element base will be introduced. The status and the nearest planes concerning TSC main storage ring are described.
У 2000 р. після довгої перерви відновилися роботи по створенню технологічного накопичувального комплексу - ТНК, у м. Зеленограді. ТНК був розроблений в ІЯФ СВ РАН. Він складається з лінійного прискорювача (ЛП) на енергію до 80 МеВ, малого накопичувача (МН) на енергію 450 МеВ, основного великого накопичувача (ВН) на енергію 2,2 ГеВ і двох каналів перепуску (ЕОК-1 й ЕОК-2). Накопичувач електронів з енергією електронів Е = 2,2 ГеВ є спеціалізованим джерелом СВ, призначеним для вирішення проблем субмікронних технологій, а також для проведення досліджень у проміжку довжин хвиль 0.2…2000 Å. Лінійний прискорювач був змонтований і запущений протягом 2000-2002 р. У 2005 р. був отриманий циркулюючий струм електронів у Малому накопичувачі. У цей час закінчується монтаж ЕОК-2. Проводиться ревізія устаткування ВН. Крім того, проводиться модернізація всіх систем керування і живлення і перехід на сучасну елементну базу. Описується статус ТНК і найближчі плани по монтажу і запуску ВН.
В 2000 г. после долгого перерыва возобновились работы по созданию технологического накопительного комплекса – ТНК, в г. Зеленограде. ТНК был разработан в ИЯФ СО РАН. Он состоит из линейного ускорителя (ЛУ) на энергию до 80 МэВ, Малого накопителя (МН) на энергию 450 МэВ, основного большого накопителя (БН) на энергию 2.2 ГэВ и двух каналов перепуска (ЭОК-1 и ЭОК-2). Накопитель электронов с энергией электронов Е = 2.2 ГэВ является специализированным источником СИ, предназначенным для решения проблем субмикронных технологий, а также для проведения исследований в области длин волн 0.2…2000 ангстрем. Линейный ускоритель был смонтирован и запущен в течение 2000-2002 г. В 2005 г. был получен циркулирующий ток электронов в Малом накопителе. В настоящее время заканчивается монтаж ЭОК-2. Проводится ревизия оборудования БН. Кроме того, проводится модернизация всех систем управления и питания и переход на современную элементную базу. Описывается статус ТНК и ближайшие планы по монтажу и запуску БН.
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| first_indexed | 2025-12-07T19:01:22Z |
| format | Article |
| fulltext |
Физика и техника ускорителей
STATUS OF “ZELENOGRAD” STORAGE RING
V. Arbuzov, K. Chernov, A. Chernyakin, I. Churkin, B. Dovzhenko, E. Gorniker, A. Kondakov,
V. Kozak, S. Krutikhin, G. Kulipanov, E. Kuper, I. Kuptsov, G. Kurkin, A. Medvedko, G. Os-
treiko, V. Petrov, A. Philipchenko, A. Pilan, I. Sedlyarov, G. Serdobintsev, S. Sinyatkin,
A. Steshov, S. Tararyshkin, S. Vasichev, V. Veremeenko, V. Ushakov, D. Shvedov, V. Yudin
Budker Institute of Nuclear Physics SB RAS, Lavrentiev 11, 630090, Novosibirsk, Russia;
A.Valentinov, V. Korchuganov, Yu. Krylov, K. Kusnetsov, D. Odintsov, Yu. Yupinov
Kurchatov Center of Synchrotron Radiation and Nanotechnology, Kurchatov Institute,
Kurchatov Sg. 1, 123182, Moscow, Russia;
N. Grachev, V. Khramtsov, V. Mishachev, N. Spinko
Federal State Institution “Lukin Research Institute of Physical Problem”,
124460, Moscow, Russia
In 2000, after a long break, works on creation of a technological storage ring complex (TSC) have been renewed
in ZELENOGRAD. TSC was developed at Budker INP of Siberian Branch of Russian Academy of Science. It con-
sists of a linear accelerator on the electron energy up to 80 MeV, a small storage ring on the energy 450 MeV, a
main storage ring on the energy 2 GeV and two electron transfer lines (TL-1 and TL-2). The Main Ring (MR) with
energy of electrons 2 GeV is the dedicated synchrotron radiation source intended for the decision of problem of sub-
micron technologies and realization of various researches in a range of wavelengths of 0.2…2000 Å. Linac was
mounted and put into operation during 2000-2002. The circulating electron current was received in small storage
ring in 2005. Currently, the assembling of TL-2 is being completed. The inspection of the main storage ring equip-
ment made before is carried out. Besides, a modification of all control and power supply system MR is done and a
modern electronic element base will be introduced. The status and the nearest planes concerning TSC main storage
ring are described.
PACS: 29.17.-w
1. INTRODUCTION
Synhrotron Radiation (SR) opened up the possibility
to realize some new technologies such as X-ray lithog-
raphy for manufacturing of submicron structure devices
and LIGA-technologies for production of micro- me-
chanical tools.
The TSC complex has been developed and manufac-
tured in Budker BINP SB RAS.
Fig.1. TSC Complex: the Synchrotron Radiation source
in Zelenograd
The complex consists of Linear Accelerator (LA) of
80 MeV energy and two Storage Rings: 450 MeV Small
Storage Ring (SSR) and 2.2 GeV Main Storage Ring
(MSR).
It is meant for generation of bright Synhrotron Radi-
ation (SR) beams in infra-red (IR), ultra-violet (UV) and
X-ray areas of spectrum in the wave length range of
0.1…2000 Å.
When the complex of specialized Synhrotron Radia-
tion sources was developed the optimization of magnet-
ic structure parameters has been hold in order to obtain
minimum electron beam emittance and to provide maxi-
mum radiation brightness from bending magnets as well
as to get the possibility to install insertion devices like
undulators, mini-undulators and strong field wigglers. It
was assumed to have 37 beam line: 20 technology beam
from superconducting wigglers line; 10 analytical beam
line with use hard SR; 7 analytical beam line with use
soft and VUV SR.
Currently main purpose of the project is creation of
universal nanotechnology and metrology complex in
Lukin NIIFP, Zelenograd in accordance Nanotechnolo-
gy Federal Programm.
2. INJECTION SYSTEM OF THE MSR
The accepted two-stage injection system is a most
efficient variant of the complex structure. Injection part
of MR consists of 80 MeV Linear accelerator (LA),
450 MeV small storage ring (SSR) and two transfer
lines TL-1 and TL-2.
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PROBLEMS OF ATOMIC SCIENCE AND TECHNOLOGY. 2008. № 5.
Series: Nuclear Physics Investigations (50), p.3-7.
3
2.1. LINEAR ACCELERATOR
The 80 MeV Linear accelerator (LA) is an electron
source of SSR [1]. It was commissioned at NIIFP of
F.V.Lukin (Zelenograd, Moscow) in 2002.
Currently received principle parameters of electron
beam at LA output are shown in Table 1[1].
Table 1. Main parameters of electron beam
Beam Energy 70 MeV
Energy spread 1%
Pulse beam current ~ 80 mA
Pulse duration 15 ns
Transversal emittance 0.1 mrad⋅cm
Repetition rate 1…2 Hz
In 2007 a thermostabilization of accelerating struc-
ture is planned to be assembled and put into operation as
well as to be trained up to 80 MeV.
2.2. TRANSFER LINE TL-1
TL-1 is meant for transfer of electron beam from LA
to SSR and for beam emittance matching at LA output
with SSR acceptance. TL-1 consists of straight section
with quadrupole triplet and an area with two 12о bending
magnets meant for parallel transfer of electron beam.
2.3. SMALL STORAGE RING (SSR)
Small storage ring (SSR) is a booster for MSR with
the following parameters: single bunch with energy
Е=450 MeV,electron current I~150 mA and longitudi-
nal size σs =30 cm.
Fig.2 shows the SSR preinflector and inflector sec-
tions and an area of injection channel. The section I is
put under injection septum, RF cavity and beam current
sensor. Inside vacuum chamber of II and 1V straight
sections, including quadrupole lenses and vertical orbit
corrector, there are plates of preinflector and inflector
plates. To compensate the chromatism in straight sec-
tions II and III the sextupoles are placed. In section IV
there is octupole lens to compensate cubic nonlinearity
of magnetic field. The extraction septum is placed in
straight section III.
Fig.2. Small Storage Ring
2.3.1. INJECTION AND EXTRACTION OF SSR
Injection in SSR from LA is single-turn and is car-
ried out in vertical plane at 12º angle to median plane.
Multiple storage of particles uses pre-kick. Vertical ac-
ceptance is Aу= 5.6⋅10-3 cm·rad.
From SR the electrons are also extracted up in verti-
cal plane at 20º angle turn to median plane. Before ex-
traction an orbit is corrected in vertical direction and a
beam is moved to the septum magnet. 20 ns duration
electromagnetic pulse of deflector plates (inflector in
accumulation mode) raises beam path up to the septum
magnet aperture. In the septum magnet the extracted
electron path is moved into transfer line TL-2. SSR ex-
traction cycle period should be T ~ 0.5 min at circulated
beam current I ~ 100…150 mA.
2.3.2. SSR VACUUM SYSTEM
All elements of SR vacuum system are made from
stainless steel without any rubber or viton seals. The RF
cavity insertion is made from ceramic. Either welded
connections or metal seals are applied everywhere. That
allows to heat vacuum chamber up to 250ºC.
2.3.3. SSR RF SYSTEM
SSR RF system provides required amplitude 15 kV
of RF voltage in cavity. For injection into MR at storage
of one RF separatrix it is important that an injected
beam was in single bunch. That is why first harmonic of
frequency f0 = 34,59 МHz is used.
Main SSR beam parameters are shown in Table 2.
Table 2. Main SSR beam parameters
Energy, E 0, 45 GeV
Circumference, C 8.6832 m
Bending magnet field, B 1.5 Т
Relative energy spread, δЕ/Е 3.8⋅10-4
RF harmonic number, q 1
RF frequency, fRF 34.59 МHz
Field decay index, n 0.5
Betatron numbers: νх, νу 0.793, 0.895
Relative energy spread, δЕ/Е 3.8⋅10-4
Horizontal emittance 8.6⋅10-7 mrad
Vertical emittance 8.6⋅10-9 mrad
Radiation damping time τх, τу, τs 7.5, 7.2, 3.4 msec
At the end of 2005 the small storage ring was com-
missioned, the accumulation mode was reached. That
justified that all SSR systems are efficient and there are
no bad mistakes. However, at pre-start heating up, in ce-
ramic insertion in cavity straight section a leakage has
appeared. We had no reserved ceramic insertion and the
production of a new one would take a lot of time. That
is why accumulated current was sufficiently limited be-
cause of low vacuum characterizing a lifetime of circu-
lating beam. During 2006 a new ceramic insertion has
been produced and replaced. SSR vacuum chamber has
been heated up and vacuum P = 10-6 Pa was reached.
Currently, the vacuum chamber is under constant pump-
ing and vacuum is P = 10-6 Pa.
Up to the end of 2007 we are planning to accelerate
a beam in SSR and extract it into TL-2. During 2008 we
are expecting to get all calculated beam parameters.
2.4. TRANSFER LINE TL-2
TL-2 is meant for transfer of electrons from SSR
into MSR. It includes:
two 20° bending magnets (4М1 and 4М2) providing
vertical parallel transfer of beam three horizontal 20°
4
bending magnets (4М3, 4М4 and 4М5) for horizontal
60° bend of a beam six quadruples to match the transfer
of beam parameters.
Pulse magnet 4М1 with a field of sinusoidal shape is
fed from special generator. It is placed in a straight sec-
tion of SSR. Pulse duration t = 100 μsec, maximum
magnitude В = 3 Т, bending radius R = 0.5 m.
Direct current magnet 4М2 is fed from special power
supply В-1000 with current up to I = 1 kA. 4M2 – mag-
nitude is В=1.5 Т, bending radius – R = 1 m. Magnets
4М3 and 4М4 are the same as magnet 4М2. They are
connected in series and fed from the same В-1000.
Pulse magnet 4М5 with a field of sinusoidal shape is
fed from special generator. It is placed in a straight sec-
tion of MSR. Pulse duration is t=100 μsec, maximum
magnitude В=2 Т, bending radius R= 0.75 m. To reduce
the leakage of magnetic fields into MSR vacuum cham-
ber there is insertion made from “ARMCO”.
TL-2 is assembled up to 4М4 magnet. The vacuum
chamber was pumped to forevacuum. In the nearest fu-
ture (October 2007) a beam position sensors and other
missing TL-2 elements to the injection MSR septum
will be mounted. The vacuum chamber will be heated
up in order to start it up by the end of 2007.
3. MAIN STORAGE RING (MSR)
When creating the specialized storages, SR sources,
it is most important to reach bright spectral photon flux-
es. SR source magnetic structure should provide the
possibility to install the undulators and superconductive
wigglers in straight sections for storing the electron
beam small emittance. In general, the necessity to reach
high radiation brighness from bending magnet, high
field multipole wiggler and undulator had been revised.
Thereupon, the range of optimal behavior of betatron
and dispersion functions on azimuths of those SR
sources has been found. Optimal amplitude functions of
the storage have significantly different behavior on az-
imuths of bending magnets, wigglers and undulators.
Table 3 shows principal parameters of Main Storage
Ring the specialized SR source [2].
3.1. MAGNETIC STRUCTURE
Calculated magnetic structure of MSR consists of
six mirror-symmetric super periods. Each super period
has two 3 m straight sections for undulators, wigglers,
injection and RF cavity. At 2.2 GeV energy the horizon-
tal emittance of electron beam is caused by quantum
fluctuations of radiation. The basic stability range of be-
tatron movement is within νx=0.73, νz =0.74.
Magnetic structure, amplitude functions βx(s), βy(s)
and dispersion of MR super period are shown in Fig.3.
The start and the end of super periods are the centers
of zero-dispersion sections, which are, mainly, meant
for installation of high field wigglers and RF cavities. In
the centers of super periods, inside achromatic bend,
there are sections where undulators and injection sep-
tum magnet may be installed.
The MSR superperiod structure consists of 12
quadrupole lenses and 4 bending magnets. The part of
the structure, which includes undulator section,
quadrupole lenses F1 and D1 and bending magnets B
provides the possibility to obtain achromatic bend and
big βx, βy, which are optimal for installation of undula-
tor and sextupole lenses to compensate chromatism.
Fig.3. Magnetic structure and amplitude Function
of MSR superperiod
Another part, including lenses D2, F3, D3 and wig-
gler section, provides frequency variations of betatron
oscillations, omitting the distortion of achromatic bend.
It also provided generation of optimal βx, βy in the wig-
gler straight section. 30º bending magnet is divided into
two similar (mirror-symmetric) 15º magnets. The loca-
tion of F2 quadrupole between 15° bending magnets in
focus of achromatic bend system, provides the possibili-
ty of easy position control of minimum horizontal beta
function (from the right and at the left of lens F2) at
reaching the necessary emittance.
Optimal position and minimum value βx0 in bending
magnet corresponding to minimum emittance εxmin, are
reached as in achromatic bend scheme, which is realized
only by two bending magnets (without separation into
two) and by two doublets of lenses F1 and D1. Howev-
er, at the same time, emittance minimization is practi-
cally impossible because the length of undulator section
is necessary to be no less than horizontal beta function
in it (βx ~ 20 m), i.e. the value should be very high. Sep-
aration of magnet into two and installation of lens F2 re-
move this limit, and focusing system inside achromatic
bend gets necessary flexibility and allows one to change
easily the undulator straight section length in a wide
range. In our case, lund = 318 cm is accepted. Besides,
there is an opportunity to get injection scheme with two
inlet kickers placed on lenses F2 azimuths inside one
achromatic bend with betatron phase incursion, equal to
π/2, between them. As a result of bending magnet short-
ening the construction of vacuum chamber is also light-
ened and SR extraction gets easier.
Values of bending magnet functions βx and η are
close to be optimal. In each bending magnet value βx is
no more than 3.5 meters. In extraction radiation points it
is equal to 2.5 and 0.6 meters that provides the radiation
extraction from magnet of SR beam with brightness
close to maximum.
In a 3 m long straight section, which is meant for
placement of super conductive wiggler with high mag-
netic field, the dispersion and its derivative are equal to
zero (ηw = ηw′ = 0). That is why, when installing the wig-
glers, there is an addition possibility to reduce emittance.
____________________________________________________________
PROBLEMS OF ATOMIC SCIENCE AND TECHNOLOGY. 2008. № 5.
Series: Nuclear Physics Investigations (50), p.3-7.
5
Horizontal beta-function in the center of wiggler section
βx = 6 m is sufficiently big. Its value is a compromise be-
tween acceptable distinction of dispersion from zero in
wiggler section and, from other hand, necessary condition
for high brightness at zero angularly. Vertical βy function
is small (~0.5 m). That guarantees a small shift of vertical
betatron frequency at installation of high field wigglers.
In accordance with calculations, the betatron tune shift in-
troduced by super conductive wiggler with super high
field ∆νу ~ 5⋅10-3. It is enough easily compensated by
these local area, without introducing noticeable pulsations
of structural functions in the ring.
Table 3. MSR Main Parameters
Energy E 2 GeV
Perimeter П 115.73 m
Super period quantity N 6
Bending magnets mag-
netic field
B 0.37; 1.5 Т
Quantity of 3 meters long
sections
12
Betatron numbers νх, νу 7,73; 7.74
Ratio of orbit spatial
compression
α 9.9*10-3
х, у − chromatism xX, x Z -19; -20
Horizontal emittance εx 35 nm-rad
Vertical emittance εy 0.35 nm-rad
х, у, s − damping time tх,ty,ts 4.15;4.3;2.0 ms
Turn frequency f 2.5905 МHz
RF multiplicity N 70
RF voltage U 1200 kV
Current:
а) single bunch mode
б) multi bunch mode
I 100 mA
300 mA
Depending on tuning the undulator section is charac-
terized by high betatron functions being necessary to get
weakly-divergent electron beam βx = 12…17 m, β
y = 4…6 m, and dispersion function is small ηxmax =80…
114 cm.
Each magnetic elements of “Siberia-2” are made
from magnetically soft non-laminated Armco iron.
Storage magnetic system includes 24 bending 15°
magnets connected in-series. Bending magnets of TSC
are of H-type. H-type constructions of magnetic elements
of TSC allows making SR beam lines through magnetic
yoke without distortion of high quality of magnetic field
at working region. The magnet is dismounted in median
plane into top and bottom halves. Effective magnetic
length is 1457 mm, and iron length is 1446.5 mm.
The bending magnet consists of one main long area
and another short area with a field being a quarter from
the main one at the edge of the magnet. SR spectrum of
2.5 GeV electrons, at areas with a field B=1.5T is
o
c A75.1=λ and B=0.375T is o
c A7=λ . The weak field
areas adjoin with quadruple lenses D1 and D2.
Such distribution of magnetic field and magnet
placement provides spatial radiation separation from a
magnet and radiation from wigglers and undulators.
Consequently, one provides the decrease of heat flow
from orbit area at magnet edges in straight section,
where the super conductive systems requiring cooling
would be installed.
Magnetic gap between plane-parallel poles of mag-
netic magnet is equal to 42 mm. At 2.2 GeV energy
power consumption of one magnet is 17.6 kW at a cur-
rent I = 6.3 kA and voltage U=2.8 В in main coil.
For closed orbit distortion in horizontal plane in the ar-
eas of weak field magnets the correction coils are provided.
Magnetic system MR includes 72 quadrupoles with
dipole and gradient correctors. They joint in 12 triplets,
12 dublets and 12 C-shape quadrupoles. The
quadrupoles are separated in 6 families. Each family
quadrupoles are connected in series and are fed from
power supply IST with current up to 1 kA.
3.2. CURRENT STATUS
All dipoles and quadrupoles Sextupoles and oc-
tupoles Multi-pole wigglers and undulators after long
storing, are revised in BINP. The revision includes
cleaning, electrical tests, magnetic measurements and, if
necessary, mechanical modification.
Dipoles will be delivered to Zelenograd in dezem-
ber, 2007.
Quadrupoles will be delivered to Zelenograd in
march-june, 2007.
Sextupoles and octupoles have been delivered to Ze-
lenograd in June, 2007.
Power supply systems for different magnets such as
TPV I=7.2 kA, IST: I=1.0 kA, В-1000: I=1.0 kA, TIR:
I=20 А, UM; I=5.0 А. will delivered to Zelenograd in
90th became obsolete. Besides, because of new Complex
Control Systems the modification of present and produc-
tion of new power supply sources is carried out. A part of
them will be delivered to Zelenograd and commissioned
in 2007 (magnet power supply of injection system).
MSR magnetic system power supply sources are
planned to be modified or produced and to be commis-
sioned at TSC in 2008-2009.
Pulse elements power supply (2М2, 4М1. 4М5).
The generators for septum 2М2 and 4М1 power supply
are assembled and started up at the Complex. The gen-
erator for septum 4М5 power supply is being produced.
It will be commissioned at the TSC in 2008.
Kicker power supply system. The generators for LA
gun and SSR kickers’ power supply were commissioned
and are operating at the Complex. The generators for
MSR kickers’ power supply are being assembled and
commissioned.
RF system is practically newly produced. The spare
parts are being purchased and generator is being assem-
bled and produced. Two cavities are manufactured in a
workshop. After “cold” and “hot” tests made in BINP,
they are planned to be delivered to the Complex at the
end of 2008.
Control system. Electronic units have been produced
in BINP. They are ready to be delivered to the Complex.
SOFT is developed by Kurchatov Synchrotron Radia-
tion and Nanotechnology Center. The mutual coopera-
tion with this Center is planned on a system start up and
its adjustment from the beginning of October 2007.
6
MSR vacuum system.
Dipole vacuum chamber is practically newly pro-
duced. Other part of vacuum system are revised and
tested. We respect the assembling of vacuum system at
the end 2008 – beginning 2009.
Our Plane: Main Storage Ring Commissioning will
be in 2009.
REFERENCES
1. K. Chernov, et al. // Problems of Atomic Science
and Technology. Series “Nuclear Physics Investi-
gations” (47). 2006, №3, p.12-14.
2. А.Г. Валентинов и др. Параметры ТНК-спе-
циализированного источника синхротронно-
го излучения: Препринт ИЯФ, 90-129, 1990.
Статья поступила в редакцию 14.09.2007 г.
СТАТУС НАКОПИТЕЛЯ ТНК (г. ЗЕЛЕНОГРАД)
В.C. Арбузов, К.Н. Чернов, А.Д. Чернякин, И.Н. Чуркин, Б.А. Довженко, Э.И. Горникер, А. Кондаков,
В.Р. Козак, С.А. Крутихин, Г.Н. Кулипанов, Э.А. Купер, И.В. Купцов, Г.Я. Куркин, А.С. Медведко,
Г.Н. Острейко, В.М. Петров, А.В. Филипченко, А.М. Пилан, И.К. Седляров, Г.В. Сердобинцев,
С.В. Синяткин, А.Г. Стешов, С.В. Тарарышкин, С.С. Васичев, В.Ф. Веремеенко, В.А. Ушаков,
Д.А. Шведов, В.Д. Юдин, А.Г. Валентинов, В.Н. Корчуганов, Ю.В. Крылов, К.Н. Кузнецов, Д.Г. Одинцов,
Ю.Л. Юпинов, Н.Н. Грачев, В.П. Храмцов, В.И. Мишачев, Н.В. Спинко
В 2000 г. после долгого перерыва возобновились работы по созданию технологического накопительного
комплекса – ТНК, в г. Зеленограде. ТНК был разработан в ИЯФ СО РАН. Он состоит из линейного ускори-
теля (ЛУ) на энергию до 80 МэВ, Малого накопителя (МН) на энергию 450 МэВ, основного большого нако-
пителя (БН) на энергию 2.2 ГэВ и двух каналов перепуска (ЭОК-1 и ЭОК-2). Накопитель электронов с энер-
гией электронов Е = 2.2 ГэВ является специализированным источником СИ, предназначенным для решения
проблем субмикронных технологий, а также для проведения исследований в области длин волн 0.2…
2000 ангстрем. Линейный ускоритель был смонтирован и запущен в течение 2000-2002 г. В 2005 г. был по-
лучен циркулирующий ток электронов в Малом накопителе. В настоящее время заканчивается монтаж ЭОК-
2. Проводится ревизия оборудования БН. Кроме того, проводится модернизация всех систем управления и
питания и переход на современную элементную базу. Описывается статус ТНК и ближайшие планы по
монтажу и запуску БН.
СТАТУС НАКОПИЧУВАЧА ТНК (м. ЗЕЛЕНОГРАД)
В.C. Арбузов, К.Н. Чернов, А.Д. Чернякін, І.Н. Чуркін, Б.А. Довженко, Е.І. Горникер, А. Кондаков,
В.Р. Козак, С.А. Крутихін, Г.Н. Куліпанов, Е.А. Купер, І.В. Купцов, Г.Я. Куркін, А.С. Медведко,
Г.Н. Острейко, В.М. Петров, А.В. Филипченко, А.М. Пілан, І.К. Седляров, Г.В. Сердобинцев,
С.В. Синяткін, А.Г. Стешов, С.В. Тараришкін, С.С. Васичев, В.Ф. Веремеєнко, В.А. Ушаков,
Д.А. Шведов, В.Д. Юдін, А.Г. Валентинов, В.Н. Корчуганов, Ю.В. Крилов, К.Н. Кузнецов, Д.Г. Одинцов,
Ю.Л. Юпінов, Н.Н. Грачов, В.П. Храмцов, В.І. Мишачев, Н.В. Спинко
У 2000 р. після довгої перерви відновилися роботи по створенню технологічного накопичувального
комплексу − ТНК, у м. Зеленограді. ТНК був розроблений в ІЯФ СВ РАН. Він складається з лінійного
прискорювача (ЛП) на енергію до 80 МеВ, малого накопичувача (МН) на енергію 450 МеВ, основного
великого накопичувача (ВН) на енергію 2,2 ГеВ і двох каналів перепуску (ЕОК-1 й ЕОК-2). Накопичувач
електронів з енергією електронів Е = 2,2 ГеВ є спеціалізованим джерелом СВ, призначеним для вирішення
проблем субмікронних технологій, а також для проведення досліджень у проміжку довжин хвиль 0.2…2000
Å. Лінійний прискорювач був змонтований і запущений протягом 2000-2002 р. У 2005 р. був отриманий
циркулюючий струм електронів у Малому накопичувачі. У цей час закінчується монтаж ЕОК-2.
Проводиться ревізія устаткування ВН. Крім того, проводиться модернізація всіх систем керування і
живлення і перехід на сучасну елементну базу. Описується статус ТНК і найближчі плани по монтажу і
запуску ВН.
____________________________________________________________
PROBLEMS OF ATOMIC SCIENCE AND TECHNOLOGY. 2008. № 5.
Series: Nuclear Physics Investigations (50), p.3-7.
7
Status of “Zelenograd” storage ring
2. Injection system of the MSR
2.2. Transfer line TL-1
2.3. Small storage ring (SSR)
2.3.1. Injection and extraction of SSR
2.3.2. SSR vacuum system
2.3.3. SSR RF system
2.4. Transfer line TL-2
3. Main Storage Ring (MSR)
3.1. Magnetic structure
3.2. Current status
Статус накопителя ТНК (г. Зеленоград)
СТАТУС НАКОПИЧУВАЧА ТНК (м. ЗЕЛЕНОГРАД)
|
| id | nasplib_isofts_kiev_ua-123456789-111455 |
| institution | Digital Library of Periodicals of National Academy of Sciences of Ukraine |
| issn | 1562-6016 |
| language | English |
| last_indexed | 2025-12-07T19:01:22Z |
| publishDate | 2008 |
| publisher | Національний науковий центр «Харківський фізико-технічний інститут» НАН України |
| record_format | dspace |
| spelling | Arbuzov, V. Chernov, K. Chernyakin, A. Churkin, I. Dovzhenko, B. Gorniker, E. Kondakov, A. Kozak, V. Krutikhin, S. Kulipanov, G. Kuper, E. Kuptsov, I. Kurkin, G. Medvedko, A. Ostreiko, G. Petrov, V. Philipchenko, A. Pilan, A. Sedlyarov, I. Serdobintsev, G. Sinyatkin, S. Steshov, A. Tararyshkin, S. Vasichev, S. Veremeenko, V. Ushakov, V. Shvedov, D. Yudin, V. 2017-01-10T09:06:18Z 2017-01-10T09:06:18Z 2008 Status of “ZELENOGRAD” storage ring / V. Arbuzov, K. Chernov, A. Chernyakin, I. Churkin, B. Dovzhenko, E. Gorniker, A. Kondakov, V. Kozak, S. Krutikhin, G. Kulipanov, E. Kuper, I. Kuptsov, G. Kurkin, A. Medvedko, G. Ostreiko, V. Petrov, A. Philipchenko, A. Pilan, I. Sedlyarov, G. Serdobintsev, S. Sinyatkin, A. Steshov, S. Tararyshkin, S. Vasichev, V. Veremeenko, V. Ushakov, D. Shvedov, V. Yudin // Вопросы атомной науки и техники. — 2008. — № 5. — С. 3-7. — Бібліогр.: 2 назв. — англ. 1562-6016 PACS: 29.17.-w https://nasplib.isofts.kiev.ua/handle/123456789/111455 In 2000, after a long break, works on creation of a technological storage ring complex (TSC) have been renewed in ZELENOGRAD. TSC was developed at Budker INP of Siberian Branch of Russian Academy of Science. It consists of a linear accelerator on the electron energy up to 80 MeV, a small storage ring on the energy 450 MeV, a main storage ring on the energy 2 GeV and two electron transfer lines (TL-1 and TL-2). The Main Ring (MR) with energy of electrons 2 GeV is the dedicated synchrotron radiation source intended for the decision of problem of submicron technologies and realization of various researches in a range of wavelengths of 0.2…2000 Å. Linac was mounted and put into operation during 2000-2002. The circulating electron current was received in small storage ring in 2005. Currently, the assembling of TL-2 is being completed. The inspection of the main storage ring equipment made before is carried out. Besides, a modification of all control and power supply system MR is done and a modern electronic element base will be introduced. The status and the nearest planes concerning TSC main storage ring are described. У 2000 р. після довгої перерви відновилися роботи по створенню технологічного накопичувального комплексу - ТНК, у м. Зеленограді. ТНК був розроблений в ІЯФ СВ РАН. Він складається з лінійного прискорювача (ЛП) на енергію до 80 МеВ, малого накопичувача (МН) на енергію 450 МеВ, основного великого накопичувача (ВН) на енергію 2,2 ГеВ і двох каналів перепуску (ЕОК-1 й ЕОК-2). Накопичувач електронів з енергією електронів Е = 2,2 ГеВ є спеціалізованим джерелом СВ, призначеним для вирішення проблем субмікронних технологій, а також для проведення досліджень у проміжку довжин хвиль 0.2…2000 Å. Лінійний прискорювач був змонтований і запущений протягом 2000-2002 р. У 2005 р. був отриманий циркулюючий струм електронів у Малому накопичувачі. У цей час закінчується монтаж ЕОК-2. Проводиться ревізія устаткування ВН. Крім того, проводиться модернізація всіх систем керування і живлення і перехід на сучасну елементну базу. Описується статус ТНК і найближчі плани по монтажу і запуску ВН. В 2000 г. после долгого перерыва возобновились работы по созданию технологического накопительного комплекса – ТНК, в г. Зеленограде. ТНК был разработан в ИЯФ СО РАН. Он состоит из линейного ускорителя (ЛУ) на энергию до 80 МэВ, Малого накопителя (МН) на энергию 450 МэВ, основного большого накопителя (БН) на энергию 2.2 ГэВ и двух каналов перепуска (ЭОК-1 и ЭОК-2). Накопитель электронов с энергией электронов Е = 2.2 ГэВ является специализированным источником СИ, предназначенным для решения проблем субмикронных технологий, а также для проведения исследований в области длин волн 0.2…2000 ангстрем. Линейный ускоритель был смонтирован и запущен в течение 2000-2002 г. В 2005 г. был получен циркулирующий ток электронов в Малом накопителе. В настоящее время заканчивается монтаж ЭОК-2. Проводится ревизия оборудования БН. Кроме того, проводится модернизация всех систем управления и питания и переход на современную элементную базу. Описывается статус ТНК и ближайшие планы по монтажу и запуску БН. SOFT is developed by Kurchatov Synchrotron Radiation and Nanotechnology Center. en Національний науковий центр «Харківський фізико-технічний інститут» НАН України Вопросы атомной науки и техники Физика и техника ускорителей Status of “ZELENOGRAD” storage ring Статус накопичувача ТНК (м. Зеленоград) Статус накопителя ТНК (г. Зеленоград) Article published earlier |
| spellingShingle | Status of “ZELENOGRAD” storage ring Arbuzov, V. Chernov, K. Chernyakin, A. Churkin, I. Dovzhenko, B. Gorniker, E. Kondakov, A. Kozak, V. Krutikhin, S. Kulipanov, G. Kuper, E. Kuptsov, I. Kurkin, G. Medvedko, A. Ostreiko, G. Petrov, V. Philipchenko, A. Pilan, A. Sedlyarov, I. Serdobintsev, G. Sinyatkin, S. Steshov, A. Tararyshkin, S. Vasichev, S. Veremeenko, V. Ushakov, V. Shvedov, D. Yudin, V. Физика и техника ускорителей |
| title | Status of “ZELENOGRAD” storage ring |
| title_alt | Статус накопичувача ТНК (м. Зеленоград) Статус накопителя ТНК (г. Зеленоград) |
| title_full | Status of “ZELENOGRAD” storage ring |
| title_fullStr | Status of “ZELENOGRAD” storage ring |
| title_full_unstemmed | Status of “ZELENOGRAD” storage ring |
| title_short | Status of “ZELENOGRAD” storage ring |
| title_sort | status of “zelenograd” storage ring |
| topic | Физика и техника ускорителей |
| topic_facet | Физика и техника ускорителей |
| url | https://nasplib.isofts.kiev.ua/handle/123456789/111455 |
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