SOVIET ATOMIC ENERGY VOLUME 18, NUMBER 6

Declassified and Approved For Release 2013/09/24: aIA-RDP10-02196R000700010006-1 ? / Voilime 18, Number 6 'June, 1965- 7." ATOMHAR 3HEPrIIR (ATOMNAYA siNERGIYA) TRANSLATED FROM 'RUSSIAN CONSULTANTS 'BUREAU Declassified and Approved For Release 2013/09/24 : 6IA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 IMPORTANT NEW PHYSICS SERIES FROM CONSULTANTS BUREAU Place your standing order today for books in these series. It will ensure the delivery oi new volumes immediately upon publication; you will be 'billed later. This arrangement is solely for. your convehience and may be cancelled by you cit any lime. , REVIEWS'OF , PLASMA PHYSICS Acad. M. A. Leontovich, Series editor systematic, multi-volume review of the ores= ent status of plasma theory, serving both as an introduction for students and for researthers entering the field, and as a convenient, authori- tative, up-to-date presentation of current knowl- edge for workers ,in plasma physics. This continuing series, ?translated from Russian, is prepared by internationally known Soviet ex- perts. 'Each volunie contains a number of in- tegrated tutorial reviews, covering in depth and in breadth specific aspects of theory. In many cases, new' material is presented. Volunie 1 ? ? A comprehensive, introOuction to '!classical" plasma physics, containing authoritatiVe papers on: 'Motion of Charged ,Particles in Electromag- hetic.Fields in the Drift?Apprqimation, by D. V. Sivukhin; Partiale'interactionS in;a Fully Ionized ,Plasma, by B. A. Trubnikov; Transport Processes in a 'Plasma, by S. I.' Braginskii; and Thermo- dynamics of a Plasm', by A. A. Vedenov. Much ofjthe material in the first tWo papers is pre- sented here for the first time. Although the theoretical analyses are 4uite advanced, the experimental aspects of the subject are kept firmly in 'view throughout. ' 326 pages 1965 $12.50 Volume 4 Contains 'three papers: Hydrodynamic' oescrl,p- tion of a'. Collisionless Plasrna, by .T. F:',Volkov; Cooperative -Phenomena and Shock Waves in Collisionless Plasmas, by R. Z. Sagdeev; and Coulomb Collisions in a -Fully Ionized Plasma. by D. V. Sivukhin. 241 pages , 1966 $12.50 Further Volumes in this series will be.published during 1966. . , 1 LEBEDEV PHYSICS', SERIES Acad. D. V. Skobelisyn, Series editor Complete English translations of the Proceed- ings ("Trudy") of the famed lebedev Physics Institute-of 'the USSR Academy of Sciences pub- lished as Special Research Reports translateq from Russian. N OPTICAL METHODS OF ;INVESTIGATING SOLID BODIES "Trudy" Volume 25 InClbdes a major paper by N.' D. ZhevandroV On polarized luminescence of crystals. The second / , paper, by the: late V. P. CheremisinoV, reports a study of the vibrational spectra and Structure - of oxides; a final paper' by L. A. Vainihtein con: ? cerns the calculation of cross-sections for e*- citation of atoms and ions by electron inipaCt. -194 pages 1965 $22:50 COSMIC RAYS "Trudy" Volume 26, COntainS an' account of the experimental in- vestigations int6 nuclear and electromagnetic interactions at' high and ultra-high energies car- ried out in 'the last few years in the laboratories and -research centers of the Lebedev Physics Institute.. , .254 pages ,1965 $27.50 RESEARCH IN - MOLECULAR SPECTROSCOPY ?''Trudy" Volume 27/ Devoted to spectioscopic invesligation intb , matter in various states of aggregation by the methods of Raman scattering and infrared '? .sorption. A special section is devoted 'to the methodological problem 'of correcting measured quantities fot instrumental errors. ) '206 pages , ' 1965 $22.50 ? Further volumes in this-series will be published approximately 6 months after their appearance in the Original Russian. f T, CONSULTANTS BURE22 AU .?7 '. ?Weet 17.th Street. New York. N, ew York 10011 ?. Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 ATOMNAYA ENERGIYA A EDITORIAL BOARD. I. Alikhanov M. G. Meshcheryakov SOVIET ATOMIC A. A. Bochvar M. D. Millionshchikov I. N. Golovin V. B. Shevchenko ENERGY N. A. Dollezhal' (Editor-in-Chief) V. S. Fursov P. N. Palei V. F. Kalinin D. L. Simonenko N. A. Kolokol'tsov V. I. Smirnov (Assistant Editor) A. P. Vinogradov A translation of ATOMNAYA ENERGIYA, A. K. Krasin N. A. Vlasov A. I. Leipunskii (Assistant Editor) a publication of the Academy of Sciences of the USSR V. V. Matveev ? 1966 CONSULTANTS BUREAU, A DIVISION OF PLENUM PUBLISHING CORPORATION, 227 west 17th Street, New York, N. Y. 10011 Volume 18, Number 6 June, 1.965 CONTENTS Phase Grouping of a Beam of Charged Particles During Capture into Acceleration in the OIYaI Synchrophasotron?G. S. Kazanskii, A. I. Mikhailov, N. B. Rubin, RUSS. PAGE PAGE and A. P. Tsarenkov 709 555 Improvements in The Cern Synchrocyclotron Over the Past Three Years?P. Lapostoll 714 559 Reduction of y-Ray Background from Induced Activity at CERN Proton Synchrotron by Using Low Activity Absorbers?M. Barbier 720 565 Flux of Secondary Neutrons Produced by 660 MeV Protons in Shielding ?V. A. Kon'shin, E. S. Matusevich, S. S. Prokhorov 728 573 The Effect of Delayed Neutrons on the Time of Establishing a Stable Fission Chain ?V. F. Kolesov 734 578 The Shape of the Spectrum of Moderated Neutrons in Absorbing Media?V. N. Avaev. 741 584 A New Method of Reconstructing True Spectra?A. N. Tikhonov, V. Ya. Arsenin, A. N. Dumova, L. V. Mayorov and V. I. Mostovoi 747 588 Measurement of Neutron Spectra in Nickel, Iron, and Stainless Steel?I. I. Bondarenko, V. G. Liforov, V. N. Morozov, M. N. Nikolaev, V. A. Parfenov, and V. A. Semenov 752 593 Self-Diffusion in the a and 13 Phases of Uranium?A. A. Bochvar, V. G. Kuznetsova, V. S. Sergeev, and F. P. Butra 761 601 Study of the Mechanical Properties of Beryllium?N. N. Davidenkov, B. A. Sidorov, L. M. Shestopalov, N. F. Mironov, N. M. Bogograd, L. A. Izhvanov and S. B. Kostogarov. 768 608 Thermographic Investigation of UO2, UC1, and KCI Ternary and Binary Systems ?N. S. Martynova, I. V. Vasil'kova, M. P. Susarev 777 616 Removal of Radioactive Isotopes from Sewage?F. V. Rauzen and Z. Ya. Solov'eva 784 623 NOTES ON ARTICLES SUBMITTED Waveguide Accelerator-Buncher Intended to Produce a Monokinetic Electron Beam ?G. I. Zhileiko and V. A. Snedkov 789 627 Maximum Efficiency and Limiting Current of an Electron Beam in a Heavy-Current Waveguide Accelerator?G. I. Zhileiko 790 628 Dose Rate from a Unidirectional Source of Gamma Quanta Close to the Ground-Air Interface.?Yu. I. Bublik, S. M. Ermakov, B. A. Efimenko, V. G. Zolotukhin and t. E. Petrov. 791 629 Ages of Neutrons from Mono-Energetic and Multi-Energetic Sources in a Uniform Moderator ?D. A. Kozhevnikov 793 630 Annual Subscription: $95 Single Issue: $30 Single Article: $15 All rights reserved. No article contained herein may be reproduced for any purpose whatsoever without permission of the publisher. Permission may be obtained from Consultants Bureau, A Division of Plenum Publishing Corporation, 227 West 17th Street, New York, N. Y. 10011, U.S.A. Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 CONTENTS (continued) RUSS. PAGE PAGE HealTranSfer and Temperature Fields in Bundles of Rod-Shaped Heat-Emitting Elements, Parallel to the Laminar Flow of a Liquid in which They Are Immersed ?M. Kh. Ibragirnov and A. V. Zhukov 794 630 The Role of Diffusion in the Migration of Radioactive Contaminants?V. M. Prokhorov 796. 631 LETTERS TO THE EDITOR A 10 MeV WavegUide Synchrotron?A, A. Vorob'eV, A. N. Didenko, A. I. Lisitsyn, B. N. MorOz0v, Yu. I. POtekhin, L. G. Salivon, and R. M. Vilatova 797 633 'Passage Through the Critical Energy in an Automatically Controlled Accelerator ?g, A. Zhil'Icov -799 634 Particle 1.,o8Ses Due to Passage Through Nonlinear Resonances in Accelerators and Storage Devie es ?A A. K olornenskii 803 636 Effective Method of Solving the Two-Dimensional Diffusion Equation for Square and Hexagonal Cells?G. I. Marchuk and V. P. Kochergin 806 638 Critical Thermal Load in Bunches With Spacer Grids?A. S. Korekov and Yu. D. Barulin 810 640 Thermoelectric Properties of Polycrystalline Uranium?A, A. Tsvetaev, YU. N. Golovanov, R. K. Chuzhko, and I. V. KirillOv ? ? 813 642 Effect of Crystallization Rate and Annealing on the Plastic Properties of High-Boron Steel R. V. Grebennikbv and A. V. Chirkin 816 .644 Precipitation Conditions for Uranyl Ammonium Arsenate and Some of its Properties ?M. A. Korenev, B. V. Nevtkii, Z. P. Zorina, Ts. L. Ambartsurnyari, and N. G. Nazarenko. 819 647 Some Possible Methods for Preparing Radioactive Isotopes?N.13, Rudenko, and A, M. Sevaseyanov 822 649 Optimum Specific y-Activity of a Quasi-Homogeneous Radiation Chemical Plant ?V. A. gletekOV 825 650 N-I-P Germanium Detector Features High Resolution for Low-Energy arid Mediurn-Energy Gammas ?L. V. MasloVa, 0. A. Matveev, S. M. Ryvkin, I. A. Sondaevskaya, N. B. Strokan 829 654 Radiation Hazard in Irradiated Metal Specirhens?M, M. Krasnoshchekov 832 656 Tracer Elements Aid in Evaluating Radioactive Anomalies in Arid Regions?V. M. Konstaritinov. . 834 657 Contamination Of Flora by Radioactive Fallout?O. G. MironoV . . 837 659 SCIENCE AND ENGINEERING NEWS Nuclear Electric Power Stations in itaiy?v:v. S trekol 'nikoV , A.N. Grigoryants, Pancheriko. 840 662 A Trip to England?O. G. Kazathkovskii 844 664 Standardization of Nucleonic Instrumentation?I. AuZout 847 666 Participation of the USSR in the CEI TeChnical'Comnaittee 45,?N, M. kitaeV and V. V. Matveev. 851 669 The Russian press date (podpisano k pechati) of this issue was 6/14/1965. Publication therefore did not occur prior to this date, but must be assutned to have taken place reasonably soon thereafter. Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 PHASE GROUPING OF A BEAM OF CHARGED PARTICLES DURING CAPTURE INTO ACCELERATION IN THE OIYaI SYNCHROPHASOTRON* (UDC 621.384.611) G. S. Ka.zanskii, A. I. Mikhailov, N. B. Rubin, and A. P. Tsarenkov Translated from Atomnaya tnergiya, Vol. 18, No. 6, pp. 555-559, June, 1965 Original article submitted June 24, 1964 The authors give a method for improving capture by means of preliminary imposition of a high-frequency ac- celerating field. The frequency of this field is varied according to the law of orbital deflection in "quasi-betatron" conditions. The accuracy and possible errors in the establishment of these conditions are estimated, and experi- mental results given. It is known that a beam of particles injected into the chamber of a synchrophasotron has a certain angular and energy scatter.t This leads to the formation of a fairly complex structure in the proton beam in "quasi-betatron" conditions, causing some difficulty in effecting capture of the particles into synchrophasotron acceleration. It is known that 17% of the injected beam is captured from quasi-betatron into synchrophasotron conditions. This capture efficiency is determined [1] mainly by two factors: 1) particles with large amplitudes of radial betatron oscillation are unavoidably lost during capture and forma- tion of a beam of accelerated particles in synchrophasotron conditions; 2) in synchrophasotron conditions, the particles are captured from part of the annular bunch, limited by the phase dimensions of the region of stability. For the OIYaI synchrophasotron, the latter extends about 2000 . In this paper we discuss a method for improving the efficiency of capture into synchrophasotron conditions by grouping the particles in the azimuthal direction [2]. This grouping is effected by bunching together that fraction of the particles which, in normal conditions, find themselves outside the stability region. If we create a stability region of which the phase width is 3600, and then displace it inwards along the radius and draw this region together to normal azimuthal dimensions, we can, in certain conditions, improve the efficiency of capture into synchrophasotron con- ditions. As far as we know, a similar program was studied for the Bevatron (USA).* Let us investigate the practicability of realizing this program. The equilibrium motion of the particles in ac- celerators of the "race-track" type is given by the following equations [3]: dEs nV 21( OF ecp COS (s dt 11, Ils?c at ' dEs Es ( w Bo ; 1_ dt Ks \, o s =-- asll s Esp2 zs = 0, no * OIYaI = United Institute of Nuclear Research. t For the OIYaI synchrophasotron, the energy scatter A W/W = 0.5%; the angular scatter a = ?5'. * The calculations of the Bevatron group were not made available to the present authors. Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 (1) 709 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Fig. 1. Law of variation of frequency of accelerating potential in phase- grouping regime. Fig. 2. Law of variation of frequency of accelerating potential during initial part of accelerating cycle with phase-grouping. AB) Law of frequency variation for phase- grouping conditions; BC) law of frequency variation for synchrophasotron conditions. where Es = equilibrium energy, Bo = magnetic induction for z = 0 and some fixed radius in the electromagnet sectors, Vo = amplitude of accelerating potential, cps = equilibrium phase, Fs = flux through area of orbit, c = velocity of light; K s = 1 + ast1 = 4L (where n = index of fall in magnetic field, I = 1 + ), rs IIs = 271-rs + 4L = perimeter of equilibrium orbit (where rs = equilibrium radius, L = length of straight-line section); = frequency of accelerating field. We require that during capture the equilibrium energy shall not vary, i.e., we shall assume that Es = o. We shall neglect the effect of the vortical electric field 3Fs/at. From these conditions it follows that cos cos = 0 and r, since iti the con- trary ease it can be cansidere&Sirnply aS a 6 -function, and it can be assumed that ui z(ti). Processing of the two experimental spectra, cor- responding to one and the Same true spectrum, meas- ured by means of selectors having different resolving powers. The neutron pulses were recorded by an anal- yzer with a channel width of r 6 bisec. The first experimental ("apparatus") spectrum is obtained on a selector with quite good resolution a = al = = 4 1.1sec (s = 0.1 cm; R = 6.76 cm: co = 0.104 ? 10-2). Since in this case 0< r , the "true" spectrum z(1)(t) should differ slightly from the measured spectrum. The function ui(1) is plotted in Fig. 1 as the Solid line. The second experimental spectrum ui(2) is obtained on a selector with a worse resolution a = 02 = 17 psec (s = 0.1 cm; R = 6.76 cm; co = 0.224 ? 10-3 psec). The function ui(2) is plotted in Fig. 1 by the dash-dot line and, obviously it is a smoother curve than ui(l). In order to verify the validity of the assumptions about the kernel of the integral equation and the accuracy of the experimental data about the spectrum 14(2), the integrals 2 3 4 5 5 6 9 Ratio of neutron energy to temp. of medium Fig. 4. Directional ( ) and scalar C-----) neutron fluxes in a uranium-water lattice: (P?ti)2 2cq u(I) (1,) dl' ? pr2.77J1 0) were evaluated. If ui(1), in fact, can be assumed to be the true spectrum, then the function ui(3) should coincide with the meas- ured spectrum ui(2) . The function ui(3) is plotted as a dotted curve in Fig. 1. It is very close to the experimental spectrum ui(2), which indicates the validity of the specification of the kernal, but somewhat smoother than ui(2). The discrepancy, which is observed particularly clearly for channels with numbers i30-35, can be explained by the measurement errors. Consequently, it is not Very hopeful that by solving the integral Eq. (2) the true spectrum ui(1) will be successfully and accurately reconstructed by the spectrum ui(2) in the vicinity of In order to demonstrate the feasibility of the method of regularization of the solution of the integral Eq. (2), the spectrum ui(1) was reconstructed by the simulated spectrum uf(3). The results ate shown in Fig. 2. The fine structure of the spectrum is reconstructed quite well for i."-40 and somewhat less well for i30. The latter is ex- plained by the fact that the number of points (i.e., the number of analyzer channels), by which the experimental spectrum is defined, is inadequate for describing it accurately, and consequently, the errors of integration with re- spect to a small number of points give an excessively smooth curve in this region. On the basis of calculations carried out, it can be concluded that the fine structure of the spectrum can be de- termined not only by means of more detailed experiments but also by means of a more complete mathematical pro- cessing of the measurement results. In this case, bearing in mind the subsequent mathematical processing, it is nec- essary to improve some or other parameters of the instrument by the appropriate method, by selecting the optimum relationships between them (in the given case these parameters are the speed of rotation of the rotor, the analyzer channel width and the magnitude of the statistical errors). 750 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Calculation of the Scalar Energy Flux in a Moderator by the Measured Directional Flux In measurements of the energy spectrum of thermal neutrons in a reactor lattice the neutron beam, as a rule, is extracted from a certain point of the lattice, parallel to the axis of the block. Thus, the energy spectrum of the directional neutron flux is measured, which may be significantly different from the energy spectrum of the scalar neutron flux and which, in practice, is the most interesting. For a one-dimensional lattice with isotropic neutron scattering, the scalar energy flux cl)(E, r) at the point r is related with the energy spectrum of neutrons in the direction of the lattice axis 4.11 (E, r) by the relationship E JIM s (E) Ea (E)] (RI (E, r) s (E, E', r) CD (E', r) dE' S (E, r) (9) (all the symbols here are universal). If the directional flux 43.11 (E, r) at the point and the characteristics of the medium Ea (E), Es(E, E'), S(E, r), are known, the scalar flux at the same point can be determined by solving Eq. (1). The method described above enables a stable solution of this equation to be found. The determination of the scalar flux in uranium-water lattices are of particular interest. In [4], the directional flux was determined for these lattices by calculating the scalar flux and it was compared with the measured flux. It was shown in this paper that the calculated spectra are slightly sensitive to scattering anisotropy in water. Thus, in order to find the scalar flux in water by the measured directional flux, Eq. (9) can be used. We shall consider by way of example, a uranium-water lattice for which the energy spectra of the directional flux were measured in [2] at different points of the cell. The differential scattering cross section of neutrons in water was calculated by the UPRAS (Universal Program for Calculation of Cross sections) program on the assumption that water is described by a crystal model having an acoustic spectrum which is determined experimentally [6], and an optical spectrum with frequencies w1 = 0.2 eV and co2 = 0.4 eV. The calculated inelastic scattering cross sections agree well with the experimental data. The thermal neutron sources were assumed to be isotropic and they were calculated on the assumption that for an energy E > 0.25 eV the epithermal neutron spectrum has a Fermi form CE' and is independent of the angle. The quantity C was defined as the limit of the experimental directional flux, multiplied by E [C = E (E)] at high energies. Figure 4 shows the graph of the measured directional and calculated scalar neutron fluxes in water at the boundary with the block. In conclusion, it should be noted that as a result of reconstructing the true spectrum the errors, which distorted the shape of the experimental curve, are increased generally speaking. The problem concerning the optimum choice of the parameter a is associated with how much the measurement data, containing errors, permits the true spectrum to be reconstructed. With too small a value of a, the errors in the reconstructed spectrum become so large that they lead to buildup of the solution obtained. Paper [7] is devoted to the estimation of the errors in the reconstructed spectrum. In addition, a special paper will be devoted to this. LITERATURE CITED 1. A. N. Tikhonov, Dokl. AN SSSR, 149, 529 (1963). 2. V. L Mostovoi et al., Atomnaya Energiya, 13, 547 (1962). 3. V. I. Mostovoi, M. I. Pevzner, and A. I. Tsitivich, In the book: Data of the International Conference on the Peaceful Uses of Atomic Energy, Geneva, 1955, [in Russian], Moscow,Izd-vo AN SSSR (1957), p. 19. 4. H. Honeck and H. Tacahashi, Nucl. Sci. Engng, 15, 115 (1963). 5. L. V. Mayorov, V. F. Turchin, and M. S. Yudkevich, Report No. 360, presented by USSR at the Third Inter- national Conference on the Peaceful Uses of Atomic Energy [in Russian], Geneva (1964). 6. P. Egelstaff et al., Proc. Simp. Chalk-River, Vol. 1 (1962), p. 343. 7. A. N. Tikhonov and V. B. Glasko, Zh. vychislitel'noi i matematicheskoi fiziki, 4, 564 (1964). 751 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 MEASUREMENT OF NEUTRON SPECTRA IN NICKEL, IRON, AND STAINLESS STEEL (UPC 621,039,538/539,125.52) I. I. Bondarenko, V. , Liforov, V. N. Morozov, M, N. Nikolaev, V. A. Parfenov, and V. A. Semenov Translated from Atoninaya tnergiya, Vol, 18, No. 6, pp. 593601, June, 1965' Original article submitted July 13, 1964 Measurements of neutron spectra in various media, obtained by the transit-time method in the fast pulse reactor IBR with a resolution of 0.04 Asec/m, are presented. The spectra of neutrons emerging from iron and nickel prisms of various thickness and also those from stainless-steel prisms are studied. The "fine structure" due to the resonance character of the cross sections of the media studied was clearly seen in the spectra measured. The experimental neutron spectra are compared with calcu- lations made with n multigroup system of constants allowing for resonance self-screening of the cross sections. The reasons fpr the slight discrepancies found are analyzed. The most widespread methods of measuring space-energy distributions of fast and intermediate neutrons in various media are those based on measuring the spatial dependence of the rates of reactions possessing different energy/cross section relationships [1-5]. Conclusions based on the results of such measurements are not always un- equivocal, since at certain points of the set studied it is often necessary to determine the energy spectrum of the neutrons with more precise (and complex) direct methods of neutron spectroscopy, by means of photoemulsion [1, 2], the Wilson chamber [1], He3 chambers and counters [2, 3], or in some cases by means of resonance detectors [3-5]. All these methods, however, lack the resolving power needed to reveal the "fine structure" of the neutron spectrum, associated with the resonance nature of the cross section, explicitly in the experimental results. At the same time, a study of just this structure is extremely important for checking and developing ideas on the propaga- tion of neutrons in media containing neutron-resonance scatterers and absorbers. I. I. Bondarenko first snowed the necessity of considering the resonance structure of cross sections when calculating fast reactors in 1957. Since then a great deal of work has been done on developing metnods of allowing for the resonance structure of cross sections in reactor calculations [6-12], studying the influence of resonance effects in macroscopic experiments [13, 14], and developing methods for determining the mean cross-section characteristics needed to allow for resonance effects in reactor calculations [12, 15]. In all these papers, however, the influence of the resonance structure of the cross sec- tions on the propagation of neutrons in matter was considered only from the point of view of determining integral characteristics. Detailed neutron spectra in the resonance region were not examined. At the present time, the only experimental method making it possible to measure neutron spectra with a high resolving power is the transit-time method. Use of this method for studying the spectrum of fast neutrons retarded in matter is complicated by the fact that the minimum pulse length is determined by the statistical indeterminacy of the slowing -down time, which for nuclei with mass number ?50 is ?15 ?sec. Thus, for such investigations we need a pulse source of high intensity, making it possible to increase the resolution on account of the greater transit-time base. Owing to the absence of such a source, it appeared, until recently, impossible to use the transit-time method for studying fast-neutron spectra. Such a possibility re-emerged with the arrival of the fast pulse reactor IBR [16]. The pulse length of the IBR reactor, equal to ?36 ?sec, is great enough for the slowing down of the neutrons in a heayy moderator not to lead to serious prolongation of the pulse. At the same time, the high intensity of the pulse makes it possible to use an 752 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 4\ 3 I 111 Ilk?r?=-; --it _ 'L ? E? 1 !002m 750 m Cl' Fig. 1. General arrangement of the experiment: 1) scintillation detector; 2) collimator; 3) boron-counter detector; 4) monitor on 50-m base; 5) prism of material studied; 6) active zone of IBR reactor; 7) monitor on 100-m base. Fig. 2. General view of the disposition of the prism in the reactor room: 1) active zone of IBR reactor; 2) prism of material being studied; 3) platform for moving prism; 4) motor for moving platform; 5) neu- tron guide; 6) slide; A) position of prism "at the zone;" B) position of prism "at the wall." extremely large transit-time base (1 km) and thus, ensure a high resolving power of the system. It was, therefore, decided to make a cycle of experiments to study the spectra of neutrons emerging from blocks of nickel, iron, and stainless steel. The choice of materials was based on the following considerations. As we know, the resonance structure of the nuclei of nickel and iron appears right up to energies of the order of several MeV [4], and in the region of several keV it is extremely strong [6]. A characteristic feature of the resonances in the keV range of energies is the presence of deep interference minima, which exert a very great in- fluence of the diffusion and slowing-down of the neutrons [10]. The effect of interference between resonance and potential scattering arises most strongly in the distribution of neutrons in media containing even-even nuclei (iron, nickel), especially in those cases where one isotope predominates in the natural mixture (iron). Study of the slowing-down spectrum of neutrons in stainless steel is interesting from the point of view of check- ing the accuracy of existing methods of describing the propagation of neutrons in a mixture of resonance scatterers [6]. In the choice of materials for study, of course, the important fact that iron, nickel, and stainless steel are widely used in reactor construction was borne in mind. 753 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 cP(f) 10 10 ba" 10 IP tigs E, eV Fig. 9, Spectrnm of leakage neutrons from nickel (curves 1, 2, 3, correspond to prism thicknesses of 31, 52, 77 cm). The spectra of neutrons emergpg from nickel prisms 306, 515, and 770 mm thick, iron prisms 300, 480 mm thick, and stainless7steel prisms 300 and 499 cm thick were measured. The transverse dimensions of the nickel prisms were 800?. 1, it is possible to achieve stability of the bunch purely on account of the automatic control system with respect to the center I ax , 13n1 both before and after the transition. The stability of the bunch can be increased by introducing feedback via the dimensions. For other distributions, when there is natural damping, it is necessary to analyze the parameter [5, 6] before and after the critical energy is reached, as done, for example, in [6]. Owing to the non-linearity of the equations, the bunch's center does not coincide with the equilibrium phase, but is displaced relative to it by an amount equal to the equilibrium dimensions of the bunch [5]. The center of the bunch must be displaced. The results obtained are valid for bunches of small dimensions in the linear approximation. To solve the non-linear problem, special discussion is required. The author wishes to thank A. N. Lebedev for guidance, and A. A. Kolomenskii and g . L. Burshtein for dis- cussing the results. LITERATURE CITED 1. K. Johnsen and C. Schmelzer, Proc. of Int. Conf. on High Energy Accel. CERN (1956), p. 395. 2. W. Schnell, Proc. of Int. Conf. on High Energy Accel. CERN (1959), p. 485. 3. Yu. S. Ivanov and A. A. Kuz'min, Pribory i tekhnika eksperimenta, 4, 106 (1962). 4. H. Hereward, Proc. of Int. Conf. on High Energy Accel. Brookhaven (1961), p.236. 5. L. A. Zhil'kov and A. N. Lebedev, Atomnaya gnergiya, 18, 22 (1965). 6. g. A. Zhil'kov, Pribory i tekhnika eksperimenta, 1, 17 (1965). 7. A. A. Kolomenskii and A. N. Lebedev, Theory of Cyclic Accelerators [in Russian], Ch. IV, Moscow, Fizmatgiz (1962). 8. g. A. Zhil'kov, Atomnaya gnergiya, 18, 58 (1965). 802 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 PARTICLE LOSSES DUE TO PASSAGE THROUGH NONLINEAR RESONANCES IN ACCELERATORS AND STORAGE DEVICES (UDC 621.384.61) A. A. Kolomenskii Translated from Atomnaya Energiya, Vol. 18, No. 6, PP- 636-638, June, 1965 Original article submitted July 3, 1964 Reports have recently appeared concerning projects for large proton storage systems, designed to effect colli- sions between intersecting beams [1, 2]. Our aim in this paper is to analyze one of the possible mechanisms of par- ticle losses which must be allowed for in developing and applying systems of this type. A characteristic property of cyclic accelerators and storage rings is the existence of dangerous resonance com- binations of the parameters, determined by the relations q'2 == in ((h., z, in are integers), (1) where v r, v z = frequencies of radial and vertical betatron vibrations (expressed in terms of the frequency of revolu- tion w). The resonance order k is determined by k = lq11 + lqz1. The permissible limits follow from the require- ments that the working point v r, vz on the stability diagram shall not come close to the edges of the cell deter- mined by the linear resonance bands (k :s 2). This cell is crossed by bands of non-linear resonance (k > 2), caused by disturbances in the magnetic field. The effects of these resonances are usually not very dangerous, because when the working point is stationary they are compensated for by non-linear displacement of the vibration frequency. However, if the working point, though remaining within the cell, wanders and passes through non-linear resonance bands owing to instabilities of the magnetic field, the amplitude of betatron vibrations may rise to dangerous values, leading to loss of particles. There is especial danger that such losses may arise from repeated passage through non- linear resonances when these occur in storage rings, in which the particles have to circulate for very long times of an hour or more, several orders greater than those usually found in accelerators. We shall confine ourselves to systems with strong focusing, having proton storage rings in mind. For electrons, an important part is played by relativistic electromagnetic radiation, which (with suitable choice of focusing system) damps the vibrations and limits the effects of various disturbing factors. For protons, this radiation is practically nonexistent, and there is no damping of the vibrations, so that in storage rings the particle energy and magnetic field remain practically constant. If a nonlinear resonance is crossed slowly enough, there may be "coupling hysteresis" of the fraction of particles in the resonance, accompanied by marked increase in the amplitude, even for a single non-repeated passage [3]. However, it is estimated that in practice passage is comparatively rapid. There is, thus, no coupling hysteresis, and increases in amplitude will arise in those short periods during which there is synchronism between particle vibrations and harmonic disturbances of the magnetic field. The increases in amplitude due to rapid passage through non-linear resonances can be calculated from known formulae (see [3], ch. III, /8). az It is characterized by the coefficient J = 2 , where ai, a are the amplitudes of vibration before and after trans- mission, respectively. Using the method of stationary phases, we obtain for J the expression 2 J = [1 ? (? ? 1) G 25.1 sin (kivo 2 16'1 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 (2) 803 Declassified and Approved For Release 2013/09/24: CIA-RDP10-02196R000700010006-1 Here k = order of resonance (k > 2); coo = phase at moment of transmission; G (uq, a, a) I k 2pai 2 2R where = averaged coefficients expressed in terms of floquet function f and proportional to the q-th (resonance) harmonic of the disturbance (see Table 3 in [3]); p = momentum of particle; and R = radius of orbit. d6 The expression 6' = ?0- occurring in (2) determines the rate of change of detuning, 6 = v - the azimuthal angle, .9- . This can be expressed as follows: Q AB 6 v ct B (3) , in terms of (4) where ,A B, SZ = amplitude and frequency of disturbing oscillations in the magnetic field, the value of which at the orbit is denoted by B. Using (4) we can easily estimate the rate of passage through a resonance and assure ourselves that, in most practical cases, we can ignore "coupling hysteresis" in the resonance and consider the passage to be rapid, satisfying (8.5) of [3] (ch. III, E8). To simplify the calculation, we shall restrict ourselves to a cubic resonance, k = 3, V = q/3. By (2),(3) and the above-mentioned table in [3], we have J [ ? 163,1 16,211111 11/.3- ?2 rb 21 I sin (300 1-2 4)] (5) where bq is the q-th harmonic of azimuthal asymmetry of the field. For the non-linearity characteristic of an ideal field we can introduce the value Bh B - 1)h ok (6) which is a generalization of the ordinary field index ri = no. In strong-focusing machines, nk usually obeys 1 < I vol< ni I .