Declassified and Approved For Release 2013/09/25 : CIA-RDP10-02196R000600070001-1 Volume 11, No. 3 THE SOVIET JOURNAL OF March, 1962 03111IC ENERGY ATOMI1a51 1-leprli.51 \ TRANSLATED F!2aM RUSSIAN - CONSULTANTS BUREAU Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25 : CIA-RDP10-02196R000600070001-1 THE LATEST SOVIET RESEARCH IN TRANSLATION LIQUID-METAL HEAT TRANSFER MEDIA by S: S. Kutafeladze, V. M. Borishanskii, I. I. Pioiikov and 0. S. Fedynskii This informative Volume is devoted to the problems of utilizing liquid-metal heat transfer media in nuclear power. Data on the study of heat removal by liquid metals, obtained during ,the past ten years in the USSR as well as abroad, in connection with problems of nuclear po-wer are both systematized and generalized in this work. The book will be of considerable assistance to scientific workers and engineers in the field of reactor design and nuclear power and in other fields of technology where liquid-metal coolants can be utilized. cloth 150 pp. illus. $22.50 CORROSION OF CHEMICAL APPARATUS by G. L. Shvartz and M. M. Krisfal . . . the book is concerned with stress corrosion cracking and intercrystalline corro- sion, especially in connection with process equipment . . a judicious mixture of facts, prac- tice, and theory . . . It contains a good deal of Shva.rtz's own 'work, and, indeed, is useful for the many, pertinent Soviet references . . . collects in one place much of the current Soviet thinking in this field. .. the chapter on methods of testing and the' one on methods of retard- ation are particularly effective . . . Not only do they contain more detail than is usually found in such books, but they are clear and concise, and should prove useful to the practicing corro- sion engineer . . . " ?Cheinical & Engineering News cloth 250 pp. $7.50 ,DENDR1TIC CRYSTALLIZATION , . by D. D. Saratovkin , ' "Translated from Russian, this 2nd edition has been revised to include fresh material derived from observations under the stereoscopic microscope. The bulk of this volume con- tains many original and Unpublished ideas and observations, and is an example of the mod- ern microscopic approach 'to the crystalline state by an experienced worker concerned .with the Infinite variety of real crystals. Line diagrams and sets of stereoscopic photograph ? are included." ?Journal of Metals cloth 126 pp. illus. $6.00 CONSULTANTS BUREAU 227 West17.1.11 Street, NON York 11; N.Y. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 ? Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 EDITORIAL BOARD OF ATOMNAYA ENERGIYA A. I. Alikhanov A. A. Bozhvar N. A. Dollezhal D. V. Efremov V. S. Emel'yanov V. S. Fursov V. F. Kalinin A. K. Krasin A. V. Lebedinekii A. I. Leipunekii I. I. Novikov (Editor-in-CM/) B. V. Semenov V. I. Vekeler A. P. Vinogradov N. A. Vlaeov (Assistant Editor) A. P. Zetirov THE SOVIET JOURNAL Of ATOMIC ENERGY A translation of ATOMNAYA ENERGIYA, a publication of the Academy of Sciences of the USSR (Russian original dated September, 1961)., Vol. 11, No. 3 March, 1962 CONTENTS Acceleration of Hes up to 35 Mev in the One and One-Half Meter Cyclotron. N. I. Venikov, G. N. Golovanov, V. P. Konyaev, N. V. Starostin, and N. I. Chumakov Silicon Counters for Nuclear Spectrometry. S. M. Ryv kin , L. V. M as lov , 0. A. Matveev, N. B. Strokan, and D. V. Tarkhin Two-Dimensional Boundary Problem for Two-Dimensional Square Lattices. L. Trl if a Diffusivity of Sodium and Lithium. I. I. Rudnev , V. S. Lyashenko. and M. D. Abramovich Vasilii Savvich Lyashenko Preparation of Highly Pure Beryllium by the Chloride Method. I. E. Vii 'komirs kii , G. F. Silina, A. S. Berengard, and V. N. Semakin The Separation Factor of Lithium Isotopes during Vacuum Distillation. S. G. Katal'nikov and B. M. Andreev ? ? ? f LETTERS TO THE EDITOR The Angular and Energy Dispersion of "-Mesons in the Scatterd Magnetic Field of a Six-Meter Synchrocyclotron.V. G. Kirillov, -Ugryumov, A. A. Kropin, V. S. Roganov, and A. V. Samoilov Improving the Monochromaticity of an Ion Beam in a Cyclotron. N. I. V en ikov and N. I. Chumakov The Angular Anisotropy of Fission of Even-Even Nuclei. V. G. N es t e rov G. N. Smirenkin, and I. I. Bondarenko The Possibility of the Practical Use of Isomers. Yu. V. Petrov The Space Distribution of Fast Fission Neutrons in Iron. V. P. Mash kov ich and S. G. Tsypin The Problem of Thermal Contact Resistance during Heat Transfer to Liquid Metals. 0. P. Astakhov, V. I. Petrov, and 0. S. Fedynskii The Thermodynamics of the Reduction of Uranium Tetrafluoride by Calcium. N. P. Galkin, U. D. Veryatin, and Yu. V. Smirnov NEWS OF SCIENCE AND TECHNOLOGY Tenth Session of the Learned Council of the Joint Institute for Nuclear Research. V. Biryukov International Conference on Theoretical Aspects of Phenomena Occurring at Very High Energies. V. S. Barashenkov RUSS. PAGE PAGE 857 213 861 217 865 221 877 230 881 232 882 233 889 240 894 245 898 247 901 248 903 250 905 251 910 255 914 257 918 261 919 262 Annual subscription $ 75.00 1962 Consultants bureau Enterprises. Inc., 227 West 17th St., New York 11,N. Y. Single issue 20.00 Note: The sale of photostatic copies of any portion of this copyright translation is expressly Single article 12.50 prohibited by the copyright owners. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 CONTENTS (continued) RUSS. PAGE PAGE Use of Tritium in Physical and Biological Research. Ya. M. Vars ha vskii and A. A. Ogloblin Seminar on the Use of Isotopes and Nuclear Radiations in Blast-Furnace Production. P. L. Gruzin [Trends in the Design of British Nuclear Power Stations 922 927 264 268 Source: Nucl. Engng. 6, 100 (1961) No. 58 269] [The Role of the AGR in British Power Program Source: Nucl. Engng. 6, No. 59, 151 (1961) 270] [First News on Operation of the Yankee Power Station Source: Nucleonics, March, 1961 271] [Nuclear Power Costs Source: Nucl. Engng., 6, No. 60, 216 (1961) 273] [In-Pile Testing of Nuclear Direct Conversion Device Source: R. Howard et al. ARS Space Power Systems Conf., Sept., 1960 275] [Metals Compatability in Gas-Cooled Reactors Source: Nucl. Engng., 6, No. 60, 217 (1961) 277] [On the Use of Carbon Steel in the NPR Reactor Source: Nucleonics, March, 1961 277] [A New Radiometric Separator for Enriching Uranium Ores, and Its Application Sources: Mine and Quarry Engng., 25, No. 1, 46(1959); Engng. and Mining J., 160, No. 2, 158 (1959); S. Afric. Mining J., 72, No. 3551, 409 (1961) 279] [A New Concept in Manipulators Source: Nucl. Engng. 6, No. 59, 173 (1961) 282] BIBLIOGRAPHY New Literature 933 287 Engineering and Physics Journal Inzhenerno-Fizicheskii Zhumal 943 294 NOTE The Table of Contents lists all materials that appear in Atomnaya gnergiya. Those items that originated in the English language are not included in the translation and are shown enclosed in brackets. Whenever possible, the English-language source containing the omitted reports will be given. Consultants Bureau Enterprises, Inc. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 ACCELERATION OF He3 UP TO 35 Mev IN ,THE ONE AND ONE-HALF METER CYCLOTRON N. I. Venikov, G. N. Golovanov, V. P. Konyaev, N. V. Starostin, and N. I. Chumakov Translated from Atomnaya Energiya, Vol. 11, No. 3, pp. 213-216, September, 1961 Original article submitted January 30, 1961 A method is described for accelerating Her to 35 Mev ma cyclotron. A beam of 301a with an energy spread of ?0.3% was obtained on a target 12 m from the cyclotron. Due to the use of a gas recycling system, the loss of He3 was decreased by two orders and was approximately 5 cm3/hr. Lately there has been great interest in the utilization of accelerated He3 nuclei as bombarding particles. There have been reports concerning He3 acceleration in the Los Alamos [1] and Birmingham [2] cyclotrons. Until the present, there have been no attempts to accelerate He3 in Russian cyclotrons. In usual cyclotron operation, where the amount of running gas pumped out of the vacuum chamber and exhausted to the atmosphere reaches 0.5 liter/hr, the expendi- ture of He3 is very great. In order to use the available supply of gas repeatedly, a special gas recycling system was developed by the authors and used on the cyclotron of the I. V. Kurachatov Order of Lenin Institute of Atomic Energy. The Gas .Recycling System A diagram of the gas recycling system is given in Fig. 1. Gas is pumped from the cylinder by a special mercury pressure regulator of the automatic-acting pump-type into the system to a pressure of 100-200 mm of Hg. Then the cylinder is cut off and the gas is bled through a needle valve into the ion-source discharge chamber. Gas flow to the cyclotron could be adjusted remotely from a control panel by a servomotor system. Diffusion pump Vacuum gauge no. 1 Needle valve Vacuum gauge number 2 Forevacuum pump Oil vapor trap Fig. 1. Diagram of the recycling system. Charcoal traps Mercury vapor trap Mercury pressure regulator 857 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 On entering the cyclotron vacuum chamber, a small amount of the gas will be lost through nuclear reactions and sorption on the chamber material. However, the main part of the gas is pumped out along with other gases by the two diffusion pumps followed by mechanical forevacuum pumps. The pumped gas-vapor mixture proceeds through a system of traps, is compressed to the required pressure and returned to the system with the pure He3. One trap, which is chilled by liquid nitrogen, freezes out easily condensed substances (oil, water, and outgasing products). The second trap, which is designed for the absorption of nitrogen and oxygen, is filled with activated char- coal and also chilled with liquid nitrogen. There is also a trap for mercury vapor from the pressure regulator. The charcoal trap's absorption capacity is 10-15 liter of air at normal pressure, consequently the service period of such a trap with the usual vacuum system* leak rate, approximately 0.1 cm3/ min, is several days. When a pressure increase in the system warns of a decrease in the charcoal's absorption capability, it is possible to switch to a previously readied second charcoal trap of the same type. Preparation of the pump for service is accomplished by heating it to 200?C for several hours in a special electric furnace while simultaneously pumping on it, with forevacuum pumps. There is a reserve mechanical pump in the system also. In order to reduce He3 losses on dismantling the system and with certain other operations (such as switching from one pump to another), the dimensions of the separate parts of the system have been reduced to a minimum. The chief harmful volume (the exhaust chamber of the mechanical pump) was significantly diminished by a fiberglas ballast in the pump's exhaust chamber. An additional careful packing of the mechanical pumps was carried out and a special water-cooled oil baffle was introduced to decrease the oil entering the system with the He3 from the mechanical pump. The mercury regulator supplied gas from the cylinder to make up the losses. The average loss of He3 during the experiment was about 5 cm3 /hr at atmospheric pressure. 5 030 ? 40 50 60 70 R, cat Fig. 2. Ion current dependence on the acceler- ation radius. Acceleration of He3 The maximum possible energy of the accelerated He3 ions in the cyclotron was determined by the highest resonance fre- quency attainable, 11.2 Mc. This frequency corresponds to a mag- netic field intensity H = 11,000 oe. The ultimate energy of the twice ionized He3 ions in this case is about 35 Mev at the 67 cm radius. 00 I 50 u,kv100 Fig. 3. Target ion current de- pendence on the deflecting sys- The magnetic field was shimmed to secure adequate ver- tern potential. tical ion focusing and so that the potential difference between the dees was 160 kv (i.e., it was lower than the breakdown voltage). A pulsed ion source supply was employed which increased the output of twice ionized helium by three-five times. To decrease the ion losses during their acceleration and exit from the magnetic field, a focusing diaphragm was designed and employed on the dees which on the one hand strongly increased the ion focusing along the vertical ? The volume of the cyclotron vacuum system is about 5000 liter. 858 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 100 150 200 ? 211,kv Fig. 4. Target ion current depend- ence on the dee potential difference. in the cyclotron's central plane (where magnetic focus- ing is practically absent)* , while on the other blocked undesirable ions which in any case would have been lost during acceleration and exit. This decreased the load on the high frequency oscillator, reduced ion losses and con- sequently also the background and induced activity. The ion source was displaced to a previously calculated dis- tance from the center of the magnetic field. The ion current dependence on the acceleration radius is given in Fig. 2. It is obvious from the figure that there are no ion losses beyond a 40 cm radius. The ion delivery co- efficient from the deflecting system was 7050. To deflect the ions, a system was designed em- ploying hyperbolic electrodes which permitted beam focusing in the horizontal plant [4], more precisely, which compensated for the defocusing action of the bend- ing magnet's field. Similar systems to improve ion beam parameters have been used in other acceleration systems. z, 3 2 0 -1 -2 -3 j, Relative units -3 -2 4 0 1 2 3 x,cx a 05 I j,relative units Fig. 5. Ion current intensity distribution at the target along the horizontal (a) and vertical (b) distance from the target center: x along the horizontal; z along the vertical. Figure 3 shows the target ion current dependence on the deflecting system potential and Fig. 4 the dependence on the dee potential difference. The following parameters were obtained for the Her ion beam at the target situated 12 m from the cyclotron: Hes ion energy, measured by the range in aluminum, was 35 Mev; half width of the beam energy spectrum, measured by a magnetic analyzer ? not more than ? 0.31o; beam half width in the horizontal plane at the target ? 8 mm, in the vertical plane ?less than 8 mm. The ion current intensity distribution at the target along the horizontal and along the vertical is given in Fig. 5. The average ion current intensity at the target was 30 jia. Usually work had been conducted with an average target current of 10 pa. Using the third subharmonic of the high frequency, a sizeable Her ion beam with an energy of 5.4 Mev was accelerated and extracted on the target. To do this it was necessary to alter the potential between the dees (without changing the resonant circuit tuning) and to decrease Ho to 10,000 oe. This result shows that subharmonic acceleration does not drastically reduce the accelerated ion current. The authors wish to express their deep appreciation to N. A. Vlasov and S. P. Kalinin for the continuing in- terest in the project; to V. I. Lamunin and N. N. Khaldin for constructing the gas recycling system; to N. V. Kartashov for tuning the pulsed ion source; to the staffs of the operating group and machine shop who assisted in the preparation of the apparatus and cyclotron inlet system. ? A similar diaphragm is described in referente [3]. 859 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 LITERATURE CITED 1. H. Wegner, W. Hall, Rev. Scient. Instrum., 29, No. 12, 1100 (1958). 2. I. Sremlin, W. Hardy, H. Shaylor. J. Scient. Instrum., 36, No. 9 390 (1959). 3. A. Morton, W. Smith. Nucl. Instrum. and Methods, .f L3 (1959). 4. A. A. Arzumanov, E. S. Mironov, Atomnaya Energiya 6, No. 2, 202 (1959). 860 All abbreviations of periodicals in the above bibliography are letter-by-letter transliter- ations of the abbreviations as given in the original Russian journal. Some or all of this peri- odical literature may well be available In English translation. A complete list of the cover- to- cover English translations appears at the back of this issue. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 SILICON COUNTERS FOR NUCLEAR SPECTROMETRY S. M. Ryvkin, L. V. Maslov, 0. A. Matvee, N. B. Strokan and D. V. Tarkhin Translated from Atomnaya E-nergiya, Vol. 11, No. 3, pp. 217-220, September 1961 Original article submitted March 18, 1961 Laboratory models of surface-barrier and diffusion-type silicon n-p counters were developed which were suitable for nuclear spectrometry. The counters have linear pulse height-energy dependence for particles with 60 i paths (in particular, for a-particles with energies up to 10 Mev), and ^, 0.5 To reso- lution for an E of 5.5 Mev (with units of small area). A series of papers [1-4] appeared in foreign publications during 1960 in which spectrometric counters of nu- clear particles based on silicon n-p junctions were described. The semiconductor n-p counters operate on the prin- ciple of the ionization chamber, but the pulse resolution of the best units exceeds the resolution of an ionization cham- ber, being 0.25% or 14 key for 5.5 Mev a-particles [3,4]. Among other qualities of n-p 'counters, there should be noted the relative insensitivity to magnetic fields, the small size, the reliable detection of strongly ionizing particles in a background of weakly ionizing particles (for example, fission fragment nuclei in a background of a-, a -, and y -radiation), the linear dependence of pulse height on energy, and the high counting rate. Ru n-SI Fig. 1. Construction of a semiconductor counter and circuit diagram (shaded portion ? space-charge re- gion of n-p junction, the sensitive layer). Fig. 3. External view of the Physico -technical Institute counters. Fig. 2. Oscillogram of Pu238 a-pulses (0.2 ?sec markers). The sensitive layer of the counter ? the space-charge region of an n-p junction ? is formed in the immediate neighborhood of the irradiated surface. The original sili- con can be of either the n- or p-type. In the first case, a film of gold several hundred atom layers thick is de- posited to obtain an n-p junction; in the second case, diffusion of phosphorus produces an n-region 0.1-1? thick. These counters are schematically represented in Fig. 1. Particles incident on the counter give rise to ioni- zation, creating electron-hole pairs. These pairs are se- parated by the field in the space-charge layer, and the re- leased ionization charge Q is collected by the layer capacitance C and assembly capacitance Cm. Through this, the capacity is charged to a potential difference Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 (1) 861 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 C,nti cm2 1200 1000 800 600, 400 200 0 5 10 15 20 25 30 v 0;02/01,arb units 7,2 0,f1 0,6' 0,4 0,2 AL:2 I, 5 L. fa 0 02/07), E2=8,78 mev E =6,05 Inev 10 Fig. 5. Dependence of pulse height and ratio of pulse heights on applied voltage for a-particles with ener- Fig. 4. Dependence of counter capacity on applied gies of 8.78 and 6.05 Mev. voltage (unit numbers: 0 ?103; ? ? 90). 20 30 40 50 v Better peak resolution is obtained when practically the entire particle track is contained in the space-charge region the depth d of which is determined by the relation d = 1,4.10-6 V (Vo+ QIL Cht, (2) where V0 is the contact potential difference of the n and p regions (v); V is the applied bias voltage (v); p is the specific resistance of silicon (ohm-cm); II is the current-carrier mobility (cm2-v-sec). The characteristics of counters which were developed during 1960 at the A. F. Ioffe Physico-technical Institute of the USSR Academy of Sciences are described in this paper. Small area counters had a pulse height --lmv/Mev and a resolution of less than 110 for Ea = 5.5 Mev. The pulse shape is shown in Fig. 2. The counters were made by deposition of gold on n-type silicon and by diffusion of phosphorus into p-type silicon. The working area of both types of counters had values of 2 x 2, 5 x 5, and 10 x 10 mm (Fig. 3) In what follows, results of the investigation of the following counter characteristics are presented: 1) voltage- current characteristics; 2) dependence of capacity on bias voltage; 3) pulse height; 4) dependence of pulse height on a-particle energy; 5) resolution. 1. The voltage-current characteristics of the units have the usual shape for n-p junctions. The inverse current was 0.5-0.05 a at 40 v for a group of units 2 x 2 mm2in area. For units with 5 x x and 10 x 10 mm2areas, the current increased in proportion to the area. The breakdown voltage varied from 50 to 60 v. 2. An important parameter of the counter is the capacity of the sensitive layer ? the space-charge region. In the first place, the magnitude of the capacity determines the pulse height; in the second place, it is easy to determine the thickness, d, of the sensitive layer from the value of the capacity. It is obtained in a manner similar to that for a plane condenser d 8?8 4nC ' (3) where S is the area of the unit; E0 is the dielectric constant. Since d V + V? :he capacity must decrease as (V + V0) -1 with increase in applied voltage. This dependence was fulfilled with satisfactory precision by our units. The dependence C = f (V) calculated for a unit 1 cm2 in area is indicated by the solid line in Fig. 4. 3. Pulse height for a given capacity is determined by the free particle charge Q = eN where N is the number of ion pairs which, in turn, is determined by the average energy for pair formation (E) and the energy of the ionizing particle. In previous work (for example, [4]), it has been established that E does not depend on the nature and energy 862 Declassified and Approved For Release 2013/09/25 : CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 ? Not 200 150 100 50 0 5,491 Mev Generator 4ikey ? ? I ? 0 40key . 30kev t I I I 1 I ?I 1 . II 11\ / ? / / . . 40 50 60 channel number 70 Fig. 6. Pulse height spectrum of Pu238 a-particles (Peak half- width after subtracting instrumental noise was 27 key or 0.5010 of the ionizing particle, and has a value ?3.5 ev for silicon. For Pu 238 a-particles, we obtained Q = 2.5.10'13 k, i.e., 6 = 3.53 0.15 ev, with our counters. Therefore, charge was collected just as completely as in counters described earlier. 4. It follows from formula (1) that pulse height is proportional to charge collected. Therefore, by irradiating the counters with a-particles of different energies, and collecting all the resulting charge, we ought to obtain a linear dependence of pulse height on particle energy. Since a-particles with different energies have different path lengths, one should expect that complete charge collection will occur for different sensitive layer thicknesses, i.e., for different voltages. The dependence of the pulse height (I, on counter voltage V is shown in Fig. 5 for a-particles with energies of 8.78 and 6.05 Mev. It is clear that pulse height reaches a saturation value for the short-path group at ? 15 v. However, in this situation, the thickness of the sensitive layer is still insufficient for complete collection of the charge created by the more penetrating particles with an energy of 8.78 Mev. Saturation is achieved at ? 35 v for the more penetrating group. In addition, the ratio of pulse heights is equal with great precision, to the ratio of energies which testifies to the linear dependence of .1)(Ea). We were unable to check linearity for higher energies, but one can predict that linearity will be maintained at V = 60 v for a-particles with energies up to 10 Mev, or for other particles with 6011 paths. 5. We studied the value of peak resolution by standard methods using a 100-channel analyzer. Signal distortion because of noise and instrumental instability was taken into account with the help of a pulse generator. The spectrum of Pu238 a-particles measured with a 2 x 2 mm2counter is shown in Fig. 6. From the figure, it can be seen that two groups of a-particles were resolved whose energies differ by 41 key. The absolute value of the resolution after allowing for instrumental noise was 27 key or 0.501o. It is necessary to point out that the resolution depended strongly on the area of the unit. Thus, for 5 x 5 mm2 counters, the resolution was 101o, and for 10 x 10 mrr? counters, 10010 . Such a dependence is apparently explained by the fact that the characterisitics of various portions of a large surface will be non-uniform because of the non-uniformity of the silicon used, leading to a spread in pulse heights. Units 10 x 10 mrr in area prepared by us were used also at the Joint Institute for Nuclear Research in Dubna for detecting 863 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Ncr,f 150 100 50 0 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 13 0 12 20 28 36 44 52 channel number 60 Fig. 7. Pulse height spectrum of U2SS fission fragments in the presence of cc-particle background of 104 sec-1. 864 fission fragments from Um in the presence of a high a-particle background (104 sec-1). The resolution of two main groups of fragments is clearly demonstrated in Fig. 7 which was kindly furnished us by our associates in the laboratory of G. N. Flerov, corr. mem. Acad. Sci. USSR. The voltage on the unit needed for reducing a-particle pulse heights while taking the spectrum was not given. The results presented in this paper on the counting of a-particles and fission fragments do not exhaust all the possibilities for counter development. For example, n-p counters can be used for counting fast and slow neu- trons if nuclear reactions with neutrons which form heavy charged particles are employed. The authors consider it a pleasure to thank engineer G. V. Khozov, technicians I. A. Lebedeva and G. D. Gusarina, and machinist P. I. Gorshkov for helping greatly in this work. LITERATURE CITED 1. J. Blankenship, C. Borkowski, Bull. Amer. Phys. Soc., ser. 11, 5, No. 1, 38 (1960. 2. S. Friedland, L. Mauer, J. Wiggins, Nucleonics, 18, No. 2, 54 (1960). 3. J. McKenzie, J. Waugh. Bull. Amer. Pbys. Soc., ser. II, 5, No. 5, 355 (1960). 4. M. Halbert, J. Blankenship. Nucl. Instrum. and Methods, 8, No. 1, 106 (1960). Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 TWO-DIMENSIONAL BOUNDARY PROBLEM FOR TWO-DIMENSIONAL SQUARE LATTICES ? L. Trlifai Institute of Nuclear Studies, Czechoslovakian Academy of Sciences, Prague Translated from Atomnaya Energiya, Vol. 11, No. 3, pp. 221-229, September 1961 The present article is concerned with the density distribution of thermal neutrons on the surface of lumps in two semi-infinite two-dimensional square lattices that are separated by a plane. The solution of this problem can be re- duced to the solution of the Riemann boundary problem, which can be expressed in closed form. According to an analysis of the approximate solution for cases of practical importance, the asymptotic neutron density and its deri- vative are continuous at the boundary if the lattices are replaced by a homogenized medium. A similar solution of this problem for a lattice with an infinite reflector (moderator) is considered. Introduction In calculating a multizone heterogeneous reactor,it is necessary to determine the conditions for the neutron density at the boundary between two zones or at the boundary between the reactor core and the reflector. If the dimensions of individual zones and the curvature radius of the boundary are large, the necessary conditions can be determined by solving the problem of the neutron density distribution in two infinite lattices which are separated by a flat boundary. For the sake of simplicity, we shall assume that both lattices are square, that the spacing is a, and that the boundary betw6en the lattices, is equal to the distance 8./2 from the boundary lumps of both lattices. The lumps are cylindrical, unbounded, and located at the nodes of the lattices. If we use the assumptions of the heterogeneous method, which has been developed by A. D. Galanin, S. M. Feinberg, et al., the thermal neutron density N(ka) at the surfaces of lumps will be determined by the equation [1]. (I + po)N (ka) =-- 1-1 0 (I k ? I a) N (le a) + co ? H h =-0 (1 k ? a)for k < 0; ' -1 (1 + pi) N (ka) E H 0 (I k ? I a) N (lea) -I- CO ? H (I k ? k' la) N (k' a) ;pm k> 0 , (lb) h'=o where and a 240j I (I k I a) = Ikla) [ exp ELIO ? ati a exp CEO S X 2 Vagoi dx X ?= exp ? x x qii a2 P qoj 12L2q01 *This article has been received from the Czechoslovakian Socialist Republic. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 (2a) 865 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 for j equal to Oar 1. In Eqs. (la) and (lb), it is assumed that the symmetry is such that the neutron density is equal in all lattice nodes that lie in a plane parallel to the lattice boundaries. These nodes are characterized by the integer k. The lattice with type-1 lumps fills the half space with k a 0, and the lattice with type-0 lumps fills the half space with k < 0. The properties of the moderator are characterized by the moderation length Tr and the diffusion length L. The constants qoj and qij denote the internal and the external lump effects in lattices with type-0 and type-1 lumps, respectively; ij j is the effective value of the number of secondary neutrons in lump j. From physical considerations, it is clear that, at a certain distance from the boundary between the lattices, the solution N(ka) of Eqs. (la) and (lb) in both lattices approaches the asymptotic solution A. (ka), which is determined by the equation (1 p j) A (ka) = (3) = H (I k ? k' I a) A j (k' a) for j equal to 0 or 1. The general solution of Eq. (3) is well known (1]; it contains two constant factors, the values of which are not determined. However, in the case under consideration, the asymptotic regions are connected with the boundary re- gion, so that only two of the four constant factors in Eq. (3) will be independent. The elimination of these two in- determinate constants leads to the boundary conditions for the asymptotic curve of the thermal neutron density; the determination of these conditions is important in heterogeneous reactor design. The derivation of equations on the basis of the above considerations is given below. Let us break up the solution N(ka) of Eqs. (la) and (lb) into two portions: N (ka) A (ka) N (ka) = A1 (ka) n, (ka) for n, (ka) for k < 0; k>0. t (4) The ni (ka) values play a more important role only in the boundary region, while, with an increase in I kl , their absolute value drops very quickly (for instance, it drops more rapidly than the value of 13 exp (- I k I a), where a and 6 are positive numbers). According to expressions (la), (lb), and (3), the values of nj (ka) satisfy the following equations: 866 (1 + p o) no (Ica) = k! Ho(ik ? I a) no (le a) + =--o0 Hi(lk?kila)ni(ea)d- k'=o (5a) + hO [i I 1(1 a) A1 (k' a) ? H k ? 17) Ao(ka)]; (1 + 131) n1 (Ica) = H 0(1:1c ? I a) n (le a) ? ? HIP ? k' I a) n, (k' a) + ?1 +k E ["(I["(Ik ? I a) A, (k' a) ? '=?oz) ? 1/1 k ? k' I a) A, (k' a)]. (5b) Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 I. Reduction of Equations (5a) and (5b) to the Riemann Problem Since the values of nj (ka) decrease fairly quickly with an increase in I kI , we can determine functions 013+(z) and 61)- (z) of a complex variable z whose values on the unit-radius circle K with the center at the coordinate origin are determined by the following series: 00 (s) sh n1 (ka); lx.= 0 -1 (s) sh no (k a) . , it?co (6) Since the points s are located on the unit-radius circle, it can be assumed that s = exp(iaw). Thus, relationships (6) can be considered as Fourier series for the function of the (real) variable w with the period 2r/a of the inverse lattice. After multiplying Eqs. (5a) and (5b) by sk and performing summation with respect to k according to expression (6), we obtain after certain transformations: [1 p ? F i(s)] (s) = = +Po ? F 0 (8)1V (s) S (s) for s = exp (iaco), where and S (s) = SJo [H1(1 k k' I a) A1 (k' a) ? ? H0 (l k k' la) A0(k'a)]-1- co ?1 + Ash co[ ? H (I k k' I a) A1 (k' a) + +H 0(J k ? k' la) Ao (k' a)]. (s) =h c2co kl a) (7) (8) (9) We shall find two functions of the complex variable z which satisfy the linear relationship (7) on a circle with unit radius, namely, the function cl)+(z), which is an analytic function in the inside region K- of the circle K, and the function 4)-(z), which is analytic in the external region K- of the same circle, including z = CO. Then, the sub- sequent solution of E. (7) will be reduced to the solution of the nonhomogeneous Riemann boundary problem. In this, we shall follow the terminology and notation used in [2]. In order to solve the Riemann problem, it is necessary to determine the form of the function S(s) in Eq. (7), which is determined by expression (9), where A(ka) are solutions of Eq. (3). As was mentioned before, the solution of Eq. (3) is well known [1]. With the accepted notation, we can write: A (ka) = A .? B z7h .71 :71 I where A? andB ? are constants, and z? is the root of theequation l (10a) 1+ pi ? (zi)= O. (10b) The F3 (z) function is expressed by the Laurent series (8). For an active medium, zj = exp(iK ja), while, for an inactive medium, zj = exp (K ja), where K j are real parameters [3]. For a critical medium-, Eq.(10b) has a double root which is equal to unity, and the corresponding solution of Eq. (3) will be given by A3(ka) = Aj + Bjka. The summation of the series in expression (9) is given in the Appendix (see end of article). The obtained re- sult can be written in the following form: 867 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 S (s) = (- 1)5.1 + pj? Fj 5)] x (11) j=0 X (?I IA.+ B sz ? 2 S-Zi 2 ? After dividing both sides of Eq. (7) by 1 +Pi _ Fi(s), we obtain the usual form of the Riemann problem. The coefficient of this problem and its free term [2] satisfy the Helder condition on circle K, with the exception, perhaps, of the points zi and zi-1. At the points zo and 41, the coefficient of the problem may be equal to zero. From this point of view, the following three cases are of interest. 1. Media 0 and 1 are Active. In this case, we can write Eq. (7) on the circle K in the following form: G (s)cir (z) ? g (s). 82?(z,+-4-)s-1-1 The G(s) coefficient is real, bounded, and different from zero on the circle K, since, according to Eq. (7), and, according to (8), [1-1?po?F0 rs2?(zid?n s+11 G (s)? [1+ pi?F2 F5 (s) = F (4-) = F7 (s). The index of the coefficient G(s) is then equal to zero. The free term g(s) in expression (12) is equal to g(9= 1G z s 0 jr) -FB0(zo +B (z--)} and it has poles at the same points as the coefficient in front of 4)-(s) in expression (12), of the free term poles does not exceed the order of magnitude of the poles of this coeffic The Riemann boundary problem of this type has been solved in [2], and, therefore, results. The solution has the following form: 868 (s) (s)(s) + (.5)); 82 ? s +1 (12) (13a) (13b) while the order of magnitude ient. we shall write only the final (14a) Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 1(s) iD (s) ? (s)+ P1 (s)1, s2 ?(zo+ s +1 X? (s) = exp (r? (s)),where r? (s) = = ? -T In G (s) 2:11i Int G s(t) dt; (14b) g 1 1 'N g (s) = [ s2 ? (zi s (s) (14c) 21ni [ t2 (zi ;10 t Vtit) tdt s. k The function Pi(s) is a first-power polynomial with indeterminate coefficients. In system (14), this function represents the solution (12) of the corresponding homogeneous Riemann problem. The power of the polynomial is determined in such a manner that 4'-(z)--,0 for izI -4 .0 in correspondence with expression (6). The integrals in system (14) are considered as Cauchy integrals. If we know rI3+(s) and .1)-(s), we can determine the values of nj(ka). According to expression (6), no (ka) (s) (15) for k < 0; ni (ka) dss-h-10+ (s) fOr k> 0. The expressions under the integral sign in these equations must be functions that can be integrated. In correspondence with Eqs. (14a) an d (14b), this can be secured by putting (s)d- Pi (s) = 0 for s equal to z and 1 ? , and ir (s)d- P1(s) = 0 for s equal to zoand_ (16)zio Moreover, the thermal neutron density and the other physical parameters must be real quantities, and, consequently, the expressions (15) for n(ka) must also be real. On the basis of expression (15), it can readily be shown that this requirement is satisfied if the coefficients of the polynomial in system (14) are real. On the basis of the same con- siderations, we must assume that, in the case under consideration, Bj = A , where the asterisk denotes a complex conjugate quantity. Thus, the thermal neutron density on the surfaces of lumps can be expressed by means of Eqs. (14), (10a), (10b), and (15). The corresponding expressions contain six constant real numbers (ai = Ai + Al, bi = i(Ai + Al). where j is equal to 0 or 1, and two real coefficients in P1 (5). These constants are related by the four conditions (16), i.e., only two out of the six constants are independent. For the independent constants, it is convenient to choose aj and bj, which pertain to the asymptotic density in the medium j; the asymptotic in the medium j j, i.e., a'i and bij. will then be determined. If, in the asymptotic density Aj (ka), we use continuously varying coordinates by means of the substitution ka-4. y, the independent constants aj and b.; can be eliminated, and we can obtain the boundary con- ditions for homogenized media, which relate the asymptotic thermal neutron densities to their derivatives at the boun- dary between the two media. ? We shall prove the latter conclusion by considering an example of lattices where neutron moderation does not take place. The latter assumption was made in connection with the fact that we have still not succeeded in deriving from Eq. (15) any simple analytic expressi on for the general case. In this case, Fi (z) = ? ?a Lq(,) \ exp ( ?T) ? 1 x .L2 sin hL a (17) X a z+ --2 cos h L 869 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 i.e., according to Eq. (13a), G(s) = -(1+P,)/ 1 + Ps. The integrals in expression (14c) can now readily be determined by using the Riemann formula: 1 --2T (zjX (s) ==t; X+ (s) = I -1-P? ; T-(s) -,------ 0; l+p, W+ (s) = ? ao (1 ?s cos x0a) be sin x a 1+ PI X 0 1+ po Xi? (1? S cos xla) ? bis sin xsa]. (18) From the second of conditions (16), it follows that Ps (s)a-0. By using the first of the conditions (16), we shall de- termine the values of ao and bo in dependence on as and 131: 1+ps , l+ps ao=i+ vo--i?p X Po X cos xoa ? cos xsa a, + sin xla bs) sin xoa sin xoa (19) However, for these ao and 130 values, 11,4- (s)---0. According to expression (15), this means that the asymptotic solution (y) ai cos x3y bi sin xiy, (20) where y = ka, while the ao and 130 values are determined by Eq. (19), is the exact solution of the problem. Considering y as a continuously changing variable, we can express the independent constants as and 131 in terms of the values of functions A(y) and their derivatives A'j(y) at certain points y j: A1 (y1) cos xiy, ? A; (ys) sinxxiiyi = al = 11++ Z [ A, (y,) cos x0y, A' (y,) cos xiYi. b sin xoyo 1 . xo i' (21a) A, (y1) sin xiy, + A'? (Ys) 1? (21b) xs _1+ po r cos xo (y0+ a) ?cos xoy, cos xla sin x, (yo + a)? sin xoyo cos x,a1 1+pi L A (1 (g o) sin xia + A; (Y 1) x, sin xia i ? These relationships express the boundary conditions for the homogenized media 0 and 1 for certain definite yj values. The most rational choice will be yo = Ys - a/2. The boundary conditions (21a) and (21b) then assume the following form: 870 + po)tosy A0( (I+ P?) sin, Ao' (? 22-)? xo 2 2 (22) Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Since the relationships (1 ? pj) x cos kja /2 1 and (1 + pj) K j-1 Sinki a /2 IN a/2 hold for lattices that are usually encountered in practice, conditions (22) signify that the thermal neutron density and its derivative are continuous at the boundary. It seems to us that this statement will also remain valid in the case where the moderation of neutrons is taken into account if only the type-0 and type-1 lattices do not greatly differ from each other with respect to their physical properties. 2. Medium 0 is Inactive and Medium 1 is Active. Equations (7) and (11) can be written in the following form: D+ (s) = G(s) Cr (s) g (s), C1 ) 1 82?(zi-1-71.- 8+ where G(s)= and rs+ I [Id-po?F0(s)] 1+ F (s) I g (s) = X s 11-.) +1 (szof 1A0+ szozoB0)+ X [G (s) (23) (24a) (24b) The index of the coefficient of G(s) is equal to unity. The solution of the corresponding Riemann problem is ex- pressed by means of the equations [2] (s) X+ (s) (s)+C] sz?(k)s-1-1 and 0- (s) = X- (s) [T- (s) d- C], where X+ (s) = exp Er. (s)], X- (s) = s-1 exp [F- (s)], F(s)= [s-IG (s)] + I .in [t-1G (t)] dt? 2rct t?s 111.1 (s) = [S2? (Zi S+ 1 Vs()s)-E g (t) 1 1 +\ 27-ti dt [t2 ? (z1+? + 1] (25a) (25b) The symbol C denotes the constant which must be real (C = Ce). kThe values of ?( a) are determined by using Eqs. (15), in which (1)+() must be a function that can be integrated, we assume that (s)+ C = 0 for s equal to z and? . (26) If we now calculate all constants that were not determined up to now, we obtain five real constants in the problem: C, Ao, Bo, a1 = A1 + Al* , b = i (A1? A11). According to conditions (26), we shall eliminate two of these constants, which will leave us with three independent constants, which contradicts the physical considerations. This contradiction can be eliminated in the following manner. Since the first portion of the asymptotic solution (10a) corresponds to an inactive Medium 0, i.e., Aoexp( + Koka)(K 100 Bev in cosmic rays point to an approximate constancy of total cross sections of strong interactions, in any case in the energy range up to 106 Bev. However, it should be noted that errors in the measurements reach very high proportions, and that experimental data do not exclude a very slow increase or decrease in cross sections. Over the entire energy range stretching from several Bev to 106 Bev, 800/0 of all the particles generated are 71 -mesons; the mean transverse momen- turn and optimum energy value of particles being generated in the center-of-mass system also remain constant and independent of the energy of the primary particle. The mean number of particles generated varies approximately as the fourth root of the energy of the primary particle. The coefficient of inelasticity for very high energies is about 0.2-0.3. These problems were the subject of a review report presented by D. Perkins. The results found in cosmic rays were also discussed in reports by Polish physicists M. Miezowics and J. Herjul. The investigations of multiple particle production at very high energies, carried out in Poland, and especially the investigation of open angular distributions with two maxima (the so-called two-humped stars) performed by the Polish physicists led to the conclusion that the principal features of inelastic interactions at very high energies may be ac- counted for by assuming a dual-center generation of secondary particles. The attention of the conference was also attracted to a paper by B. M. Pontecorvo and Ya. A. Smorodinskii on the relation between the neutrino and astrophysics. Calculations have demonstrated that available experimental data are not in contradiction with the hypothesis holding that the energy density associated with neutrino and anti- neutrino fluxes is larger by many orders of magnitudes than the energy density associated with apparent matter through- out the universe. G. Cocconi and G. von Dardel reported experimental results obtained with the new large CERN accelerator. Data on total cross sections had been published earlier. New results referred primarily to ir -p-interactions at 16 Bev and p-p-interactions at 24 Bev. These findings do not differ qualitatively from those obtained at Dubna for it -p-inter- actions at '7 Bev and p-p-interactions at 9 Bev. In particular, secondary particles in the center-of-mass system have sharply anisotropic angular distributions. It was stressed that the mean transverse momenta of generated particles of 920 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 different species remain more or less constant independently of the species and energy of the colliding particles. This constancy of transverse momenta is observed over the entire presently accessible range of high energies. In his report, G. Cocconi also discussed some interesting data on quasielastic p-p-scattering at 24 Bev. During measurements of momentum distributions of protons scattered at very small angles, .a maximum which might be interpreted as due to resonance interaction between an intermediate it -meson and a target proton in the 3,3-state was detected, in addition to the usual maximum corresponding to elastic scattering. Some experimental indications point to the existence of two additional maxima corresponding to two successive resonances in it -N-interactions. A review of statistical theories of inelastic interactions at energies -.30 Bev formed the subject matter of papers by R. Hagedorn and E. Sudershan. It was noted in both reports that the various variants of statistical theories usually employed for calculation of multiple production of particles are suitable for explaining only averaged, global char- acteristics of inelastic interactions. For example, distributions of stars by multiplicity, probabilities of various channels of inelastic reactions, and mean momenta of particles generated are close to their experimental values. However, everything pertaining to angular distributions is in sharp contradiction to experimental evidence. This is apparently precisely what is invoked, in particular, to explain the pronounced divergence, noted by R. Hagedorn, between theo- retical and experimental probabilities of antinucleon formation at various angles in p-p-collisions at 24 Bev. At the limits of applicability in each case, several variants of the statistical theories yield close results and prove to be highly useful for calculating beams and planning experiments. A special session was devoted to a discussion of diffraction phenomena in strong interactions. The results of calculations of elastic -N-interactions observed at Dubna were reported on in a paper presented by D. I. Blokhintsev. ,It was shown that the real part of the amplitude of elastic it -N-scattering at high energies ( >1 Bev) is much smaller than its imaginary part; the distribution of nuclear matter in the nucleon and the nucleon radius were computed; a new method for analysis of diffraction scattering, which is in some cases preferable to the more familiar optical model, was proposed. The phenomena of diffractive particle production were discussed in a detailed and exhaustive report by M. Good. It is generally known that the theory of such phenomena was first developed by the Soviet physicists A. I. Akhiezer, I. Ya. Pomeranchuk, and E. L. Feinberg. At the present time, this theory has gained utmost urgency because of the possibility of verifying it experimentally on the large accelerators now available. G. Solzman delivered a review paper on single-boson peripheral interactions; the results of numerical calcu- lations run on electronic computers at Dubna were reported in the paper by D. I. Blokhintsev. Experimental data now available are not in contradiction to the assumption that the cross section of peripheral it -N- and N-N-collisions is many times in excess of the cross section for central collisions, for which a purely statistical description is applicable. The average numbers of particles produced, their angular and momentum distributions calculated under the assumption of a purely single-meson process, are in excellent agreement with empirical experience, within the limits of ex- perimental error. The theory of peripheral interactions, which is a natural outgrowth of statistical theory, nevertheless remains a very coarse theory. In particular, the virtuality of a peripheral meson is neglected in the calculations even at high momentum transfers (-0.5 Bev). But the theory still fits satisfactorily with experiment in many cases, even when its conditions of applicability are rather poor. It was noted in the discussion that the further progress of this theory de- pends crucially on amassing fairly accurate experimental data to establish the points at which divergences between theory and experiment occur. The use of single-meson peripheral interactions to account for quasielastic p-p-scattering detected in 24 Bev experiments was the subject of reports by F. Celleri and E. Ferreri, M. Baker, and B. Feld. Dispersion relations techniques were invoked by the first two authors in calculating the pion-nucleon vertex. The use of Mandelstam binary dispersion relations to calculate high-energy phenomena was discussed in papers presented by S. Fraucci, S. Fubini and D. Amati, C. Goebel. This trend is one which has come into prominence only recently, and most of the results here are of solely methodological interest; however some very encouraging numerical results have also come to light. For example, angular distributions of ff--mesons scattered elastically on protons at energies of 1.7 and 5 Bev, calculated by Fubini and Amati, are in excellent harmony with experiment- ally derived values. Despite the crudity of the approximations used in the calculations, this undoubtably represents considerable progress, since all calculations in this field have up to now been carried out solely on the basis of the phenomonological optical model. 921 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 A report delivered by H. Leman was devoted to an investigation of the asymptotic properties of the amplitude of elastic scattering. It was shown that the real part of the amplitude is always considerably less at high energies than its imaginary part, although the form of the energy dependence of the real part is dependent on concrete assumptions as to the manner in which the total cross sections tend to their constant limiting values as energy increases. These conclusions are in good agreement with results of computations carried out at Dubna. A considerable portion of Leman's report was given over to an account of the work of V. A. Gribov and I. Ya. Pomeranchuk, who examined the asymptotic behavior of the amplitude of processes involving particles and antiparticles in the ground state. It was particularly emphasized in this paper that no exponential variation in the cross section such as predicted by statistically theory was ever encountered. One should note, however, that all these conclusions are based on a re- placement of a virtual meson by a real one. The results of Gribov and Pomeranchuk may conceivably indicate that . such a replacement must be resorted to with great caution. A report by A. Schock presented the parameters of now familiar proton accelerators extrapolated to energy re- gions of the order of several hundred billion electron volts, and carried out a comparison of possibilities seen in accelerators of the usual type and accelerating systems based on colliding proton beams. The conventional acceler- ators will serve a broader range of purposes, apparently, from the standpoint of versatile experimentation. Interesting data on electron accelerators with colliding beams were contained in papers presented by B. Tuszek and B. Richter. Construction of an electron and positron colliding beam accelerator with particle energies of 250 Mev In each beam is nearing completion at Frascati. The presence of one and only one storage ring is a feature of this accelerator. Electrons and positrons are obtained via pair formation of gammas, which, are in turn generated by an electron synchrotron. The expected beam lifetime is ?250 his under 10-1? mm Hg pressure. At the present time, the storage system has been completely assembled, and the first experiments on injection and storage of particles have been carried out. At Stanford, construction is nearing completion on an electron beam stacking system at 500 Mev. It is expected that the first experiments on elastic scattering of electrons by electrons will be successfully engineered in about one half year. Stress was laid time and again in the discussions and reports on the enormous importance of improved accuracy of experimental data. This task is one of the most important and most urgent ones in contemporary high-energy physics. USE OF TRITIUM IN PHYSICAL AND BIOLOGICAL RESEARCH Ya. M. Varshavskii and A. A. Ogloblin Translated from Atomnaya Energiya, Vol. 11, No. 3, pp. 264-267, September, 1961 A symposium devoted to, the use of the radioactive isotop of hydrogen ? tritium ? in physics, chemistry, and biology, was held in Vienna during May 1961. The symposium was organized by the International Atomic Energy Agency in collaboration with the Joint Commission on Applied Radioactivity of the International Union of Scientific Societies. About 300 delegates from 28 countries and from four international organizations were in attendance. The calling of this symposium on an international scale was completely justified by the already large and consistently expanding interest in tritium. Tritium is the only radioactive isotope of hydrogen ? the element which enters into ?the composition of water and a large variety of other widely distributed and abundant chemical compounds, and also into the composition of almost all substances forming living organisms. This has led to the recent extensive use of tritium as a labeled atom in chemical and biological investigations. It is important to bear in mind that, of the re- maining elements of vital importantce to chemistry and biology (i.e., oxygen, nitrogen, and carbon), only carbon has a long-lived isotope, Cm, suitable for research ends. However, in contrast to tritium, pure CIA is virtually inaccessible and the specific activity of CIA preparations is quite low (0.001 curie/mole), while tritium preparations have an 922 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 activity of several curies per mole. This fact, added to the relatively low cost of tritium and tritiated compounds, lends particular importance to tritium applications. Since tritium readily displaces ordinary hydrogen in water, it has been possible to us tritium in various branches of geophysics related to flow and movement of water, such as meteorology, oceanology, and hydrology. The study of the problem of the origin of tritium on earth has revealed data of interest on cosmic phenomena. Research related to the tritium nucleus, known as the triton, has assumed intense interest and led to applications of practical importance. Triton is, following the deuteron, the simplest nuclear system, and the study of its interactions with other nuclei has yielded a series of valuable information on the structure of nuclei and the mechanism of nuclear reactions. The large cross sections of some reactions involving tritons at low energies and the large energy yields of those reactions have made tritium one of the most important thermonuclear fuels. All aspects of the use of tritium in various fields of natural science reveal many features in common, related to the procedure for introducing tritium into the system being studied, detection of tritium, and consideration of isotope effects due to the considerable difference in the masses of tritium and its light hydrogen counterpart, protium. The papers delivered at the symposium may be arbitrarily broken down into two groupings, as follows: 1) methods for detecting and recording tritium responses; 2) distribution of tritium in nature and its use in meteorology, ocean- ology, and hydrology; 3) isotope effects of tritium; 4) techniques for introducing tritium into molecules of chemical compounds; 5) use of tritium for the study of the mechanism underlying chemical reactions and radiation-chemical processes; 6) the use of tritium as a tracer atom in the study of biological processes and the effect of intrinsic radi- ation emitted by tritium on biological systems. Methods for Detecting and Recording Tritium The most precise technique for determining the amount of tritium 'present consists of measuring tritium activity. Since the beta particles formed as tritium decays are very soft (6 -spectrum cutoff at 18 key, corresponding to a range of 0.5 mg/cm2), the tritium has to be introduced into the operational volume of the counter in order for activity to be measured. At the present time, two techniques for recording tritium emissions have been employed with success: 1) using a Geiger counter (less frequently a proportional counter) with tritium introduced in the gaseous phase into the counter interior; 2) using a scintillation counter with a tritium-containing liquid scintillator. The primary advantage of Geiger counters in this application is their high efficiency (close to 100%), although they can be used to measure the activity of only a few specimens (since the entire specimen must be converted to the gaseous phase). In most cases, preliminary enrichment of the specimen with tritium is necessary, introducing some additional error into the measurements. The most important problem in the design of facilities based on Geiger counters is therefore reduction of counter background and finding means of increasing the amount of tritium which might gain access to the counter. To reduce background, recourse is had to shielding against external radiation and to anticoincidence counters. To reduce background attributable to radioactive contaminations of the counter material proper, the volume of the counter used to record tritium emissions is sometimes separated from the volume of anticoincidence counters in which it nests by a single thin foil. In the best counters reported on at the symposium, the background was 2-3.5 cpm for an effective volume of 1.5-3 liters. The amount of tritiated gas which can be accommodated in the counter is limited by a deterioration in counter characteristics. An investigation of the quenching properties of various gases has shown that ethylamine yields the best results. When the counter is filled with ethylamine to 3-7 cm Hg and with hydrogen to 40 cm Hg, very few spurious counts are observed; the length of the plateau goes to 500 volts. Good results are also had with ethyl ether, isoprop- ylamine, and isoprene. All of these gases yield excellent counter characterisitics superior to those of ethylene, the standard gas used till now. Another very effective approach has been to supplement internal quenching by means of a quenching gas medium with external quenching with the aid of an electronic circuit, which lengthens the counter dead time to 10'3 sec. Until recently, no success had been met in attempts to obtain satisfactory counter characteristics when a counter was filled with water vapor to a pressure above 20 mm Hg. A paper by R. Ealey and L. Ballard (USA) described a counter having a plateau over 200 volts in length when the counter was filled with water vapor to 350-400 mm Hg, and with a mixture of butane and helium to 350-400 mm Hg. 923 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 In contrast to Geiger counters, scintillation cowiters can be used with many specimens. However, the effi- ciency in recording tritium radiation is not high for scintillation counters, in fact usually only several percent, attributed to the low energy of decay. This efficiency has been successfully enchanced by the use of special multi- plier tubes (J. Sharpe, W. Stanley, Britain). The composition of the scintillator has an important effect on tritium counting conditions. In working with tritiated water, as D. Beal and J. Whitehead (Britain) have shown, the best mixture is dioxane ? naphthalene ? water with a water content of 18.6%. Difficulties often arise in work with organic compounds, because these compounds either will not dissolve in the scintillator or because they quench the light flash. This explains why choice of the proper solvent is one of the first problems to be tackled. On the whole, the symposium evinced a certain tendency to give primacy to the role of Geiger counters over that of scintillation counters. The best facilities using Geiger counters are capable of measuring a tritium concen- tration of the order of 1 atom of tritium per 1016 hydrogen atoms. Scintillation counters remain most convenient for rapid and not particularly precise determination of tritium content. Problems related to recording of tritium nuclei formed in nuclear reactions were discussed in a paper presented by A. A. Ogloblin (USSR). The technique developed in this case allows for measuring the energy and angular dis- tributions of tritons under conditions practically free from background contributed by other charged particles. The tritons emerging from the target are trapped in stacks of foils situated around the target, and after an exposure tritium content is measured in each foil. The use of this technique has made it possible to investigate the fundamental features of nuclear reactions involving triton formation. Geophysical Research Tritium is being widely employed in current geophysical research. Since the half-life of tritium is negligibly small compared to geological time, some constant source of tritium on the earth is required for its continued presence. Until 1954, the primary source for the formation of tritium on the earth was constituted by cosmic rays. During the past 7 years, the amount of tritium has increased some 10-15 times, which is due to tests of thermonuclear weapons. Tritium content in atmospheric precipitation, in air samples, and in surface waters is now decisively dependent on the place, time, and nature of the explosions carried out. This has been very convincingly demonstrated by W. Libby ( USA) in a long report read to the symposium. Tritium content in precipitates and water samples is observed to be a linear function of the amount of thermonuclear material exploded. The thermonuclear origin of atmospheric tritium is strikingly confirmed by the clearly defined correlation be- tween tritium content and Sr content in precipitates and fallout. Measurements carried out during the years 1958- 1960 show that the content of both isotopes in fallout varies with time in an identical manner. In the spring of 1959 a sharp maximum in the content of both isotopes was observed; this is related, in Libby's view, to tests performed during the autumn of 1958. Since the summer of 1959, following the cessation of nuclear weapons testing, tritium and Sr" content in atmospheric precipitation has fallen off sharply. On the papers devoted to tritium formation in nature unrelated to thermonuclear explosions, one worthy of particular attention, presented by E. Feierman (USA), reported a variation in tritium content in meteorites and in the outer casings of artificial satellites brought back from circumterrestrial orbits. The quantity of tritium measured in meteorites (seven stony meteorites and eight iron meteorites were studied) agrees in general terms with what one would predict from the effect of primary cosmic particles. However, the tritium content found in the material of satellites turned out to be many times higher than that formed in response to bombardment by cosmic rays. The satellite Discoverer-XVII was launched on November 12, 1960 and was in orbit for 50 hours with apogee at 995 km and perigee at 185 km. An intense solar flare appeared on the sun several hours prior to the launching. Tritium con- tent in the satellite material proved to be several thousand times higher than in meteorites. Tritium content in the material of the Discoverer-XVIII satellite, launched on December 7, 1960 into an orbit with similar orbit parameters, proved to 10-20 times less than in the preceding satellite, but still many times larger than in meteorites. One plausible explanation to account for the results obtained is that tritium was formed as a result of nuclear reactions on the surface of the sun during the period of increased solar activity. Some of this tritium reached the earth and was trapped in its vicinity for some time following the flare. Pursuance of these investigations should be of great interest in the study of solar processes. The hydrological investigations reported on at the symposium refer predominantly to the study of ground water flow in different localities and terrains. The study was carried out by concurrent measurement of natural tritium 924 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 and introduction of tritium into water reservoirs, in some cases. Experimentation showed that the use of tritium in this type of investigation yielded results in no wise inferior, with respect to precision and accuracy, to those attained by other methods. Investigations in the area of oceanology pertain primarily to the study of the mixing rate of waters. Isotope Effe cts of Tritium Great differences in the masses and zero energies of hydrogen isotopes lead to very noticeable isotope effects in the case of tritium which cannot be ignored when evaluating the results of experiments involving isotope exchange. The more generalized theoretical problems involved in isotope effects were considered by Ya. M. V arshavskii (USSR) and Y. Biegeleisen (USA). Varshavskii's paper described a method of statistical-thermodynamical calculation of equilibrium isotope effects for various types of hydrogen isotope exchange reactions. Calculated values of tritium distribution coefficients (a) for protium-tritium exchange between different components at 20?C were presented. It was shown that the value of a may reach very high values (above 20) for some systems (e.g., hydride of an alkali metal ? hydrocarbon system). The physical fundamentals of the general approach which had made it possible to predict the values of a for isotope exchange in any systems of hydrogen-containg substances were formulated in this paper. The problem of the relationship between isotope effects for deuterium and tritium was considered in Biegeleisen's paper. The predominant role is attributed to what is known as the primary isotope effect, corresponding to processes accompanying the scission of chemical bonds or major effects due to bond disruption. The secondary effect, much smaller in scope, is due to a change in intermolecular forces. A method for tentative calculation of tritium isotope effects based on data dealing with deuterium isotope effects was laid bare in this paper. Methods for Introducing Tritium into Molecules The very simple and convenient method for introducing tritium into molecules of complex organic compounds suggested by K. Wilzbach in 1957 has opened up broad perspectives for the use of tritium as a tracer atom in organic chemistry, biochemistry, and biology. The gist of the Wilzbach method is that the substance to be investigated is placed in an atmosphere of gaseous tritium, the isotope exchange process sets in and protium atoms are replaced by tritium atoms. One essential feature is that in the case of tritium exposure, in contrast to deuterium labeling, ex- change takes place not only at the O-H- and N-H-bonds, but also at the C-H- linages. The Wilzbach method has been extended at present to promote tritiation of gaseous, liquid, and even solid compounds. The mechanism of the corresponding isotope exchange reactions is still somewhat obscure, but available data support the view that hydrogen exchange is a radiation-chemical process initiated by tritium-emitted betas. In his report to the symposium, K. Wilzbach (USA) presented new data on the method which he discovered and which bears his name. The paper laid special emphasis on radiation-chemical side reactions taking place in the system. One typical trait of the method is the nonuniform distribution of tracer throughout the molecule. For ex- ample, in the case of toluene, the content of tritium in the ortho position is 16 times the tritium content in the CH3? group, while the tritium content at the meta?and para- positions is 7 times as great as in the Cl-I3? group. And in the mandelic acid molecule, tritium concentration in the aromatic ring is 750/0 of tritium content in the CH(OH)COOH functional group. Other techniques for tritium-labeling of molecules were also discussed at the symposium, (e.g., exchange in an electrical discharge, exposure to ultraviolet light, etc.). As a rule, the different techniques are distinguished mainly by a preferential labeling of different sites in a molecule. For example, the Wilzbach labeling technique leads to a preparation labeled predominantly in the ring in the case of toluene, whereas toluene labeling under an electric discharge chiefly affects the CH3? group (H. Ache, West Germany). Problems involving preferential tritium labeling of iodine-containing compounds were dealt with in a paper by P. Feng (USA). Interacting with tritium gas, iodine is easily replaced by tritium with the formation of selectively tagged compounds. Labeling of complex organic compounds without the use of tritium gas was the topic treated by two reports. D. Garnett (Australia) told of experimental findings on isotope exchange between T20 and aromatic hydrocarbons and their derivatives in the presence of platinum catalyst. A typical feature of the isotope exchange reaction with T20 was the pronounced difference in rate of exchange for various hydrogen atoms on the aromatic ring. The catalytic exchange method has some advantages over the Wilzbach method, since more selectively tagged products can be arrived at through the former method. R. Falter (USA) devoted his paper to isotope exchange between vapors of organic substances and heated uranium tritide. 925 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Several reports touched on the biosynthesis of tritium-labeled biologically active compounds. Investigations of Mechanisms in Chemical Reactions D. Barre (USA), in a review paper, took up questions associated with the use of tritium in the radiation chem- istry of organic compounds. The origin of hydrogen atoms liberated in radiolysis can be determined in some cases by introduction of tritium as tracer atom, as can the mechanism of interaction between hydrogen gas and organic matter, etc. The data obtained were correlated with data available for deuterium. This comparison resulted in a successful evaluation of the dependence of isotope effects on the mechanism behind the process, and in drawing of inferences on the effect of the intrinsic radiation of tritium on radiolytic and isotope exchange processes in the sys- tems studied. A. Powell (USA) told of results of an investigation of the Cannizzaro reaction using tritium tracer in the para- positions of benzaldehyde and phenyl benzoate. The principal inference drawn from the research is that the first stage of the Cannizzaro reaction is an intermolecular shift of the hydride ion, rather than an intermolecular displace- ment of hydrogen. The isotope effect discovered for this reaction is an indication that the stage of proton transfer follows the first stage, rather than running concurrently with the shift of the hydride ion. D. Beal (Britain) reported on applications for a highly promising double-labeling (I-13 and C14) technique. This method makes it possible to study the amino acid composition of proteins in trace quantities (of the order of micro- grams), opening up new opportunities in protein chemistry. Biological Investigations Roughly half of all the papers submitted to the symposium dealt with tritium applications in biological research. These may be subdivided under two headings: 1) papers in which radiation effects of tritium on biological systems are investigated; 2) papers dealing with the study of various biological processes with tritium used as tracer atom. The radiation effects of tritium may have the effect of accelerating hydrogen isotope exchange, with some loss of tracer as a result, and may lead in some instances to appreciable changes in the characteristics of the biological system. Results of a study of tritium beta effects on the growth and activity of ricketsial bodies, influenza virus, intestinal bacilli, the bacterial flora of the cud of large horned cattle, etc. were presented in some papers. A paper by E. Cronkite (USA) dealt with a study of the toxicity of tritiated thymine. The possibility of employing the beta radiation of tritiated drugs to cure cancer was examined in a paper by D. Marian (Britain). A high-activity (28 curies/mole) preparation was synthesized, and this preparation readily gained access into living cells. The intake of malignant cells was found to be more rapid than that of healthy cells. It is important that assimilation of the preparation by bone marrow cells proceed at a rate of at most only one fifth that of tumor cells. Positive results were indicated from use of this preparation on patients. Papers devoted to the use of tritium tracer touched on research into the broadest variety of biochemical processes: most of the reports dealt with particular problems. At the same time, several methodological novelties of some in- terest were reported on. A paper by J. Hampton (USA) demonstrated new opportunities for the simultaneous use of autoradiography and electron microscopy for the study of cell processes in vivo. The method suggested was success- fully employed for detailed monitoring of the process of incorporation of tritiated thymine into the nucleus of a DNA cell. W. Sin i (USA) presented his findings from an investigation of isotope exchange in animal organisms. The analysis showed that approximately 981 of the tritium introduced into the organism was incorporated into the body water, and 2% into the tissues. Many papers were devoted to a study of cell metabolisms using tritiated thymine and cytidine preparations. In particular metabolic studies were made of bone marrow cells (F. Gavosto, Italy; W. Bond, USA), tissue metabolism of thyroid hormones (J. Roche, France), etc. 926 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 SEMINAR ON THE USE OF ISOTOPES AND NUCLEAR RADIATIONS IN BLAST FURNACE PRODUCTION P. L. Gruzin Translated fromAtomnaya gnergiya, Vol. 11, No. 3, pp. 268-269. September, 1961 A broad research and development plan for applications of radioactive isotopes and nuclear reactions in the metallurgical industry was started in the USSR in 1948-1949. At the present time, many research projects on the possible applications of isotopes and nuclear radiations are being completed at factories and inInstitutes. This has pointed up a need for topical seminars on special problems in metallurgical production. A seminar on the use of isotopes and nuclear radiations in blast furnace production was held during March 1961 at Dneprodzerzhinsk, under the sponsorship of the Commission of the State Scientific and Engineering Committee of the Russian Soviet Federated Socialist Republic on the integration of isotopes and nuclear radiations into industry, and of the Dzershinskii metallurgical plant. Over 50 scientists and engineers engaged in the development and pro- duction engineering of various isotope and radiometric techniques and instruments in blast furnace production took part in the seminar. The most important metallurgical enterprises of the nation (the Dzerzhinskii plants, the Il'ich "Azovstal' " plant, the Stalino (Donets), Krivoi Rog, Novaya Tula, Cherepovets, KMK, YuGOK, etc, plants) were represented at the seminar, along with leading scientific and research Institutes engaged in metallurgical studies (TsNIIChM ferrous metallurgy research institute, the Ukrainian Institute of Metals, the Dneprodzerzhinsk metallur- gical institute, the Moscow Engineering and Physics Institute (MIFI), and other). 19 papers and communications on the use of radiation and isotope methods and instrumentation for monitoring, control, and investigation of blast furnace production processes were read to the seminar. The participants benefited from trips to the Dzerzhinskii plant, the Krivoi Rog metallurgical enterprise, and the YuGOK enterprise, where they became acquainted directly at shop level with the substance of the advances based on isotopes and nuclear radiations, and with the process instrumentation of these major plants. All of this was an enormous aid to the seminar participants in carrying out a detailed discussion of the contents of the papers, and singling out the perspectives of further work. Let us spend some brief time on typical reports made to the seminar, and outstanding remarks by participants. ? P. L. Gruzin (Moscow) and A. D. Kutsenko (Dneprodzerzhinsk) gave, in their papers, a general evaluation of the status of work on applications of instruments and nuclear radiations in various branches of metallurgical production, and shed light on the perspectives of further production-line exploitation of the achievements of nuclear physics in metallurgical practice. Attention was drawn to the extensive opportunities for the use of radiation sensors whose functioning is based on the use of 8- and y - and neutron radiation, and various process control systems of metallur- gical interest. The applications of neutron sources of radiation for continuous monitoring of high temperatures and moisture of raw materials was discussed in particular. Possibilities for the use of radiometric techniques to monitor the dimensions of hot-rolled product of complex configuration were discussed, as well as the activation analysis method in application to blast-furnace burden, and the method of gamma-neutron probing of the tuyere zone and the shaft of the blast furnace. In the discussions on the papers, it came out that all of these questions are of vital sig- nificance to the plans for starting up the world's largest blast furnaces in our country. A report by I. G. Polovchenko and V. N. Uzlyuk was devoted to a review of research involving tracer and radioisotope studies carried out at the Dzerzhinsk plant in cooperation with the TsNIIChM institute. The reporters limited their treatment in the main to a generalization of data from their own investigations, partially known to the participants of the seminar from published materials. Data on the economic effectiveness of the use of various radiometric techniques and instruments in blast furnace process control were heard with intense interest. It was pointed out in their report that isotopes have been successfully employed to extract valuable data on problems in- volving control of the blast furnace melting furnace, for improving furnace design, atutomation and correction of operations during a heat, with a resulting increase of 2.5-31 in pig iron melts, a 3-3.50/0 reduction in fuel costs, and a 5-8010 increase in furnace operating life. Several reports and statements from the floor were devoted to peculiarities in the design of on-off and servoed radiometric level gages for monitoring the level of blast furnace burden, and the results of industrial production tests 927 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 at the Dzerzhinskii plant. All of the reporters and commenters introduced many valuable suggestions on improving individual components in the existing prototypes. V. I. Afanas'ev and V. G. Smirnov gave a brief characterization of the design of a new model of servoed radiometric burden level gage (URMS-2), developed by TsNIIChM on the basis of industrial tests of the device under production conditions at the Dzerzhinskii plant. The participants at the seminar acknowledged the feasibility and timeliness of the installation of UFtMS-2 devices at 15 blast furnaces of the NTMZ, Krivoi Rog, KMK, Il'ich, and other metallurgical plants during the 1961-1962 period. Several reports and comments were devoted to a discussion of radiometric techniques for control of hot spots in the well of blast furnaces (at the Dzerzhinskii, KMK, "Azovstal' ", Il'ich, and NTMZ plants). These techniques have been in use at over 30 furnaces. The method was first tried out in 1950 at the NTMZ plant, and data extracted from the experiment provided a basis for suggestions toward enhancing well durability (increased cooling facilities, use of improved refractories, etc.). Subsequent research work at those plants confirmed the correctness of those suggestions, which have been incorporated in good measure into blast furnace construction practice, with excellent economic returns of a qualitative nature. The method developed for checking hot spots in the blast furnace well has been adopted by other countries. A. V. Pugachev (Tula) devoted his paper to a discussion of results of industrial testing of a radiometric facility designed to monitor the degree of sintering of sinter cake. V. M. Ivanov pointed out several difficulties standing in the way of adapting this device to production conditions at KMK. N. S. Gogin (NTMZ) noted that the use of the radiometric method for monitoring the degree of sintering of sinter cake under high-temperature operating conditions is of enormous significance. The seminar also took up the results of a study of the rate of flow of burden materials in blast furnaces (of the Dzerzhinsk "Avozstal' " plants), the perspectives for the use of radiometric methods in quality control of burden (TsNIIChM), and some questions relating to blast furnace production theory where isotope applications are concerned (Dneprodzerzhinsk metallurgical institute). A paper presented by A. S. Golovan' dealt with the perspectives for the development of research on radioisotope applications in enterprises of the Dnepropetrovsk Council of the National Economy. At the concluding session of the seminar, a resolution was adopted in which the most efficient approaches for implementation of isotope and nuclear radiation techniques in blast furnace production were indicated. The par- ticipants of the seminar pointed up the need for a systematic program of topical seminars on applications of radio- active isotopes and nuclear radiations in particular branches of metallurgical industry. We may accordingly rest assured that this first experience in carrying out topical seminars of this nature has been a positive one. 928 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 ISOLATION OF TECHNETIUM A sophisticated process [1] for obtaining kilogram quantities of technetium Te99 (weak beta-emitter with a half-life of 2.12.105 yrs) from spent nuclear fuel has been developed at ORNL. To date, most of the technetium was extracted, along with uranium in UF6 obtained by fluorination of uranium trioxide, from spent uranium. Anion ex- change techniques have been successfully employed to extract technetium more efficiently. The technetium from a concentrate containing negligible amounts of fission fragments and ions of aluminum, calcium, sodium, uranium, and fluorine, was extracted with 2,4-dimethylpyridine. The organic phase was distilled off and Tc99 was collected in the residue with some amounts of impurities from the concentrate and with the dimethylpyridine. This product was extracted to remove organic impurities, using an extractant mixture of tri-n-octylamine in benzene. Pure technetium was isolated in the form of ammonium pertechnate by repeated crystallizations from a solution of ammonium nitrate. This salt was reduced by contacting with hydrogen at 400-500?C, and a metallic powder con- taining over 99.9% Tc99 was obtained. This improvement in technology brought the cost of technetium down from 1600-2800 dollars/gram to 100 dollars/gram. At the present time, the monthly output at a pilot plant has increased a thousandfold and amounts to about 400 g of metal, but may be increased further to meet mounting demands. The pertechnate ion?a powerful inhibitor of corrosive attack by water on iron and steel ? is being eyed as a potential anticorrosion medium for boiling water reactors. Tc99 has the added distinction of being an excellent superconductor (the transition temperature of 11.2?K is the lowest [2] for the elements). Its melting point is ?2200?C [3]. Most of the fundamental properties of this element have yet to be studied, although some considerations on its possible alloys are discussed in the literature[4]. LIT ERA TURE CITED 1. Chem. Engng. News, 39, No. 9, 52 (1961), 2. A. N. Murin et al. Uspekhi khimii. 30, 249 (1961). 3. E. Anderson et al. Nature, No. 1883, 48 (1960). 4. N. V. Ageev et al. Doklady akad. nauk SSSR, 129, 555 (1959). REFLECTING BETA THICKNESS GAGE MONITORS SETTLED COAL DUST IN MINES (ROTOP-3A GAGE) The use of the principle of the reflecting thickness gage [1] has aided in the development of a device for sensing the amount of dust precipitated on the surfaces of mine workings, an advance of no mean significance for miners' safety conditions. The radiation -actuated reflecting thickness gage for monitoring coal dust, the ROTOP-3 [2,3], developed by the State Makeev Scientific Research Institute of Work Safety in the Mining Industy jointly with the Khar'kov Mine Surveying Instruments Manufacturing Plant (KhZMI), has passed industrial tests with flying colors and has been recommended for routine use. In 1960, KhZMI engineered industrial production of a modernized version of the ROTOP-3A thickness gage. The functioning of this instrument is based on changes in the intensity of reflected beta radiation by the isotope T1204 as a function of the thickness of a layer of monitored coal dust lying on tope of a rock substrate. The presence of an appreciable difference in atomic numbers (of the order of 7-8 units) between the coal, which is the exposed material in the given case, and the host rock which is the bulk material forming the substrate, provides the necessary conditions for successful functioning of the radiation thickness gage. The gage (Fig. 1,2) consists of a planar ionization chamber with a stretched aluminum foil and polyethylene film covering the entrance window a compartment for an annular radiation source surrounding the ion chamber, a d-c electrical amplifier, and a microammeter calibrated in units of surface concentration of dust. 929 Declassified and Approved For Release 2013/09/25 : CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Fig. 1. General view of the ROT OP-3A 930 The annular emitter is made up of 29 point sources of T1204 built up on the base of a standard B1 source. The total activity over the emitter surface is 5 microcuries. The d-c amplifier is based on a 2E2P electrometer tube included in a balanced bridge circuit. The electrical com- pensation of the initial current provided for in the circuit makes it possible to amplify and measure only that part of the ionization current which is due to reflection from a coal-dust layer. The redesigning of the instrument for transient measurements under the natural conditions prevailing in coal pits, with a rather uneven and rough contouring of the rock substrate, necessitated considerable changes from the more familiar coating- layer thickness gages, and added to the difficulties hampering measurements. The principal difficulty is due to the impossibility of constantly com- pensating initial current, since the contouring of the surface to be monitored is different for any run of measurements. Fig. 2. Cross-sectional view of the ROTOP-3A thickness gage; 1) shielding screen; 2,4) supply compartments; 3) micorammeter; 5) electrometer tube; 6) ion chamber housing; 7) amber insulator; 8) grid electrode; 9) radiation source; 10) diaphragm for entrance window. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 The redesigning of the instrument for transient measurements under the natural conditions prevailing in coal pits, with a rather uneven and rough contouring of the rock substrate, necessitated considerable changes from the more familiar coating-layer thickness gages, and added to the difficulties hampering measurements. The principal diffi- culty is due to the impossibility of constantly compensating initial current, since the contouring of the surface to be monitored is different for any run of measurements. A procedure of measurements was developed to eliminate any effects of mine topography on the results, and functions as follows. The gage is placed on a rock substrate covered with coal dust. All of the current due to re- flection of radiation is compensated by feeding in compensating voltage, and the gage is reset to zero. A rubber bulb is then squeezed to blow away an area of dust from underneath the instrument, and the compensation voltage proves insufficient in view of the increased reflection. The circuit then balances out at a level proportional to the amount of dust removed, and this is recorded by the output device. When compensating voltage is used in this manner, some constant contribution from the voltage is always placed across the control grid of the measuring part of a 2E2P double tetrode to drive the grid bias to a value equal to the bias voltage across a second control grid, i.e., actually to reset the amplifier. The remaining portion of the voltage, whose function is to directly compensate ionization current, varies in different measurements and is higher or lower depending on the surface topography of the section of mine being monitored. The effect of surface topography on instrument readings is thereby virtually eliminated, enhancing the use of the gage as a portable instrument. The measurement range of the instrument runs from 0 to 70 g/m2 with a sensitivity of 1 g/m2. Within these limits, the thickness of a coal-dust coating is far removed from what is known as infinite thickness, so that the in- strument scale is linear. For the same reason, any unevenness in dust distribution is without effect on instrument readings within an effective surface area range of ?150 cm2. The error in the measurements does not exceed 10 % of measured value over the range 10-70 g/m2. The instrument weighs 3.2 kg. Mercuric oxide batteries and wafer cells are used as power supplies. The instrument is operated by a single operator. The leaktightness of the radiation sources and the comparatively high hardness of the radiation from the isotope selected for the job (Emax = 0.765 Mev), as well as the presence of shielding "jaw" hinges shutting off the emitter when in "off" position, fully guarantee radiation safety of the instrument in conformity with the latest public health rules. Experience in the use of the gage has demonstrated the efficiency of ROTOP-3A gages in rendering serious assistance while safeguarding mine safety conditions for the benefit of miners. LITERATURE CITED 1. E. Clarke, S. Carlin, W. Barbour. Electr. Engng., 70, No. 1, 35 (1951). 2. F. E. Krigman et al. Patent No. 113576, 1958. 3. Ya. N. Fortel'meister et al. Ugol', No. 1, 48 (1959). All abbreviations of periodicals in the above bibliography are letter-by-letter transliter- ations of the abbreviations as given in the original Russian journal. Some or all of this peri- odical literature may well be available in English translation. A complete list of the cover- to. cover English translations appears at the back of this Issue. 931 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Brief Communications Poland. In line with the decision adopted by the X session of the Learned Council of the Joint Institute for Nuclear Research, a conference on cyclotron-based scientific research was held June 5 to 10, 1961, at the Institute of Nuclear Physics at Krakow. Reports from physics institutes of member nations of the Joint Institute for Nuclear Research were presented to the conference. The agenda of the conference included an exchange of experiences on the performance and further improvement of the U-120 model cyclotron, specimens of which are being used in many institutes of member nations of the Joint Institute, and time was set aside for a discussion of the results of physics experiments carried out on accelerators, and trends in future research. Participants learned from the papers presented that a stable mode of acceleration had been achieved by the time of the conference on all U-120 cyclotrons in use, and that experimental researches are being undertaken on a broad scale. Possibilities for expanding the range of accelerated particles, increasing the limiting energy, and monochromatizing beams of accelerated ions were also discussed. It should be noted that despite individual technological flaws which came to light in the process of testing and adjustment, the U-120-1 cyclotrons developed and fabricated by the Institute of Electrophysical Equipment (USSR) have come in for high praise at the conference. A wealth of experimental material dealing with scattering on the nuclei of various particles has been amassed in recent years. Papers were read to the conference on measurements of spectra and angular distributions of neutrons and charged particles in reactions of types (d,n); (d,t); (a,n); (a,t), etc. The discussion demonstrated the need for further research efforts in these areas, and the urgency of obtaining intense beams of polarized protons on the cyclotron. In experiments on investigation of gamma radiation appearing in response to bombardment of some nuclei by protons, deuterons, and heavy ions, a certain amount of interest has centered on the study of cascade gamma transi- tions in (a, y) reactions, and on experiments probing into coulombic excitation of levels in nuclei. Much attention focused on problems of technique, particularly semiconductor detectors for charged particles. The silicon detectors developed and manufactured at the Nuclear Research Institute (of Czechoslovakia) have excellent linearity into the 12 Mev proton energy range, and an energy resolution not inferior to 0.6%. Laboratories equipped with these silicon detectors could simplify their experimental methods appreciably, and effect an increase in the accuracy of their measurements. The last session also discussed the problem of improving avenues of scientific information exchange between the institutes of the various member-nations of the Joint Institute. 932 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 BIBLIOGRAPHY NEW LITERATURE Books and Symposia Translated from Atomnaya Energiya, Vol. 11, No. 3, pp. 287-294, September, 1961 J. Bowen, E. Neisters. Upravlenie yadernymi reaktorami: a translation of Nuclear Reactor Control published in Britain. Moscow, Gosatomizdat, 1961. 96 pages, 30 kopeks. The book reviews the basic parameters of the control system of gas-cooled uranium-graphite reactors. The effect of changes in reactivity and speed of coolant flow on reactor performance in different operating modes is described, and a method for studying transients by analog simulation is presented. Specifications for control components and loops are given. The concluding chapter contains a concise description of instruments for measuring neutron flux. The book is written for scientific and engineering personnel and technicians engaged in the design and operation of nuclear reactors, and for students majoring in nuclear engineering. P. Margen. Vybor optimal'nykh variantov v reaktorostroenii Abridged translation from the English. [Optimiza- tion of reactor design] Moscow, Gosatomizdat, 1961. 100 pages, 40 kopeks. This book is devoted to the timely question of the economics of nuclear electric power generating stations, to the optimization of power station parameters on the basis of an engineering economics analysis. The objects of analysis in this book are the reactor core, heat transfer and friction, and the thermodynamic cycle, which are approached in the context of a power station built around a gas-cooled reactor using heavy water moderator. The book contains six chapters. The first chapter outlines in popular style the procedure for the engineering costs analysis of the conductor carrying the current. Subsequent chapters provide the fundamental relationships for physical and thermal core calculations and for calculating the thermodynamic cycle of the station. A procedure is considered for optimizing core parameters and heat transfer parameters in a physical analysis, and some considerations on the proper choice of thermodynamic cycle for a nuclear power station are outlined in brief. The appendices present formulae and tables needed for calculating optimum parameters for a nuclear power station. The book is written for nuclear power specialists engaged both in reactor core calculations and in the design of power engineering equipment, and for graduate students specializing in nuclear power engineering. V. L. Shashkin. Metody analiza estestvennykh radioaktivnykh elementov. Moscow, Gosatomizdat, 1961. 152 pages, 47 kopeks. [Methods of analysis of natural radioelements]. This book provides a review of radiometric and nucleonic methods in the analysis of elements in the uranium, radium, and actinium-uranium series in natural formations and in products of uraniferous and thoriferous ore processing. Characteristics of the radioactive properties of natural radioactive elements are given. Methods for the measurement of radioactive radiations are described, and techniques of analysis based solely on measurements of radioactive radiations are outlined. Methods for determination of uraniurn, thorium, protactinium, actinium, and polonium are presented, in addi- tion to the emanation methods of such vital importance in the determination of radium and radon isotopes. The principles of complex radiochemical analysis are elucidated. The list of useful literature references appended in- cludes 126 titles. The book is written for radiochemists and physicists working in the field of analysis of natural radioactive elements. It may also prove useful to students majoring in those topics. 933 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 I. NUCLEAR POWER PHYSICS NEUTRON AND REACTOR PHYSICS. PHYSICS OF HOT PLASMAS AND CONTROLLED FUSION. PHYSICS OF ACCELERATION OF CHARGE PARTICLES Doklady akad. nauk SSSR, 137, No. 4 (1961) B. N. Gershman 822-25. On some features of transverse propagatioh of microwaves in a magnetoactive plasma. Zhur. tekhn. fiz., XXXI, No. 6 (1961) Ya. B. Fainberg et al., 633-39. Note on the nature of instabilities in interactions between charged-particle beams and a plasma. V. S. Imshennik, Yu. I. Morozov, 640-49. Analysis of instability of a beam of charged particles in an electron plasma. M. D. Gabovich, I. M. Mitropan, 6-16-79. Observation of hydromagnetic oscillations in the plasma of a pulsed electrodeless discharge. Zhur. eksptl. i. teoret. 40, No. 5(1961) A. I. Morozov, L. Solov'ev, 1316-24. Kinetic examination of some plasma equilibrium configurations. P. S. Zyryanov, 1358-56. Quantum theory of acoustic oscillations of an electron-ion plasma in a magnetic field. Yu. N. Dnestrovskii, D. P. Kostomarov, 1404-10. On the dispersion equation for an ordinary wave propagating in a plasma at right angles to the externally applied magnetic field. M. T. Zhumartbaer, 1434-39. On the stability of magnetic tangential discontinuities in relativistic hydro- dynamics. Izvestiya akad. nauk SSSR, seriya fiz., 25, No. 4 (1961) A. K. Trofimov, 460-61 Luminescence of lanthanides in thorium oxide. B. S. Grebenskii et al., 500-503. On enhancing the efficiency of slow-neutron scintillation detectors. G. V. Gorshkov et al., 504-505. A disperse-phase-fast-neutron detector. Pribory i tekhnika elcsp., No. 2 (1961) S. Ya. Nikitin, 5-13. Modem techniques in processing bubble chamber plates. Yu. M. Khirnyi, L. N. Kochemasov, 14-19. Injector for negative hydrogen ions. 0. D. Kovrigin et al., 19-25. A double-focusing large beta-ray spectrometer. V. N. Lukashev, 26-34. Analysis of electron trajectories in an axial beta-ray spectrometer with centrally placed source. V. F. Litvin, 33-34. Double focusing over a broad energy range with the aid of sectored homogeneous magnetic ? fields. A. I. Veretennikov et al., 42-46. Gamma-ray spectrometer uses organic scintillator with time sampling of gamma radiation. M. I. Daion et al., 47-52. Spark-counter telescope in a magnetic field measures pulses of fast charged particles. A. M. Ratner, I. A. Rom-Krichevskaya, 53-62. Note on the theory of energy resolution in scintillation counters. A. E. Voronkov et al., 63-68. New instrument automatically scans nuclear emulsions by the TV raster method. I. Servo system. E. Fenyes et al., 68-72. Semiautomatic measuring instrument for processing bubble chamber plates and Wilson chamber plates. V. I. Strizhak, N. S. Nazarov, 72-75. Neutron generators. V. N. Bochkarev, V. V. Nefedov, 80-81. Scintillation detector for separately recording heavy and light ionized particles. N. A. Vitbvskii et al., 82-83. Silicon n-p-counters for heavy charged particles operate without supply sources. 934 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Amer. J. Phys., 29, No. 4 (1961) J. Solbrig, 257-61. Doppler effect in neutron resonance absorption. Amer. J. Phys., 29, No. 5 (1961) C. Ananiades, J. Dewdney, 329. Alpha-particle semiconductor detector. Energia Nucleare, 8, No. 4 (1961) C. Galotto et al., 243-46. Design of photoneutron source and its calibration. Nucl. Energy, No. 156 (1961) - -, 199-200. Methods and equipment for training courses in nuclear physics. Nucl. Instrum. and Methods, 10, No. 4 (1961) D. Caro, J. Rouse, 249-58. The variable-energy cyclotron at Melbourne University. G. Wilson, 259-62. Phase variations near the center of a cyclotron. G. Kelley et al., 163-71. Source of high constant ion currents. I. Myers, H. Larson, 281-88. Precision instruments for monitoring beams in electron accelerators. R. Glover et al., 343-47. Telescopic counter system for fast-neutron experiments. H. Grassier, K. Tesch, 353-55. Detection efficiency of a plastic scintillator for neutrons in the 1-14 Mev energy range. Nuovo Cimento, XIX, No. 6 (1961) H. Carvalho et al., 1131-41. Angular distribution of uranium photofission fragments. Techn, Digest, III, No. 6 (1961) - -, 48-50. Microscope for measuring nuclear particle tracks. II. NUCLEAR POWER ENGINEERING NUCLEAR REACTOR THEORY AND CALCULATIONS. REACTOR DESIGN. PERFORMANCE OF NUCLEAR REACTORS AND POWER STATIONS Atompraxis, 7, No.4 (1961) H. Bildstein, P. Koss, 126-28. The ASTRA reactor fuel elements. W. Cawley, 131-35. Problems in load transfer of fuel elements. H. Benzler, 135-41. Power engineering problems in a gas-cooled reactor. H. Schudi, 142-46. Approximate calculation of optimal pitch in uranium lattices. Atompraxis, 7, No. 5 (1961) J. Stohr, 189-93. Fuel elements for graphite-moderated reactors using pressurized-0O2 coolant. Energia Nucleare, 8, No. 4 (1961) G. Zorzoli, 255-60. Theoretical investigations and experimental results obtained for critical assemblies with moderator of organic fluid and water. F. Castelli, 161-69. The Enrico Fermi nuclear power station. 935 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 I. Bachmann, 270-75. Experience of the first stages of operation of the Yankee Atomic reactor. M. Covino, R. Lepore, 176-87. Details of the planning and development of the Garigliano nuclear power station. Ji.dern-a Energie, 7, No. 5 (1961) - -, 158-66. Physics of heavy-water reactor lattices. Kernenergie, 4, No. 4 (1961) W. Fratzscher, R. Nitsch, 269-75. Evaluation of heterogeneous reactors from the standpoint of thermodynamic potential. A. Sydow, 276-84. The UNIMAR analog computer in nucleonics programs. Kernenergie, 4, No. 5 (1961) H. Hessel, 384-90. Note on the problem of constant burnup in pressurized-water reactors. Nucl. Energy, No. 156 (1961) - -, 201 The NESTOR neutron source reactor - -, 202-204. The Sizewell nuclear power station. B. Link. Clark, 205-209. Model of an experimental reactor for studying heat transfer. - -, 209. Reloading mechanism of the AGR reactor. Ncul. Engn., 6 No. 61 (1961) - - , 239-52. Maritime heavy water reactor with steam cooling system. Nucl. Power, 6, No. 62 (1961) J. Collier, 61-66. Fuel burnup in liquid-cooled reactors. 1. - -, 70. Thermocuples for elevated temperatures. S. Hollands, 78-79. The export policy of the USA in the nuclear power field. Nucl. Sci. and Engng., 9, No. 4 (1961) C. Orth, 417-20. Diffusion of lanthanides and actinides from graphite at high temperatures. G. Smith et al., 421-29. Experimental investigation of resonance capture of neutrons by U238 in UO2 fuel elements. D. Parks, 430-41. Effect of motion of atoms on thermalization of neutrons. G. Boyd, et al., 442-54. Flow transients in a multiloop reactor system. E. Hellstrand, J. Weitman, 507-18. The resonance integral for thorium in the form of metallic rods. Nucleonics, 19, No. 6 (1961) D. Keller, 45-48. Calculating fuel burnup for stainless-clad UO2. F. Boni, P. Otten, 58-61. Steam generators for the Enrico Fermi power station and the Hallam nuclear power station. A. DeStordeur, '74 ff. Drag coefficients for remote-controlled components between fuel elements. Nucleonik, 3, No. 2 (1961) P. Weissglas, 54-57. Theoretical calculation of effect of lattice parameters on destruction of coolant channels in a natural-uranium burner with heavy water moderator and coolant. E. Kern, A. Schatz, 61-76. Diffusion of radioactive substances in solids of grainy structure. W. Hage, L. Cameron, 76-80. Iterative solution of a system of kinetic reactor equations for a rod drop experi- ment. E. Eberth, W. Oldekop, 80-83. Two-group diffusion theory for a finite heterogeneous pebble-bed reactor. P. Ahlstrom, P. Weissglas, 83-85. Spatial variations in concentration of isotopes in a fuel element rod. 936 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Reactor Sci. and Tech., 14, No. 1 (1961) W. Blackburn, 1-8. Deflection of fuel elements in assembly due to creep. M. Reier, J. De Juren, 18-24. Diffusion length of thermal neutrons in water over the 23-244?C temperature range. L. Blake, 31-48. Extensive fuel burnup in fast reactors. R. Bertrand, 49-50. Determination of Pung content in a specimen of spent natural uranium, with the aid of an alpha spectrometer. D. Popplewell, 50-51. Specific a-activity and half-life of U233 . J. Adam, M. Rogers, 51-52. Use of x-ray diffraction in the study of fission-fragment damage to uranium carbide and uranium nitride. III. NUCLEAR FUEL AND MATERIALS NUCLEAR GEOLOGY AND PRIMARY ORE TECHNOLOGY. NUCLEAR METALLURGY AND SECONDARY ORE TECHNOLOGY. CHEMISTRY OF NUCLEAR MATERIALS. Doklady akad. nauk SSSR, 137, No. 3 (1961) Yu. B. Pademo, G. V. Samsonov, 646-47. Electrical properties of hexaborides of alkali and rare-earth metals and thorium. Zhur. neorgan. khim., 6, No. 4 (1961) 0. L. Kabanova, 786-89. Complexing of plutonium (V) and EDTA. I. I. Chernyaev et al., 790-98. On the complex nature of uranyl peroxide compounds. A. V. Nikolaev, S. M. Shubina, 799-803. Nature of the linkage in complexes of uranyl nitrate and butyl- phosphate compounds, from IR absorption spectra. 0. E. Zvyagintsev, L. G. Khromenkov, 874-82. On complexes between thorium and tartaric acid. Chung Huang-Bang, P. I. Fedorov, 971-76. The ternary system thorium sulfate?sodium sulfate?water. G. A. Polonnikova, L. V. Utkina, 1001-1003. On ammonium uranyl sesquicarbonate. Zhur. fiz. khim., 35, No. 3 (1961) L. M. Kovba et al., 563-68. Study of the crystalline structure of uranates. I. Uranates containing tetragonal layers of (UO2)02. D. A. Knyazev, 612-19. Calculating separation coefficients of isotopes in ion exchange. Zavod. lab., 27, No. 5 (1961) V. B. Spivakovskii et al., 390-91. Determination of traces of uranium in rocks and natural waters. Radiokhimiya, 3, No. 2 (1961) V. B. Shevchenko, V. S. Shmidt, 121-28. Extraction of ruthenium and several other fission products by tri-n- octylamine from nitrate solutions. V. B. Shevchenko et al., 129-36. Extraction of uranium (VI) and (IV) from chloride solutions by the diisoamyl ether of methylphosphonic acid. S. Mints, A. Ugnevskaya, 137-43. Effect of salting-out agents on extraction of uranyl nitrate by cyclohexane. I. E. Stank et al., 151-54. Study of the state of protactinium in aqueous solution. IV. Ion exchange method. V. I. Grebenshchikova, Yu. P. Davydov, 155-64. Study of the state of Pu(IV) in dilute solutions of nitric acid. V. I. Grebenshchikova, Yu. P. Davydov, 165-72. Adsorption of Pu(IV) on a glass surface. V. M. Vdovenko et al., 174-80. Vapor pressure above ether solutions of uranyl nitrate. 937 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 P. N. Palei et al., 181-86. Express extraction-photometric determination of uranium using arsenazo III reagent. V. M. Solntsev, Yu. M. Tolmachev, 187-94. Dissolution reaction of 1J808 in sulfuric acid. I. On the kinetics of some reactions with powders. J. Maly et al., 195-98. Reaction of plutonium dioxide with ammonium hydrogen fluoride in the absence of water. K. K. Aglintsev, 237-39. Determination of effective age of fission fragments. V. F. Luk'yanov et al., 239-40. Analytic chemistry of thorium, III. Photometric determination of thorium using arsenazo III in natural materials. Fizika metallov i metallovedenie, 11, No. 3 (1961) V. N. Strekalovskii et al., 400-403. Phase transformations in reduction and oxidation processes of uranium oxides. Atompraxis, 7, No. 4 (1961) J. Robertson, 121-26. UO2 fuel elements. B. Baines, 128-31. High-density graphite. Canad. Mining and Metallurg. Bull., 53, No. 583 (1960) (1961) W. Evans, 893-900. Metallurgy of highly reactive materials. Kernenergie, 4, No. 5 (1961) K. Helbig, 291-92. Determination of error in absolute activity measurements of specimens by the coincidence method. Kemenergie, 4, No. 5 (1961) J. Fialkowski, R. Plejewski, 391-94. Spectrographic analysis of radioactive slurries. Mining and Chem. Engn. Rev., 53, No. 6 (1961) - -, 57-59, Processing of uranium ores. Nucl. Energy, No. 156 (1961) M. McQuillan, T. Farthing, 195-97. Beryllium. 0. Joklik, 211-20. Radiation polymerization of methylmethacrylate. Nucl. Power, 6, No. 62 (1961) G. Llewelyn, R. Allardice, 71-76. Experience in processing enriched fueld elements. 0. Plail, 81-82. Methods of irradiating fissile materials. 6. Nucl. Sci. and Engng., 9, No. 4 (1961) F. Sicilio et al., 455-61. Decontamination of irradiated tributyl phosphate by distillation in a kerosene-type solvent. J. Keyes, A. Krakoviak, 462-74. Niconel fatigue at 768? C due to high-frequency temperature oscillations. G. Seaborg, 475-87. The transuranium elements. T. Gens, 488-94. What's new in the processing of uranium-zirconium alloy fuel. J. Williams, C. Huffine, 500-506. Electrolysis of yttrium metal in the solid state. 938 Nucleonics, 19, No. 6 (1961) D. Worlton, 80-82. Ultrasonic testing of uranium slugs. J. Bates, 83-85. Improving high-temperature thermal conductivity. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 'J Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 IV. NUCLEAR RADIATION SHIELDING RADIOBIOLOGY AND RADIATION HYGIENE. SHIELDING THEORY AND TECHNIQUES. INSTRUMENTATION Agrobiologiya, No. 2 (1961) I. M. Vasil'ev, 259-69. Effect of ionizing radiations on plants. Byul. Kirgiz. nauchno-issled. inst. zemledeliya, No. 5 (1960) Ta. A. Ivanov, B. N. Kulikov, 43-46. Effect of irradiation of seeds by radioactive cobalt on the growth, de- velopment, and crop yield of wheat and barley. Zhur. Vsesoyuz. khim. ob-va im. Mendelleeva, 6, No. 2 (1961) A. A. Kastal'skii, 193-99. Decontamination of sewage waters containing radioactive materials. Izvestiya vyssn. ucheb. zaved. Lesnoi zhur., No. 1 (1961) A. D. Tarabarin, 37-39. Uptake of P82 by mycorrhizic and nonmycorrhizic oaklets in relation to preliminary phosphate treatment. Izmerit. teldmika, No. 4 (1961) M. R. Yudin, 0. A. Filippov, 37-42. Tissue-equivalent fast-neutron dosimeter. V. S. Merkulov, 61-63. Soviet radioisotope-based instrumentation. Pribory i tekhnika eksper.. No. 2 (1961) M. Ya. Balats et al., 171. Fabrication of plastic scintillators by the press method. Radiobiologiya, 1, No. 1 (1961) L. P. Breslavets et al., 128-34. Changes in pollen grains in rye plants exposed to continuous gamma bombardment. N. M. Berezina, V. A. Yazykova, 135-38. Significance of disturbance to metabolic reactions in radiation damage to seeds (of the corn plant). G. V. Radzievskii, 141-48. Dosimetry for external alpha radiation. Radiokhimiya, 3, No. 2 (1961) Yu. A. Kototov et al., 199-206. Sorption of long-lived fission products by soils and clayey minerals. Atompraxis, 7, No. 5 (1961) J. Baarli, K. Madshus, 167-70. Analysis of background radiation in the 0.08-1.7 Mev range measured by a scintillation counter. R. Tzschaschel, 170-72. Gamma-spectrometric investigation of fallout specimens by the gray wedge method. H. Munzel, M. Hollstein, 177-78. Effect of shape of loop on the counting characteristics of a methane flow- type counter. H. Scharpenseel, 178-81. Effect of several material parameters on measuring efficiency in liquid scintillation spectrometry. Energia Nucl., 8, No. 4 (1961) A. Persano et al., 287-94. Calculating safety factors and radiological shielding for nuclear power stations. 939 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Health Phys. 5, Nos. 1-2 (1961) - 1-19, Suggested rules for radiation shielding. E. Wagner, G. Hurst, 20-26. GM gamma dosimeter with low neutron sensitivity. G. Brownell et al., 27-36. Large plastic scintillators for radioactivity measurements. P. Harris, 37-44. Irradiation dose determination in an accident due to criticality at the Los Alamos laboratories In 1958. M. Randloph et al., 24-29. Decay of polonium-beryllium fast-neutron sources. E. Ray, S. Hammond, 50-56. Use of alpha-pulse amplitude analyzer in dosimetric monitoring of surroundings. E. Gupton et al., 57-62. Use of flat film badge at ORNL in criticality accidents. A. Broido, J. Teresi, 63-69. Study of hazard associated with radioactive fallout. I. Determination of gamma and beta dosage. D. Gardiner, K. Cowser, 70-78. Removal of radioisotopes from low-activity industrial wastes. P. Zigman, J. Mackin, 79-84. Premature decay of fission product mixtures. II. Rates of liberation of gamma- energy and ionization in response to fissioning of U235 by thermal neutrons. Health Phys., Nos. 3-4 (1961) W. Lacy, 228-32. Some problems in deep-pit disposal of radioactive wastes. H. Larson, 233-35. Pocket dosimeter counter. C. Bernard et al., 236-43. Silver metaphosphate glass for x-ray measurements in fields of neutron and gamma radiation. E. Tochilin, R. Golden, 244-249. Investigation of relative sensitivity of photographic emulsions to beta and gamma radiation. L. Stephens et al., 267-74. Radioactive fallout and natural background radiation in the Sna Francisco Bay area. J. Teresi, C. Newcombe, 275-88. Calculation of maximum tolerance concentrations of radiactive fallout in water and air. D. Summers, M. Gaske, 289-92. Maximum tolerable activity of fission products in air and water. M. Rankin, 293-98. Air alpha activity badge. F. Bradley, 298-301. Use of electrometer with vibrating-reed sensor as alpha counter. B. Wheatley, 301-302. Integrating dosimeter with ionization chamber. E. Geiger et al., 302-304. Simplified method for alpha-emitter autoradiography. H. Wyker, 309-11. Maximum tolerable concentration of nonidentified radioisotopes in water. R. Rosen, 311. Method for evaporating water fallout samples. 940 Jaderna Energie, 7, No. 5 (1961) V. Stach, 146-50. Safety factors for overheating in fuel elements. Kernenergie, 4, No. 4 (1961) R. Reichel, 285-90. Study of de-excitation time in liquid organic scintillators. Nucl. Power, 6, No. 62 (1961) D. Brocardo, 67-69. Safety and reliability of scram circuits. 1. Nucleonics, 19, No. 6 (1961) P. Berry 62. Attenuation coefficients for gamma radiation. P. Wickersham, L. Ostwald, 66 ff. Microwave detector for measuring thermal neutron flux. Nukleonik, 3, No. 2 (1961) M. Bormann et al., 85-92. Particle discrimination with the aid of scintillation detectors. Radiation Res., 14, No. 3 (1961) L .Skargard ,H .Johns, 231-60. Spectral flux density of scattered and primary radiation at 250 kv. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 L. Skarsgard et al., 261-80. Correction for iterative characteristics of.a scintillation spectrometer. N. Barr et al., 291-95. Use of Fricke dosimeter for measuring photoelectric absorption. Radiation Res., 14, No. 4 (1961) A. Boni, 374-80. Polyacrylamide gamma dosimeter. V. RADIOACTIVE AND STABLE ISOTOPES TRACER TECHNIQUES. USES OF RADIOACTIVE RADIATIONS. DIRECT CONVERSION Avtomob. dorogi, No. 4 (1961) V. G. Firstov, 22-23. Radiometric sensing of compacting of roadbed. Vestnik akad. nauk Kazakh. SSR, No. 3 (1961) V. I. Ryaldiovskii, 107-108. Nuclear radiations for disinfection of fur and leather raw materials. Gazovaya prom., No. 4 (1961) [Gas industry] V. A. Astakhov et al., 10-14. Automatic radioactive condensate bleed, type AKO-1. Doklady akad. nauk SSSR, 137, No. 4 (1961) I. N. Plaksin et al., 880-81. Neutron activation analysis applied to determination of tungsten content in minerals and beneficiation products. Doklayd akad. nauk Uzbek. SSR, No. 3 (1961) V. P. Vasil'ev. Study of intermediate layer of an oxide cathode, with the aid of radioactive tracers. Zavod. lab., 27, No. 4 (1961) V. N. Fainberg, 411-13. Gamma-ray flaw detection of thick-walled parts by means of a scintillation counter. Izvestiya akad. nauk Eston. SSR. Seriya fiz.-matem. i tekhn. nauk, 10, no. 1 (1961) A. I. Karpov. 75-81. Experimental investigation of speed of particles and resistances in pneumatic conveying by the tracer method. Kozhev.-obuvnaya prom.,:No. 2 (1961) [Shoe and leather industry] I. A. Mad, E. P. Mediis, 12-13. Radioactive instrumentation in extractive industry. Razvedka i okhrana nedr, No. 3 (1961) A. A. Ya. Doronin, 44-45. Experience in the use of radioactive techniques for delineating tectonic zones. Sb. nauchno-issled. inst. osnovanii i podzemnykh sooruzh. akad. stroit. i arkhitek. SSSR, No. 43 (1961) D. E Pol'shin , Hsi Chung-Han, 5-12 Gamma-ray method for investigating a planar field of soil density. 941 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Trudy Vsesoyuz. nauchno-issled. inst. veterar. sanitarii, 17 (1960) V. I. Rogachev et al., 171-76. Ionizing radiations applied to the preservation of meats and meat products. Trudy Moskv. energet. inst., No. 34 (1961) N. N. Yakimov, L. G. Sherstnev, 315-22. Tracer studies of diffusion processes in an oxide cathode. Trudy nauchno-issled. inst. asbesta, slyudy, asbestotsementnykh izdelii i proetktr. stroit. predpriyatii slyudyanoi prom., No. 11 (1961) [mica and asbestos research] M. G. Egorov, L. A. Sukhova, 114-18. Determination of B208 in synthetic boron micas, by the neutron absorption method. Appl. Radiation and Isotopes, 10, Nos. 2-3 (1961) J. Dale et al., 65-71. Ion chamber for measuring t3- and y -radiation of standard radioactive preparations. I. Possible applications and calibration. J. Dale, 72-78. Ion chamber for measuring B - and y -radiation of standard radioactive preparations. II. Instrument response to gamma radiation. F. Carleton, H. Roberts, 79-85. Determination of specific activity of tritium-labeled compounds on paper chromatograms with a servomechanism. J. Puig, J. Dobo, 112-15. Radiochemical grafting by irradiation at low temperatures. R. Platzman, 116-27. Total ionization of gases by high-energy particles. H. Otto, M. Winand, 128-31. Sampling system for high-intensity gamma sources. 942 Atompraxis, 7, No. 6 (1961) W. kolb, 146-50. Gamma radiography in boiler construction. Jadema Energie, 7, No. 5 (1961) B. Dolezel, 151-58. Effect of ionizing radiations on polymers. Nucl. Engn., 6, No. 61 (1961) P. Barrett et al., 230-32. Pulsed neutron sources. Nucleonics, 19, No. 6 (1961) B. Scott, W. Driscell, 48-52. Radiometric chemical analysis in automatic process control. J. Cameron, J. Rhodes, 53-57. Radioactive sources in x-ray spectrometry. - -, 88-89. A vessel with a seed irradiation facility. T. Gregson et al., 90-93. Measurement of age of industrial components by the radioactive dating technique. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 ENGINEERING AND PHYSICS JOURNAL INZHENERNO - FIZICHESKII ZHURNAL THE JOURNAL COMES OUT MONTHLY IN TWELVE PRINTED FOLIOS. The burden of the Journal's contents concerns scientific problems of deep significance for modern engineering. In particular, the Journal publishes the results of theoretical and experimental physical research in the area of heat and thermodynamics (heat exchange and mass balance, thermal conductivity theory, thermodynamics, physics Of combustion, theory of dessication), physics of structural materials (soil mechanics, structural-mechanical and rheo- logical characteristics of disperse media, heat transport in structural materials and enclosing structures), the ther- modynamics of irreversible processes and its applications to transport phenomena in the presence of phase trans- formations, chemical transformations, and nuclear transmutations, as relates to technological processes. The Journal will also publicize engineering and technical methods for the solution of scientific and engineering problems. The basic task of the Journal is to aid to the maximum the assimilation of the results of scientific physics re- search into actual engineering practice, to contribute to closer coordination of the efforts of physicists and engineers alike, as well as designers, in industrial enterprises and in-plant laboratories. The Journal publishes articles and short notes, and contains the features: book review and current bibliography, chronicle of outstanding events in the scientific life and activities of the USSR and other nations, a section of re- view articles on the timeliest aspects of modem science and engineering. The readership of the Journal embraces broad circles of scientific workers, professorial and educational institute staffs, graduate students, undergraduates, engineers and technicians, workers in designing, drafting, and planning units, and in-plant laboratories. Subscriptions to the Engineering and Physics Journal will be processed by all municipal and district subsections of Soyuzpechat', by communications offices and sections, and by all persons authorized for subscription, processing in industrial enterprises, scientific institutions, and schools. The subscription price is set at 8 rubles, 40 kopeks annually, 4 rubles 20 kopeks per half-year. 943 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Soviet Journals Available in Cover-to-Cover Translation ABBREVIATION AE Akust. zh. Astr(on). zh(urn). Avto(mat). svarka Byull. eksp(erim). biol. i med. DAN (SSSR) Dokl(ady) AN SSSR Derevoobrabat. prom-st'. ntom(o1). oboz(renie) Farmakol. (i) toksikol(ogiya) FMM Fiziol. zhurn. SSSR (im. Sechenova) Fiziol(ogiya) rast. FTT lzmerit. tekh(nika) lzv. AN SSSR, 0(td). Kh(im). N(auk) RUSSIAN TITLE TITLE OF TRANSLATION Atomnaya energiya Soviet Journal of Atomic Energy Akusticheskii zhurna) Soviet Physics ? Acoustics Anti biotiki Antibiotics Astronomicheskii zhurnal Soviet Astronomy?AJ Avtomaticheskaya svarka Automatic Welding Avtomatika i Telemekhanika Automation and Remote Control Biofizika Biophysics Biokhimiya Biochemistry Byulleten' eksperimentarnoi biologii Bulletin of Experimental i meditsiny Biology and Medicine Doklady Akademii Nauk SSSR The translation of this journal is published in sections, as follows: Doklady Biochemistry Section Doklady Biological Sciences Sections (Includes: Anatomy, biophysics, cytology, ecology, embryology, endocrinology, evolutionary morphology, genetics, histology, hydrobiology Life Sciences microbiology, morphology, parasitology, physiology, zoology sections) _ Doklady Botanical Sciences Sections (Includes: Botany, phytopathology, plant anatomy, plant ecology, plant embryology, plant physiology, plant morphology sections) 1 Proceedings of the Academy of Sciences of the USSR, Section: Chemical Technology Chemical Sciences Proceedings of the Academy of Sciences of the USSR, Section: Chemistry Proceedings of the Academy of Sciences of the USSR, Section: Physical Chemistry Doklady Earth Sciences Sections (Includes: Geochemistry, geology, geophysics, hydrogeology, mineralogy, paleontology, petrography, permafrost Earth Sciences sections) Proceedings of the Academy of Sciences of the USSR, Section: Geochemistry Proceedings of the Academy of Sciences of the USSR, Sections: Geology Mathematics Doklady Soviet Mathematics Soviet Physics?Doklady (Includes: Aerodynamics, astronomy, crystallography, cybernetics and control theory, electrical engineering, energetics, fluid mechanics, heat engineering, hydraulics, mathematical physics, Physics mechanics, physics, technical physics, theory of elasticity sections) Proceedings of the Academy of Sciences of the USSR, Applied Physics Sections (does not include mathematical physics or physics sections) Derevoobrabatyvayushchaya Wood Processing Industry ' promyshlennost' Clecktrosvyaz Telecommunications Entomologicheskoe obozrenie Entomological Review Farmakologiya i toksikologiya Pharmacology and Toxicology Fizika metallov i metallovedenie Physics of Metals and Metallography Fiziologicheskii zhurnal im. I. M. Sechenova Sechenov Physiological Journal USSR Fiziologiya rastenii Plant Physiology Geokhimiya Geochemistry Fizika tverdogo tele Soviet Physics?Solid State lzmeritel'naya tekhnika Measurement Techniques lzvestiya Akademii Nauk SSSR: Bulletin of the Academy of Sciences Otdelenie khimicheskikh nauk of the USSR: Division of Chemical Sciences PUBLISHER Consultants Bureau American Institute of Physics Consultants Bureau American Institute of Physics British Welding Research Association (London) Instrument Society of America National Institutes of Health* Consultants Bureau Consultants Bureau American Institute of Biological Sciences American Institute of Biological Sciences American Institute of Biological Sciences Consultants Bureau Consultants Bureau Consultants Bureau American Geological Institute Consultants Bureau Consultants Bureau The American Mathematics Society American Institute of Physics Consultants Bureau Timber Development Association (London) Massachusetts Institute of Technology* American Institute of Biological Sciences Consultants Bureau Acta Metallurgica* National Institutes of Health* American Institute of Biological Sciences The Geochemical Society American Institute of Physics Instrument Society of America Consultants Bureau TRANSLATION BEGAN Vol. Issue Year 1 1 1956 1 1 1955 4 1 1959 34 1 1957 1 1959 27 1 1956 1 1957 21 1 1956 41 1 1959 106 1 1956 112 1 1957 112 1 1957 106 1 1956 106 1 1956 112 1 1957 124 1 1959 106- 1 1957- 123 6 1958 106- 1 1957- 123 6 1958 131 1 1961 106 1 1956 106- 1 1956- 117 1957 9 1959 1 1957 38 1 1959 20 1 1957 5 1 1957 1 1957 4 1 1957 . 1 1958 1 1 1959 1 . 1959 1 1952 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 _ Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 continued lzv. AN SSSR, 0(td). T(ekhn). N(auk): Met(all). i top. lzv. AN SSSR Ser. fiz(ich). lzv. AN SSSR Ser. geofiz. lzv. AN SSSR Ser. geol. Kauch. i rez. Kolloidn. zh(urn). Metalov. i term. obrabot. metal. Met. i top. Mikrobiol. OS Pribory i tekhn. eks(perimenta) Prikl. matem. i mekh. PTE Radiotekh. Radiotekh. i elektronika Stek. i keram. Svaroch. proiz-vo Teor. veroyat. i prim. Tsvet. Metally UFN UKh UMN Usp. fiz. nauk Usp. khim(ii) Usp. matem. nauk Usp. sovr. biol. Vest. mashinostroeniya Vop. gem. i per. krovi Vop. onk. Vop. virusol. Zav(odsk). lab(oratoriya) ZhAKh Zh. anal(it). khimii ZhETF Zh. eksperim. i teor. fiz. ZhFKh Zh. fiz. khimii ZhMEI Zh(urn). mikrobiol. epidemiol. i immunobiol. ZhNKh Zh(urn). neorganfich). ZhOKh Zh(urn). obshch(ei) khimii ZhPKh Zh(urn). prikl. khimii ZhSKh Zh(urn). strukt. khimii ZhTF Zh(urn). tekhn. fiz. Zh(urn). vyssh. nervn. deyat. (im. Pavlova) I. V iiee Met. i top.) lzvestiya Akademii Nauk SSSR: Seriya Bulletin of the Academy of Sciences fizicheskaya lzvestiya Akademii Nauk SSSR: of the USSR: Physical Series Bulletin (lzvestiya) of the Academy of Columbia Technical Translations 1 1954 Seriya geofizicheskaya lzvestiya Akademii Nauk SSSR: Sciences USSR: Geophysics Series lzvestiya of the Academy of Sciences of the American Geophysical Union 1 1954 Seriya geologicheskaya USSR: Geologic Series American Geological Institute 1 1958 Kauchuk i rezina Soviet Rubber Technology Research Association of British Rubber Manufacturers 18 1 1959 Kinetika i kataliz Kinetics and Catalysis Consultants Bureau 1 3 1960 Koks i khimiya Coke and Chemistry USSR Coal Tar Research Association (Leeds, England) 1 1958 Kolloidnyi zhurnal Colloid Journal Consultants Bureau 14 1 1952 Kristallografiya Soviet Physics ? Crystallography American Institute of Physics 2 1 1957 Metallovedenie i termicheskaya Metal Science and Heat Treatment of obrabotka metallov Metals Acta Meta I lurgica 6 1 1958 Metallurg Metallurgist Acta Metallurgica 1 1957 Metallurgiya i topliva Russian Metallurgy and Fuels Eagle Technical Publications 1 1960 Mikrobiologiya Microbiology American Institute of Biological Sciences 26 1 1957 Optika i spektroskopiya Optics and Spectroscopy American Institute Of Physics 6 1959 Pochvovedenie Soviet Soil Science American Institute of Biological Sciences 1 1958 Priborostroenie Instrument Construction British Scientific Instrument Research Association 1 1959 Pribory i tekhnika eksperimenta Instruments and Experimental Techniques Instrument Society of America 1 1957 Prikladnaya matematika i mekhanika Applied Mathematics and Mechanics American Society of Mechanical (see Pribory i tekhn. eks.) Engineers 1 1958 Problemy Severa Problems of the North National Research Council of Canada Radiotekhnika Radio Engineering Massachusetts Institute of Technology* 12 1 1957 Radiotekhnika i elektronika Radio Engineering and Electronics Massachusetts Institute of Technology* 2 1 1957 Stanki i instrument Machines and Tooling Production Engineering Research Assoc. 1 1959 Stal' Stal (In English) Iron and Steel Institute 1 1959 Steklo i keramika Glass and Ceramics Consultants Bureau 13 1 1956 Svarochnoe proizvodstvo Welding Production British Welding Research Association 4 1959 Teoriya veroyatnostei i ee primenenie Theory of Probability and Its Applications Society for Industrial and Applied Mathematics 1 1956 Tsvetnye metally Nonferrous Metals Primary Sources 1 1960 Uspekhi fizicheskikh Nauk Soviet Physics ? Uspekhi (partial translation) American Institute of Physics 66 1 1958 Uspekhi khimii Russian Chemical Reviews The Chemical Society (London) 1 1960 Uspekhi matematicheskikh nauk (see UFN) (see UKh) (see UMN) Russian Mathematical Surveys London Mathematical Society 15 1 1960 Uspekhi sovremennoi biologii Russian Review of Biology Oliver and Boyd 48 1959 Vestnik mashinostroeniya Russian Engineering Journal Production Engineering Research Assoc. 4 1959 Voprosy gematologii i perelivaniya krovi Problems of Hematology and Blood Transfusion National Institutes of Health* 1 1957 Voprosy onkologii Problems of Oncology National Institutes of Health* 1 1957 Voprosy virusologii Problems of Virology National Institutes of Health* 1 1957 Zavodskaya laboratoriya Industrial Laboratory Instrument Society of America 25 1 1959 Zhurnal analiticheskoi khimii Journal of Analytical Chemistry USSR Consultants Bureau 7 1 1952 Zhurnal eksperimentarnoi i theoreticheskoi fiziki Soviet Physics?JETP American Institute of Physics 28 1 1955 Zhurnal fizicheskoi khimii Russian Journal of Physical Chemistry The Chemical Society (London) 7 1959 Zhurnal mikrobiologii, epidemiologii i immunobiologii Journal of Microbiology, Epidemiology and Immunobiology National Institutes of Health* 1 1957 Zhurnal neorganicheskoi khimii The Russian Journal of Inorganic Chemistry The Chemical Society (London) 1 1959 Zhurnal obshchei khimii Journal of General Chemistry USSR Consultants Bureau 19 1 1949 Zhurnal prikladnoi khimli Journal of Applied Chemistry USSR Consultants Bureau 23 1 1950 Zhurnal strukturnoi khimii Journal of Structural Chemistry Consultants Bureau 1 1 1960 Zhurnal teknicheskoi fiziki Soviet Physics?Technical Physics American Institute of Physics 26 1 1956 Zhurnal vysshei nervnoi deyatel'nosti (im. I. P. Pavlova) Pavlov Journal of Higher Nervous Activity National Institutes of Health* 1 1958 *Sponsoring organization. Translation through 1960 issues is a publication of Pergamon Press. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R00060007000171 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 SIGNIFICANCE OF ABBREVIATIONS MOST FREQUENTLY ENCOUNTERED IN SOVIET PERIODICALS FIAN Phys. Inst. Acad. Sc!. USSR GD! Water Power Inst. GITI State Sc!. -Tech. Press GITTL State Tech. And Theor. Lit. Press GONTI State United Sc!. -Tech. Press Gosenergoizdat State Power Press Goskhimizdat State Chem. Press GOST All-Union State Standard GTTI State Tech. and Theor. Lit. Press IL Foreign Lit. Press ISN (Izd. Soy. Nauk) Soviet Science Press Izd. AN SSSR Acad. Sc!. USSR Press Izd. MGU Moscow State Univ. Press LEITZhT Leningrad Power Inst. of Railroad Engineering LET Leningrad Elec. Engr. School LET! Leningrad Electrotechnical Inst. LETIIZhT Leningrad Electrical Engineering Research Inst. of Railroad Engr. Mashgiz State Sc!. -Tech. Press for Machine Construction Lit. MEP Ministry of Electrical Industry MES Ministry of Electrical Power Plants MESEP Ministry of Electrical Power Plants and the Electrical Industry MGU Moscow State Univ. MKhTI Moscow Inst. Chem. Tech. MON Moscow Regional Pedagogical Inst. MSP Ministry of Industrial Construction Nil ZVUKSZAPIOI Scientific Research Inst. of Sound Recording NIKFI Sc!. Inst. of Modern Motion Picture Photography ONTI United Sci.- Tech. Press OTI Division of Technical Information OTN Div. Tech. Sc!. Stroiizdat Construction Press TOE Association of Power Engineers TsKTI Central Research Inst. for Boilers and Turbines TsNIEL Central Scientific Research Elec. Engr. Lab. TsNIEL -MES Central Scientific Research Elec. Engr. Lab.-Ministry of Electric Power Plants TsVTI Central Office of Economic Information UF Ural Branch VIESKh All-Union Inst. of Rural Elec. Power Stations VNIIM All-Union Scientific Research Inst. of Metrology VNIIZhDT All-Union Scientific Research Inst. of Railroad Engineering VTI All-Union Thermotech. Inst. VZEI All-Union Power Correspondence Inst. NOTE: Abbreviations not on this list and not explained in the translation have been transliterated, no further Information about their significance being available to us. ?Publisher. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 ? RESEARCH BY SOVIET EXPERTS Translated by Western Scientists RADIATION CHEMISTRY s. . PROCEEDINGS OF THE FIRST ALL-UN1ON CONFERENCE MOSCOW 1957 More than 700 of the Soviet Union's outstanding research scientists participated in this conference sponsored by the Academy of Sciences and the Ministry of the Chemical Industry.' Each of the 56 reports read in the various sessions covers either the theoretical or practical aspects of radiation chemistry, and special attention is given to radiation sources used, in radiation-chemical investigations.. The general discussions which followed each report and -reflected various points of view on the problem under analysis are also included. PRIMARY ACTS IN RADIATION CHEMICAL PROCESSES $25.00 RADIATION CHEMISTRY OF AQUEOUS SOLUTIONS - (Inorganic and Organic Systems) $50.00 ? RADIATION ELECTROCHEMICAL PROCESSES ? $15.00 THE EFFECT OF RADIATION ON MATERIALS INVOLVED IN BIOCHEMICAL PROCESSES ? RADIATION CHEMISTRY OF SIMPLE ORGANIC SYSTEMS _ THE EFFECTOF RADIATION ON POLYMERS RADIATION SOURCES Individual volumes may be purchased separately. $12.00 $30.00 $25.00 $10.00 . Special price for the 7-volume set $125.00 Tables of contents uflon request. CONTEMPORARY_ EQUIPMENT , FOR WORK WITH RADIOACTIVE ISOTOPES Of the 110 isotopes produced in the USSR during 1958, 92 were obtained by neutron irradiation. The methods and technological procedures used in the production of isotopes and the preparation of labeled compounds from them are reviewed in detail. Shielding and manipulative devices for Work with radioactive isotopes are illustrated as well as described fully. These collected reports are of interest to all scientits and technologists.concerned with radioactive isotopes. - Tables of contents upon moues!. Durable paper covers 66 pp. illus. $15.00 PRODUCTION OF ISOTOPES The eighteen papers which comprise this volume were originally read at the All-Union Scientific and Technical Conference on the AppIication of Radio- active Isotopes, Moscow, 1957. The reports con- sider the ploblems and achievements of Soviet scientists in the production of radioactive isotopes by irradiation of targets in Soviet reactors and cyclotrons. ? Not only is this-work of Significance to producers of isotopes, but many_ of the papers will prove useful to isotope users as well. Tables of contents upon request. Durable paper covers 136 pp. illus. $50.00 ' Payment in sterling may be made to Barclay's Bank in London, England. CONSULTANTS BUREAU 227 West 17th Street ? New York H, N.Y. ? U.S.A. Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1 Now available. . . an insight into the Soviet problems and achievements in-. 4. PRODUCTION of ISOTOPES The eighteen papers which comprise this volume were originally read at the All-Union Scientific and Tech- nical Conference on the Application of Radioactive Isotopes, Moscow, 1957. The reports consider die problems and achievements of Soviet scientists in the production of radioactive isotopes by irradiation of targets in Soviet reactors and cyclotrons. Not only is this work of significance to producers of isotopes, but many of the papers will prove useful to isotope users as well. The Developthent, of Isotope Production in the USSR. Certain Aspects of the Production of Radioactive Iso- topes in a Nuclear Reactor. Production of Radioactive Isotopes in a 10-Mev Deu- teron Cyclotron. Determination of Product Yields in Nuclear Reactions. Spectrochemical Methods of Analyzing High-Purity Materials Used in Reactor Construction and for the Production of Radioisotopes. Quantitative Spectral Determination of Impurities in Radioactive Preparations. The Production of Alpha-. Beta-, and Gamma-Sources Using Oxide Films on Aluminum and Its Alloys. Stable ,Isotopes Enriched by the Electromagnetic Method. Ultrahigh-Temperature Ion Source for Electromag- netic Separation of Isotopes of Elements in the Platinum Group. Inhomogeneous Field Ivlass-Spectrometer for, Analy- sis of Light-Element Isotopes. The Relative Abundance of Palladium and Germanium Isotopes. Some Problems in the Theory of Isotope Separation. Separation of Isotopes of Light Elements by Diffusion in Vapors. A Diffusion Column for the Separation of Isotopes. A Fractionating Column for Preparing BF3 Enriched in the Isotope B16. An Investigation of the Separation of the Stable Iso- topes of Light Elements. The Separation of Carbon Isotopes. Low-Temperature Methods for Separating Helium Isotopes (He3 - fled). 1959 durable paper covers 136 pp., $56:00 CONSULTANTS BUREAU 227 WEST 17TH STREET NEW YORK 11 N Y Declassified and Approved For Release 2013/09/25: CIA-RDP10-02196R000600070001-1