SOVIET CLOUD PHYSICS RESEARCH AND WEATHER MODIFICATION ACTIVITIES

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06541158
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Approved for Release: 2018/01/30 006541158 N? 74 SCIENTIFIC INTELLIGENCE REPORT SOVIET CLOUD PHYSICS RESEARCH AND WEATHER MODIFICATION ACTIVITIES 1-)C ;�:' � , iL'\i V CT 1960 OSI�Z�SR/60-42 31 August 1960 CENTRAL INTELLIGENCE AGENCY OFFICE OF SCIENTIFIC INTELLIGENCE CONFIDENTIAL Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 WARNING This material contains information affecting the National Defense of the United States within the meaning of the espionage laws, Title 18, USC, �Secs. 793 and 794, the trans- mission or revelation of which in any manner to an unauthorized person is prohibited by law. Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 Scientific Intelligence Report SOVIET CLOUD PHYSICS RESEARCH AND WEATHER MODIFICATION ACTIVITIES NOTICE The conclusions, judgments, and opinions contained in this finished intelligence report are based on extensive scientific intelligence research and represent the final and consid- ered views of the Office of Scientific Intelli- gence. OSI�Z�SR/60-42 31 August 1960 CENTRAL INTELLIGENCE AGENCY OFFICE OF SCIENTIFIC INTELLIGENCE _ Approved for Release 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 �CONFIDENTE6:12 CLASSIFIED REFERENCES The classified source references supporting this paper are identified in a list published separately. Copies of the list are available to authorized personnel and may be obtained from the originating office through regular channels. Requests for the classified list of references should include the publication num- ber and date of this report. oN ES IEL, Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 PREFACE. The potential value of weather control or cloud modification has been recognized for well over a decade. Military require- ments exist for weather control techniques to support a variety of missions. The capability to disperse supercooled stratiform clouds and fog could be used, for example, to improve terminal weather for aircraft landing and take off, to provide close sup- port of ground operations, and to enable optical tracking of mis- siles. "Rainmaking" over airfields and battle fields conceivably could cause low visibility and be used as a method of warfare. Successful weather modification promises tremendous eco- nomic as well as military benefits. If clouds can be stimulated to produce rain at times critical for crop growth and if damaging hail storms can be suppressed, crops can benefit. Furthermore, the propaganda value of well-supported claims that techniques had been developed to control the weather are obvious. The popular press has given much publicity to weather con- trol experiments, usually indicating a degree of success not sup- ported by fact. At the present time no nation can produce evidence that they can control weather to any large degree, but certain successes have been achieved on a small scale in limited circumstances. Supercooled clouds and fog have been dissi- pated and precipitation probably has been increased somewhat from certain types of clouds. Considerable controversy still exists among competent scientists concerning the future of weather control. One group believes there is little likelihood that man will be able to control weather effectively within the foreseeable future. Another group believes that the advances in the relevant sciences in the past two decades have been so startling and rapid that it may be a mistake to assume success- ful weather control will not take place or to assume that it could occur only in the far distant future. Both groups agree that until scientists understand more completely the physics of clouds, precipitation mechanisms, and the larger scale energy processes of the atmosphere and ocean, the feasibility of con- trolling weather will remain in doubt. The status of Soviet research in cloud physics and weather control is stressed in this report, with most emphasis being placed on radar meteorology, the latter field supports both cloud physics research and the control or modification of weather. Climate control * has not been covered. The intelligence pre- sented herein is based primarily upon an external contract * Climate control is the term applied to schemes for artificially alter- ing or controlling the climate of a region. Weather control is the term applied to controlling day-to-day weather in contrast to changing the average weather over a long period of time. CONFIDENTIAL Approved for Release: 2018/01/30 006541158 111 Approved for Release: 2018/01/30 006541158 study by the Office of Scientific Intelligence, but earlier reports have also been brought up to date and the intelligence incor- porated in this report where essential. All pertinent informa- tion available through 1 June 1960 has been considered in writ- ing the report. iv �CONFIDENTIAL- Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 CnNFTTIRNTT AT. CONTENTS Page PREFACE iii PROBLEM 1 CONCLUSIONS 1 SUMMARY S 2 DISCUSSION 3 Organizations and Personnel Engaged in Cloud Physics and Weather Modification Research 3 Cloud Physics Research Activities 3 Radar Meteorology 4 Radar Equipment 5 Theoretical Work in Radar Meteorology 5 Application of Radar to Meteorology 6 Status of Soviet Radar Meteorology 6 Cloud Seeding and Weather Modification Research. 7 Cloud and Fog Dispersal 7 Seeding Reagents 8 Increasing Rainfall by Cloud Seeding 9 Seeding of Convective Clouds 9 Status and Trends of Soviet Weather Modification 10 GLOSSARY 13 APPENDIX A � Organizations and Personnel Engaged in Cloud Physics Research A-1 APPENDIX B � Leading Contributors to Soviet Cloud Physics Progress B-1 APPENDIX C � Bibliography of Articles Reviewed March 1959 to February 1960 C-1 APPENDIX D � Bibliography of Articles Identified but not Available for Complete Review D-1 REFERENCES R-1 6-439 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 _GGATLIzip.TNTTT AT FIGURES Following Page I.' Photo Kobal't Radar with 20-meter Antenna . . . . 8 2. Photo Italian Anti-Hail Rockets Being Prepared for Shipment to USSR ' 8 3. Photo Soviet Cloud Physics Research Instruments Mounted on Aircraft 8 4. Map Areas of Soviet Cloud Seeding Activity. . . 10 vi CONFIDENTIAL Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 FIDE SOVIET CLOUD PHYSICS RESEARCH AND WEATHER MODIFICATION ACTIVITIES PROBLEM To assess Soviet cloud physics research and weather modi- fication activities. CONCLUSIONS 1. The USSR is engaged in a large and comprehensive cloud physics and weather con- trol program, surpassing in size the program of the United States but slightly inferior in quality. Soviet scientists recognize the lack of basic knowledge in many important aspects of cloud physics and weather control and are aggressively working toward the solution of these problems. 2. The Soviets have developed a routine op- erational technology for dispersal of certain types of low-level clouds and fogs by cloud seeding at airports to facilitate flights by civil and military aircraft. They are conducting experiments to increase rainfall and suppress hailstorms for the benefit of agriculture. It is not likely that the Soviet Union has ad- vanced beyond the West in this area of weath- er control. On the other hand the Soviets have classified much of the research in these fields and probably have done more work than they have reported. 3. In the supporting field of radar meteor- ology, the Soviet Union is believed to lag be- hind the West, but will probably overcome this deficiency within the next few years. 4. The large size of the expanding Soviet cloud physics and weather modification re- search program and the large number of com- petent Soviet scientists available presage ad- vances such that the USSR will catch up with the West in the capability to modify weather within 5 years. Based on their plans and their estimated capability to achieve them, it is believed that Soviet scientists during the next 5 years will conduct their first experi- ments designed to control large-scale mete- orological processes, but their advances will be insufficient for them to control large-scale weather processes in an operational sense dur- ing this period. --eeisT-RDEN-TIAL 1 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 SUMMARY More than 30 Soviet institutes and organi- zations with more than 200 scientists are en- gaged in cloud physics and weather modifica- tion research. An analysis of Soviet man- power in this field indicates that the magni- tude of the program is Considerably larger than that of any Western country. Research in all areas of cloud physics is being pursued actively in the Soviet Union and plans include: (1) the strengthening of work in troposphere synoptics, microphysics of clouds and fog and their modification, cloud electrification and instrumentation for experiments; (2) the ex- pansion of studies of large-scale weather sys- tems through the use of aircraft soundings to high altitudes, (3) the broadening of at- mospheric chemistry research; (4) the broad- ening of theoretical generalization of experi- mental work; (5) the developing of new in- struments for atmospheric studies and the perfecting of rockets for use in studying high clouds; and (6) the establishing of a new periodical "Clouds and Precipitation," as well as semiannual seminars. Plans also are un- der way for an "All-Union Cloud Year" in 1962 to obtain detailed observations that will provide basic information to advance weather modification techniques. These plans sug- gest experiments to influence large-scale weather processes. Soviet cloud physics and weather modifica- tion research has been along lines similar to those pursued in other parts of the world with only minor differences in the level of achievement. Recently, the Soviets empha- sized studies of atmospheric electricity and the development of better instruments for cloud physics measurements. Only a few So- viet papers have shown an advanced approach to the use of radar for meteorological prob- lems, and this lack of positive evidence leads to the conclusion that the Soviet Union trails the West in applying the techniques of radar meteorology to cloud physics and weather modification research, even though the So- viets are highly capable in the field of radar and have air defense radar of excellent quality. For cloud physics research, they still use the ancient "Kobal't" radar that has character- istics long surpassed by weather-radar devel- opments in the West. The Soviets appar- ently classify some of their weather-radar re- search, for a number of papers have withheld from publication for several years and there are gaps in their literature that must be known to the Soviets from studying foreign journals. Any lag is likely to be eliminated in the next few years with the expanding So- viet research programs in cloud physics and weather modification. Cloud seeding research is also evidently clas- sified, for details are withheld from the scien- tific journals. Nevertheless, it is known that experiments with dry ice to dissipate low clouds and fog began in the USSR around 1950. Continued work in the area led to the USSR becoming in 1958 the first country to establish a routine procedure to clear airports of fog and low clouds by seeding techniques. The Soviets are continuing to use a variety of reagents and seeding techniques. In addi- tion to dry ice, other reagents, such as silver iodide and lead iodide, have been used in weather modification experiments. Aircraft, rockets, balloons, and tracer bullets have been used to carry the seeding reagent into the clouds. Many of these techniques have been used in the hail prevention program in south- ern USSR and the Caucasus. The Soviets have made a scientifically sound proposal that large amounts of silver iodide introduced in a cloud will prevent damaging hail, but have not demonstrated that they can accomplish this "overseeding" effectively. The Soviets have concluded that rainfall can be increased by seeding, but they have not reported the efficacy of their seeding. It is difficult to believe that they have not under- taken the necessary statistical tests to deter- mine the effectiveness of their seeding experi- ments; or that, as the gaps in the literature would indicate, they are not seeding winter storms or stratified orographic clouds, which provide promise of increasing rainfall. Prob- ably such experiments have been conducted but the results are classified and not available. 2 rONFIDENTIAL Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 CONFIDENTIAL DISCUSSION ORGANIZATIONS AND PERSONNEL EN- GAGED IN CLOUD PHYSICS AND WEATHER MODIFICATION RESEARCH The senior organization in the USSR charged with coordinating Soviet cloud phys- ics and weather modification research is the Coordinating Council on the Problem of Phys- ics of Clouds and Precipitation. This organi- zation was established in 1955 by the Presid- ium of the Academy of Sciences, USSR, and is a part of the Department of Physico-Math- ematical Sciences. Ye. K. Fedorov, Corre- sponding Member of the Academy of Sciences and director of the Institute of Applied Geo- physics, is chairman of the Coordinating Council. A number of research institutes and organizations operate under the general co- ordinating efforts of the council. The Coun- cil organizes interdepartmental conferences on cloud physics and weather control research at irregular intervals six conferences having been held to date. Besides sponsoring scien- tific conferences, the Coordinating Council re- ports to the appropriate Soviet research or- ganizations on cloud physics and weather modification work done in the Soviet Union and abroad. Members of the June 1959 con- ference resolved that the Council should in- tensify the work of reporting on the research done in the Soviet Union and abroad to im- prove its coordinating work., More than 30 Soviet institutes and organizations engaged in cloud physics and weather modification re- search have been identified (appendix A) . These include institutes of the Academy of Sciences, USSR, and the Academies of Sci- ences in certain of the Soviet republics, the universities, the weather service, and the armed forces.2 Three of the Soviet organi- zations have very large cloud physics and weather modification research programs, namely, the Institute of Applied Geophysics, the Main Geophysical Observatory, and the Central Aerological Observatory. These 3 or- ganizations are estimated to have 32, 69, and 30 scientists respectively (a total of 131) en- gaged in research on cloud physics and weath- er modification. A conservative estimate, based on the authorship of publications, is that 218 scientific research personnel are ac- tive in the Soviet program; the actual num- ber working at the present time probably is larger. (The leading Soviet personnel are listed in appendix B.) No country in the West has so many scientists working in the cloud physics and weather modification field. For example, the United States has approxi- mately 75 scientists engaged in similar re- search.3 CLOUD PHYSICS RESEARCH ACTIVITIES The Soviets have been making impressive progress in their cloud physics research and the program is active and expanding. (See biblography, appendix C.) Most of the per- tinent Soviet scientific literature that is avail- able deals with basic cloud physics research, although an increasing amount of informa- tion is becoming available on weather control. All areas of cloud physics research are be- ing pursued actively in the Soviet Union. A measure of the scope of the program is the Sixth All-Union Cloud Conference, held at the Institute of Applied Geophysics of the Academy of Sciences, USSR, from 15 to 20 June 1959, which was attended by 44 Soviet representatives of nearly as many different types of scientific institutions of the USSR, as well as representatives from Communist China., The meeting was called by the Co- ordinating Council of Problems of the Physics of Clouds and Precipitation of the Depart- ment of Physical Mathematical Sciences of the Academy of Sciences, USSR. The overall effort evidently has an interdisciplinary char- acter. Articles pertinent to cloud physics have been written by members of the Institute of Physical Chemistry and other organiza- tions, such as the Institute of Power Engineer- ing and Hydraulics of the Academy of Sci- ences, Armenian SSR. The Sixth Cloud Conference was called to review the progress made since the previous CONFIDENTIAL 3 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 CONFIDENTIAL conference in 1956 and to encourage an ex- pansion of research in cloud physics. Resolu- tions were adopted: (1) to strengthen work in troposphere synoptics, microphysics of clouds and fog and their modification, cloud electrification, and instrumentation for field and laboratory experiments; (2) to expand studies of large-scale weather systems through the use of aircraft soundings to high altitudes, with special attention to clouds extending to very high altitudes; (3) to broaden work in atmospheric chemistry; (4) to broaden theo- retical generalizations of experimental work; (5) �to develop new instruments for atmos- pheric studies and perfect the use of rockets for studying clouds in the upper layers of at- mosphere; (6) to organize an All-Union Cloud Year (VOG) in 1962; (7) to publish through the Academy of Sciences, USSR, a new peri- odical entitled "Clouds and Precipitation," and to hold seminars on given problems twice a year; (8) to increase informative work by the Coordinating Council on domestic and for- eign investigations; and (9) to hold the next conference in 1961 before the VOG begins.' The establishment of a special physics jour- nal, the decision to hold seminars at 6-month intervals, and the plan to have an "All-Union Cloud Year," as well as the other decisions, all indicate a large expansion of an already substantial program. The aims spelled out in the series of resolutions have also been recognized as being important by other coun- tries, and many have instituted modest pro- grams. The Soviets have apparently seen the important implications of greater knowledge of cloud and precipitation processes and con- trol and have dictated that emphasis will be placed on this type of research. Of particular interest is the Soviets declara- tion that a more daring approach must be directed to studies influencing large-scale weather processes and climate.' This indi- cates that the Soviets recognize the potential of this type of research but that relatively little has been done to date in the area of large-scale weather modification. Evidently, increased efforts and experiments will be di- rected toward this goal in the future and it is believed that during the next 5 years the Soviets will conduct their first experiments designed to control large-scale meteorological processes. Soviet research has been along lines similar to those pursued in other parts of the world, with only minor differences in level of� achieve- ment. Research in the USSR and the United States appears to be on about the same level in the study of ice crystals and snowflakes, cloud formation and structure, atmospheric electricity, and cloud physics instruments. In the USSR, more progress has been made in the study of the microstructure of clouds, whereas in the United States more progress has been made in the study of raindrop spec- tra and precipitation processes. Research in these areas of cloud physics is basic to an un- derstanding of the natural mechanisms of precipitation and such understanding is a pre- requisite for effective control of the weather. Recently, some emphasis has been placed on studies of atmospheric electricity and on the development of better instruments for cloud physics measurements. One of the most productive scientists in these areas has been I. M. Imyanitov. He has written a large number of articles on various aspects of at- mospheric electricity and recently published a book.4 RADAR METEOROLOGY Radar is capable of detecting the presence of hydrometeors, especially large water and ice particles, and has been used extensively and beneficially in cloud physics research pro- grams throughout the Western world. Radar has furnished valuable data on fundamental problems regarding the formation of precipi- tation in convective clouds. It has been use- ful for studying the growth of convective clouds and the precipitation-generating levels in clouds. The ability of radar to detect large water and ice particles has made it a valuable tool for assessing the results of cloud-seeding experiments. To date, it has been used pri- marily for the detection of formation of pre- cipitation in cumuliform clouds, but it is rea- sonable t6 expect in the near future it will be used to supplement rain-gage networks, in order to obtain a better estimate of the total rainfall over the seeded area. 4 �etTIFTDENTTAL.� Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 �trOwriaritt Radar Equipment The standard radar set used by Soviet me- teorologists is the so-called Kobal't radar. This equipment operates at a wave length of 3.2 centimeters, peak output power of 50 kilo- watts, utilizes an antenna diameter of 0.736 meter and records on a plan-position indica- tor (PPI) scope.* All articles involving radar observations of clouds and precipitation have stated that the Kobal't radar or a modifica- tion thereof was employed. The Kobal't has been used both on the ground and in� air- planes.5 6 The characteristics of the Kobal't radar are similar in many respects to those of the AN/APQ-13, a U.S. airborne radar set devel- oped in the early 1940's for bombing and navigation and widely used by the U.S. Air Weather Service from 1945 to 1954. An im- proved U.S. radar set, the AN/CPS-9, which was specifically designed for weather observa- tions, has been used operationally since about 1954. Several Soviet papers have been written about techniques to increase the sensitivity of the Kobal't. In 1958, V. D. Stepanenko carried out tests in which the 0.736-meter antenna reflector was replaced with a 2-meter reflector.7 Another article in 1958 reports on a modified Kobal't radar with a fixed, 20- meter, vertically pointing antenna.8 It is clear from these articles published in 1958, that the Soviet scientists were trying to im- prove an existing piece of equipment, whereas in the United States a specially designed radar had already been in operational use for about 4 years. The AN/CPS-9 is a much better weather radar than the modified Kobal't because the antenna scanning is flex- ible, the output power is higher, and in all probability the minimum detectable signal is lower. In addition, the U.S. Weather Bureau in 1959 began to install new weather-radar sets that are superior to the AN/CPS-9 in many respects. It appears that the Soviets have a network of Kobal't radar sets for use at weather sta- * A type of radarscope on which the range and azimuth of a target are displayed in polar coordi- nates. tions. A Soviet meteorologist, V. M. Much- nik, cites radar data obtained at Kiev during the period 1952 and 1956.5 He also indicates that there was a Kobal't radar set in Moscow but does not give any dates. A. A. Federova analyzed data obtained at Rostov-on-Don. V. V. Kostarev set out to use radar with a vertically pointing antenna for the detection of cloud layers. Recognizing that it would be necessary to increase the sensitivity of the Kobal't radar, he chose to increase the an- tenna diameter to 20 meters. This was done by the construction of a steel reinforced con- crete paraboloid that was sprayed with a me- tallic paint (figure 1) . He discovered that the antenna gain (the increase or amplifica- tion of the signal) varied with range, out to a distance of about 25 kilometers. Over 12 kilometers, the altitude range of interest, there was a breakdown of the usual relation- ship between echo strength and distance. After considerable effort, Kostarev finally stated that exact quantitative measurements were difficult.8 In the West the aims of Kostarev's research, the detection of cloud layers, have been met in various ways. The first was to increase output power, and in this way, increase the signal-to-noise ratio. The most successful way to observe clouds with radar was to use radar sets at shorter wave lengths. As early as 1951, Western scientists were utilizing K- band radar sets (wave lengths 0.86, 1.25, and 1.87 centimeters) for cloud detection. Since that time they have been widely used both for research as well as for cloud-base and cloud- top indicators. Theoretical Work in Radar Meteorology In 1952, D. M. Vysokovskiy gave a detailed discussion of the use of radar for weather observations and the theory involved." Re- cently A. B. Shupyatskiy has proposed that by measuring returned power and attenuation one should be able to obtain measurements of the mean drop sizes and the water content of heavy rainstorms."- The article gives a fairly detailed discussion of the relevant scat- tering theory and develops equations for cal- culating the variables of interest. Although CONFIDflNTIAL 5 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 --GONFIDENTTAL the ideas expressed by these Soviet authors were not new, their articles showed that they were acquainted with the electromagnetic theory involved. Most of the relevant refer- ences were derived from journals published outside the Soviet Union. A paper published in 1958 has dealt with the problem of estimating turbulence in clouds by measuring the fluctuations of radar signal strength.12 This article does not refer- ence U.S. and Canadian work on this subject, which has been quite extensive since 1950, but it demonstrates a more advanced ap- proach to the use of radar for meteorological problems than most of the other Soviet arti- cles found to date. Application of Radar to Meteorology A number of articles have been found that refer to radar as a tool for detecting the presence or absence of precipitation.7 13 Some studies have been made of the characteristics of radar echoes as they apply to cloud physics. A. P. Chuvayev (1956) investigated the verti- cal extent of convective clouds and the exist- ence of a precipitation echo.14 Similar work was published in the United States in 1951. V. M. Muchnik published statistics on the size of convective echoes and the fraction of the observed area covered by echoes.� Similar work was done by the U.S. "Thunderstorm Project" about 9 years earlier. Muchnik also made a study of the differences of the radar echoes from showers and thunderstorms.5 The author used a rain intensity of 24 milli- meters per hour to discriminate between the two phenomena. He listed various rules in- volving vertical echo extent and range of de- tections that would permit a separation of showers from thunderstorms. This empirical approach is not particularly useful. A paper written in 1953 but published 4 years later, stated that thunderstorms can be circumnavigated by airplanes if the air- planes are equipped with suitable electric field measuring equipment. It points out that the arguments against radar for air- borne use are (1) weight, (2) high cost and (3) inability to distinguish between showers and thunderstorms. In a later section, the authors state that it would be worthwhile to combine a field meter with radar.15 Muchnik concluded that aircraft should be equipped with radar and thunderstorm detectors to improve safety and comfort. � In the United States the recommendation to install radar in commercial aircraft was made by various agencies in about 1949, and was put into prac- tice in about 1954. Sokolov, who in 1958 claimed that he was entrusted by the "Military Scientific Society" with the study of weather observations by means of radar, has discussed various aspects of weather-radar observations and suggested ways to improve the observations. Many of his statements are overgeneralizations and either incorrect or misleading and do not demonstrate an expert knowledge of the prac- tical limitations of radar equipment.� Status of Soviet Radar Meteorology If the articles in the open literature cited above represented the latest thinking of So- viet experts in radar meteorology at the time they were published, it would have to be con- cluded that the Soviets trail far behind U.S. scientists. To date, all the articles found deal with the use of the low-powered X-band Kobal't. Azimuthal scanning and vertically pointing antennas have been employed but nothing has been reported about vertically scanning equipment. The use of K-band equipment has not been mentioned. V. Soko- lov pointed out the value of large peak power but there is no evidence that anything but the Kobal't radar has been used for weather work.� Only one article has been found dealing with the use of radar for quantitative meas- urements of rainfall intensity although a few articles have mentioned this possibility. Many other aspects of radar meteorology have been barely touched upon or not mentioned in the Soviet literature. Some examples are the fol- lowing: (1) the "bright-band";* (2) non- spherical particles; (3) melting particles; (4) depolarization; (5) isoecho contour mapping. Most of the published Soviet studies have * The enhanced radar echo of snow as it melts to rain. 6 �7617n5E1 NM-22th- Approved for Release: 2018/01/30 006541158 Approved for Release 2018/01/30 006541158 CONFIDENTIAL been of a qualitative exploratory nature of the type published in the United States 5 to 10 years ago. It would appear on the basis of this literature that Soviet radar meteorol- ogy lags that of the United States by at least 5 years. On the other hand, this assessment does not take into account radar equipment and in- vestigations that are classified, and there are strong suggestions of classification in this area. For example, one of the articles cited above was written 4 years before it was pub- lished. The long delay suggests official sup- pression of publications. Soviet air defense radars are known to be of excellent quality and are equal to the best of the Western systems. There is little doubt, therefore, that the Soviets have the capability to develop high quality weather-radar. It is likely that some developments have been classified and it is possible that any lag in radar-meteor- ology may be more apparent than real; never- theless, from a conservative point of view, the Soviets would have to be judged as trail- ing in the specialized field of radar-meteor- ology. Also, it doesn't seem reasonable that if improved radar were available they would continue to use and publish on the Kobalt. It is quite likely that if improved weather radars are available, it is a recent develop- ment and they are therefore definitely behind in terms of use of, and result from, such radars. With the expanding Soviet research programs in cloud physics and weather modi- fication, it is believed that more and better weather-radar will become available within the next few years. CLOUD SEEDING AND WEATHER MODIFICATION RESEARCH Soviet cloud seeding work reported in the scientific literature has been scanty indeed, although the Soviet press and radio have re- ported on weather modification activities from time to time since 1947. During 1959-60 a number of fairly substantial articles have ap- peared concerning research done in the period before 1957. It has become clear that con- siderably more research in the area of weather modification has been in progress than has been indicated by earlier literature. In 1958, a foreign meteorologist who visited the USSR reported that the staff of a Soviet institute engaged in weather modification was reluc- tant to discuss their work because it was classified; however, he was given the impres- sion that the work was in the process of being declassified) 6 Quite evidently there has been a relaxation of government classification, but it does not appear that the relaxation has been complete. The large lag in time be- tween completion of the work and publica- tion indicates that details of work completed during the last 3 or 4 years still are being withheld from the scientific journals. There are several interesting sidelights concerning Soviet classification of weather control research and activities. Several issues of Trudy, Main Geophysical Observatory, which bear unusual numbers, namely, 09, 013, 020, have been cited in the literature un- doubtedly by oversight. No other Trudy series have numbers which begin with a zero. Every effort to obtain these has failed. Re- cently, a direct attempt to obtain them in Moscow was turned away with the statement that these, were state papers and were un- available. When members of Kozlov's party were asked about Soviet weather control dur- ing their visit in the United States, all claimed they had never heard of any Soviet capability in this field and treated it as a joke.17 Cloud and Fog Dispersal The earliest available Soviet scientific ref- erence to research applicable to cloud and fog dispersal by dry ice (solid CO2) is dated 1951.'9 As early as 1952, the Soviets at- tempted, with questionable success, to dissi- pate the low clouds by seeding techniques over Red Square in Moscow during a big parade.2� The successful use of dry ice seed- ing for dissipating stratiform clouds has been reported in a number of popular and scien- tific papers dated 1955 through 1957.21-23 In 1958, Federov stated, "The problem of the dis- persal of supercooled clouds can be consid- ered solved in principle. At present, in the USSR, a distinct technology designated for opening airports in winter is being completed and introduced into practice. Successful dis- CONFIDENTIAL Approved for Release: 2018/01/30 006541158 7 Approved for Release: 2018/01/30 006541158 -GeNplEtErrrA-r� persal is being accomplished over expenses of 10 to 15 kilometers." 24 A popular article re- iterates and substantiates this statement later in 1958 and another brief article pub- lished in 1960 describes a demonstration of carbon dioxide seeding of a fog bank to clear an airport.25 26 The scientific feasibility of dissipating subcooled clouds by dry ice seed- ing was established in the United States by the Signal Corps Engineering Laboratories during the period 1952-55.27 The USSR, how- ever, was the first country to establish a routine operational program for dispersing such clouds and fog. Seeding Reagents Although Soviet scientists showed they were aware of the possible value of various types of seeding reagents, virtually all field experiments described in the scientific litera- ture available a year or so ago made use of seeding with dry ice from aircraf t.28 Articles that have appeared recently have shown that the Soviets have used and will continue to use a variety of seeding techniques and re- agents. G. Ya. Myakishev (1958) in a nontechnical article has discussed the use of calcium chlo- ride particles for seeding so-called "warm clouds." He also indicated that experiments were conducted with water spray from air- craft which "gave positive results in separate cases only. Work in the given direction is continuing." 29 This popular article did not contain much substance, but it does show that investigation of techniques of modifying warm clouds is in progress. It is also known that the Soviets purchased a number of small rockets (maximum altitude 1,500 meters) from an Italian manufacturer (figure 2). The Italians have proposed that these rockets could be used for seeding with sodium chlo- ride and have employed them for this purpose in Africa. The Soviets probably have used them for this purpose also. A group of Soviet scientists have concluded that experiments on burning red phosphorus directly in the clouds showed that research on hygroscopic substances must be carried further with the object of modifying the warm parts of clouds.3� An increasing number of articles deal with the use of silver iodide. The particles have been dispersed in a number of ways. Shtal' and Morachevskiy have discussed various as- pects of cloud seeding techniques." 32 They mention that silver iodide has been placed in clouds by firing tracer bullets containing silver iodide as a component of the combusti- ble mixture. The firing was done from the ground. These articles are of a non-technical nature and do not give enough detail to eval- uate the feasibility or value of this seeding scheme. The authors also mention the use of lead iodide and report on the dispersion of silver iodide from an airplane. Other authors have also mentioned airborne silver iodide seeding. A non-technical article states that anti-hail rockets have been developed to seed with silver iodide. These rockets undoubtedly are similar to the rockets purchased from the Italians." A group of authors have discussed the use of silver iodide for hail suppression and state that continuous crystallization would require four to 10 kilograms in a cloud, but they suggest using 8 to 30 kilograms of the reagent to take into account unknown factors.34 The use of 8 to 30 kilograms of silver iodide in a cloud as suggested by the Soviets is a much larger quantity than has ever been used in the West. If this amount of silver iodide crystals can be put into a cloud, hail probably would be prevented. It is not clear how this can be done effectively and there is no evidence of it being done in the USSR. An extensive program was carried out in 1956 to test the possibility of modifying indi- vidual cumulus congestus clouds by introduc- ing silver iodide or lead iodide into the sub- cooled part of the cloud. The seeding crystals were produced at the ground by a new tech- nique of condensation after vaporization of a mixture with red phosphorus. The latter served as a fuel for the vaporization. One part of silver iodide was mixed with two parts of red phosphorus. Two kilograms were used to seed one cubic kilometer of cloud. The efficacy of the mixture of silver iodide and red phosphorus is unknown and was not stated in the article. The experimenters, however, demonstrated they were aware of '8 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 OFFICIAL U3E ONLY Figure 1. Koball Radar with 20-meter antenna. Figure 2. Italian anti-hail rockets being prepared for shipment to USSR. F'FTIY Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 �OFFTCIA-L---T51SET-QXLY--- / Figure 3. Soviet cloud physics research instruments mounted on aircraft. Y Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 the difficulties of using silver iodide particles in their discussions of various relevant factors such as photo-deactivation.30 Balloons have been employed for dispersing silver iodide and dry ice.3� Dry ice seeding also has been carried out by hanging a basket of dry ice from a cable below an airplane.35 The use of silver iodide for dissipating low cloud and fog was mentioned for the first time in a scientific article published in 1959.36 Increasing Rainfall by Cloud Seeding A number of recently available Soviet re- ports have concluded that a rainfall increase could be caused by cloud seeding. One group concluded that silver particles released from the ground would increase precipitation if me- teorological conditions were correct.3� G. Ya. Myakishev reported that water spray some- times produced rain from warm clouds.29 I. M. Imyanitov et al., reported precipitation echoes always appeared on the radar from cumulus congestus clouds after dry ice seeding." A. P. Chuvayev also reported precipitation was caused to form in convective clouds by seed- ing with dry ice in quantities of less than 1 kilogram per kilometer.37 Previously evalu- ated Soviet articles dealing with "rainmak- ing" also concluded that rainfall could be in- creased by seeding. There still are no Soviet reports of a systematic, carefully designed and executed program of cloud seeding that would permit statistical tests of the efficacy of cloud seeding. In most cases the behavior of a seeded cloud has been compared with that of other clouds. The possibilities of bias make this technique of questionable value. Seeding of Convective Clouds In the past year it has become clear that the Soviets are engaged in an extensive pro- gram involving the study of convective clouds and thunderstorms. A large research pro- gram is in progress in the southern USSR and the Caucasus. One lengthy article de- scribes studies of thunderstorms in these re- gions." The investigations have involved the use of specially instrumented aircraft and radar. The aircraft, IL-12 number L-1784, was equipped by the Scientific Research Insti- tute of the Civil Air Fleet with a Kobal't radar, a "complex of apparatus for recording the parameters characterizing the flight of an air- craft through a turbulent medium, an instal- lation for measuring the atmospheric electric field strength" and apparatus for atmospheric soundings (meteorograph for recording alti- tude, temperature and humidity, micro- photographic equipment for observing cloud droplets and water content instrument) . This aircraft is equipped well for cloud phys- ics observations * (figure 3) . In another article, written 4 years before publication, the same authors describe experiments in which cumulus congestus clouds were seeded with 2 to 7 kilgrams of dry ice in an effort to modify the electric state of the clouds." They con- cluded that dry ice seeding could lead to large increases in the electric field intensity, "and probably, in favorable conditions can also pre- vent the development of hail." The conclu- sion about modification of the electric state of the clouds was a reaffirmation of the same conclusion drawn in a paper by I. M. Imyani- tov and A. P. Chuvayev written in 1956 and is similar to one arrived at by MacCready in the United States. The validity of the con- clusion in both cases, however, is open to question because of uncertainties about the experimental techniques. In any event, the Soviet paper does not present hail observa- tions and without them the conclusion must be regarded as hypothetical. Silver iodide seeding from the ground has been used in an attempt to modify convective clouds in the Caucasus for the purpose of preventing hail.3� From radar observations, the experimenters concluded that in seeded clouds the "echo zones created artificially" were 1.5 to 2 kilometers lower than natural echoes. Also, they stated that "modification of cumulus congestus clouds to prevent hail is possible only where the cloud has developed up to the negative temperature regions (-5 to �10�C)." Since they were using silver iodide particles, which are not effective until * Soviet scientists started making detailed micro- physical studies of clouds with well instrumented aircraft several years before such studies were made in the United States. 9 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 �CraNnTrriffilki, these temperatures are reached, this state- ment is certainly valid. Nevertheless, the im- plication that something can be done about hail suppression is not proven. They do not present any data on hail. Although there have been a number of statements about the use of seeding to prevent damaging hail, floods, etc., no articles have been found yet which relate seeding activities directly to that phenomena. The emphasis placed on the study of thunderstorms and hail and their control through cloud modification techniques is clearly shown by the fact that the research in the southern USSR is a cooperative effort of several organizations. For example, the Academy of Sciences of Armenia and Georgia are working with other institutes of the USSR. Status and Trends of Soviet Weather Modification During the past year, the Soviet literature has contained more information than previ- ously about cloud modification studies. So- viet scientists are believed to have accom- plished much more research in this area than has found its way into the open literature. The map (figure 4) shows the areas in which cloud seeding operations are known to have been carried out, the organizations, and the dates involved. Some of the results of the work at locations A, B, and C (see map), have been reported, but the results of the project D have been very sketchy. It should be noted that all of these programs have been concerned with the modification of convective clouds. In all of these operations, one of the prime objectives has been to develop tech- niques to suppress damaging hail. One of the potentially important applica- tions of cloud modification techniques is that of increasing rainfall. No reports have been found of experiments to obtain quantitative estimates of rainfall increases following seed- ing. In many other countries such "rain- making" activities have been in practice for many years. The results of most of these tests have not been conclusive. In order to make quantitative analyses of the effects of the seeding, it is necessary to measure rain- fall at the ground or flow of water out of a watershed. The analysis involves statistical techniques. Good experiments also incor- porate sound statistical principles in the de- sign of the experiments. No Soviet research of this type has been found yet. In view of the great practical value of this kind of work, it is difficult to believe that this area has been overlooked or neglected. It may be significant that the Soviet re- ports say virtually nothing about seeding winter storms or stratified orographic clouds for the purpose of increasing rainfall. It seems inconsistent that such a well-known technique of cloud modification has not been tried. Many Western scientists believe that these types .of clouds are most suitable for increasing rainfall. The Soviets very prob- ably have been conducting experiments in this promising area for weather modification, but the results are classified and not available. An examination of figure 4 indicates that the reported cloud seeding activity is concen- trated in the western Soviet Union. A well- balanced program would call for activity also in the eastern sections because there are geo- graphical differences in cloud types and cloud properties. It is likely that work has been done in the eastern sections but not reported and that it will continue in the future. It is stated that the "All-Union Cloud Year" is in- tended to obtain detailed cloud observations over the entire Soviet Union. The observa- tions are to be used to improve cloud fore- casts and later to modify the clouds "in the interest of aviation, agriculture, transport, and other fields of the People's Economy." 1 The actions taken by Soviet scientists dur- ing the past year show that they recognize the lack of knowledge of many important aspects of cloud physics. They also demon- strate an aggressive attitude towards the solu- tion of many of the problems. The magni- tude of their program is impressive indeed. It has been expanding rapidly. Without doubt the development of successful tech- niques to modify clouds, to suppress damag- ing hail and lightning, prevent flash floods 10 rnmFIT;tENTIAL Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 POLAND Kiev FIN LAN Leningrad 0 A � Moscow �Rostov ..41\ (s0B "-Mt. Elbrus , r; ,,/ %., 0 i ...*, , Tbilisi �^"0 rt Lake Georgia 1.4 Sevan A Armenia Azerboizhan KEY Tashkent � Figure 4. Areas of Soviet cloud seeding activity. Convective clouds, thunderstorms, hail - dry ice Convective clouds, thunderstorms, hail - dry ice Convective clouds, thunderstorms, hail - seeding Convective clouds, thunderstorms, hail - Agl from ground D Convective clouds, thunderstorms, hail - dry ice INSTITUTE PERFORMING EXPERIMENT Main Geophys. Obs. Main Geophys. Obs. Scientific Res. Inst., Civil Air Lines Inst. of Geophys., Acad. Sci. Georgia SSR DATE OF EXPERIMENT 1951-1952 July 1953 1952 to 1956 Inst. of Geophys., Acad. Sci. May to July, 1956 Georgia SSR Probably to Inst. of Applied Geophys., present Acad. Sci., SSR Georgian Admin. of Hydrometeor. Service Tbilisi Sci. Res. Hydrometeor. Inst. Dept. Atmos. Phys., Lenin State Univ. Main Geofiz. Obs. Inst. Power Eng. & Hydraulics, Acad. Sci., Armenia 1958-1959 R Locations of radar sets. OFFICIAL USE ONLY Approved for Release: 2018/01/30 006541158 Approved for Release 2018/01/30 006541158 CONFIDENTIAL and increase rainfall would be of tremendous economic value. At present, neither the So- viets nor any other group can convincingly claim that they can do these things success- fully. Quite obviously, the "propaganda" value of well-supported claims that techniques have been developed to control weather would be enormous. In recent years the most spec- tacular scientific advances have had military overtones. A development of such tremen- dous peacetime value as artificial rainmaking or hail suppression probably would have great impact. It is estimated that the USSR will overtake the West in the fields of cloud physics and weather control research in 5 years if the resolutions of the "Sixth All Union Cloud Conference" are carried out while the pro- grams of the West continue at their present, and likely future, rate. The Soviets are in a strong position to mount an expanded re- search program since they have ample trained personnel to carry it out effectively. There is little reason to doubt that the Soviet gov- ernment will continue to support the expand- ing program in weather modification. �ZTCzrrmtatfr4AL-_ Approved for Release: 2018/01/30 006541158 11 Approved for Release: 2018/01/30 006541158 GLOSSARY Convective clouds Clouds that owe their vertical development, and possibly their ori- gin, to vertical motions in the atmosphere. Cumuliform clouds Clouds in which the principal characteristic is vertical develop- ment in the form of rising mounds, domes, or towers. Cumulus congestus clouds Strongly devel- oping cumuliform clouds with generally sharp outlines and sometimes with a great vertical development; they are characterized by a cau- liflower or tower aspect of large size. Hydrometeor Any product of condensation or sublimation of atmospheric water vapor. Orographic clouds Clouds whose form and extent are determined by the disturbing ef- fects of the topographical features of the earth's surface upon the passing flow of air. Stratiform clouds Clouds with extensive horizontal development as opposed to vertical development. Supercooled clouds Clouds that contain liquid water droplets at temperatures below freezing. Troposphere synoptics The qualitative study of the development, movement, and be- havior of weather phenomena in the lower 10 to 20 kilometers of the atmosphere. CONFIDENTIAL Approved for Release: 2018/01/30 006541158 13 Approved for Release: 2018/01/30 006541158 CONFIDENTIAL APPENDIX A ORGANIZATIONS AND PERSONNEL ENGAGED IN CLOUD PHYSICS RESEARCH The scientists listed either are presently or were in the last 10 years at the particular establishment. In some instances, the association of a particular individual with a particular establishment is based on weak evidence, but it waS felt desirable to do this rather than to indicate the affiliation as "unknown." After each individual's name is a list of the dates by year of articles published or reported at a conference by that individual. When more than one paper was published in.l year, letters a, b, etc., are used to designate each article. The symbols SA and CA indicate that the author in question was either a-senior Di' coauthor respectively of a paper having more . than one author. The symbol P indicates the research was reported at -a �conference but a published form of the paper has not been located. ACADEMY OF SCIENCES Coordinating Council on Problems of Physics of Clouds and Precipitation, Moscow Instituteof Applied Geophysics, Moscow All types of cloud physics research including cloud seeding. Alekandrov, E. L.: 1959 Balabanova, V. N.: 1959 a,b. Belyayeva, I. I.: 1957 (SA) Bibilashvili, N. Sh.: 1959 (SA) Bocharov, Ye. I.: 1958 a,b. Bolsheverov, B. M.: 1952 Bonchkovskiy, V. F.: 1954 Borishanskiy, L. S.: 1952 (SA) Chudaykin, A. V.: 1956 (P) Fedorov, Ye. K. (Corresponding member of Academy of Sciences; Director of Institute of Applied Geophysics): 1958; 1957 (OA); 1956; 1951; 1950. Krasnogorskaya, N. V.: 1958; 1956; 1955; 1952 Krechmer, S. I.: 1954 Laktionov, A. G.: 1958 Levin, L. M.: 1959; 1958 a,b; 1957 a,b; 1956; 1956 (CA); 1954 alb; 1953; 1953 (SA). Al Litvinov, I. V.: 1959; 1958 a,b; 1957; 1956 alb,c�d; 1955 Mamina, E. F.: 1957 (SA) Merzhanov, K. M.: 1956 (SA) Ndkirov, A. Ye.: 1959; 1957 alb,c; 1957 (CA) Novikov, Ye. A.: 1957 a,b. Ordzhonikidze, A. A.: 1959 (CA) Peterimov, N. I.: 1956 (CA) Pshenay-Severin, S. V.: 1959; 195; 1957 Pudovkina, I. B.: 1956 (P) Sergiyeva, A. P.: 1959; 1958 Shaposhnikova, I. I.: 1954 (CA) Shchelokov, V. V.: 1956 Skatskiy, V. I.: 1956 Smirnov� N. S.: 1957 (CA); 1956; 1956 a,b (CA); 1954 (SA); 1950 Starostina, R. E.: 1956 (P); 1953 (CA) CONFIDENTIAL Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 _CONK-Eafilikr- Sulakvelidzel G. 1959 a,b (CA) Tantsova, N. N.: Teverovskiy, Ye. 1952 (CA) Vul'fson, N. I.: 1956 alb; 1956 Zaytseval A. M.: K.: 1959; 1954 (CA) N.: 1956 (P); 1958; 1957 a,b; (SA); 1954, 1953 1959 (CA) Institute of Physical Chemistry, Moscow Nuclei, Growth of water drops Batova, G. A.: 1956 (P) Churakov, V. N.: 1956(P) Deryagin, B. V. (Corresponding member of Academy of Sciences); 1957 (SA); 1957 (CA); 1956 (SA); 1951 (CA); 1949 (SA); 1948 a,b (SA) Dukhin, S. S.: 1957 (SA); 1957 (CA); 1957 (CA) Izmaylova, G. I.: 1956 (P) Kudryavtseval N. M.: 1956 (P) Leonov, L. F.: 1956 (P); 1952 (CA); 1951 (CA) Nikol'skiy, A. P.: 1956 (P) Petryanov, I. Prokhorov, P. 1952 (SA); 1949 (CA); Rosenblum, N. Starozhilova, Todes, O. M.: Valesenko, G. 1948 (CA) Yashin, V. N. Institute of Physics of the Atmosphere . Moscow Theoretical studies of convection, convective Driving, A. Ya.: 1958 a,b (SA) Feigel'son, Ye, M.: 1959; 1954 a,b; 1951 Gutman, L. N.: 1958 (CA); 1957 a,b Polozova� M. N.: 1958 (CA) Smirnova, A. I.: 1958 a,b (CA) Tsvang, L. R.: 1958 (SA); 1956 Zolotavina, N. Y.: 1958 (CA) Institute of Oceanology, Moscow Atmospheric salt Blinov, L. K.: 1950 A-2 CONFIDENTIAL 1911.8 (SA) S.: 1956 (P); 1951 (SA); 1949; 1947 (SA) : 1948 (CA) A. I.: 1956 (P) 1948 (CA) Ye.: 1956 (P); : 1947 Clouds (CA) Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 Institute of Physical Problems imeni S. I. Vavilov Ball lightning Kapitsa, P. L. (Member of Academy of Sciences): 1955 Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propagation, Near Moscow Lightning Kashprovskiy, V. Ye.: 1956 (P) ACADEMY OF SCIENCES, ARMENIAN SSR Institute of Power Engineering and Hydraulics Artificial precipitation ACADEMY OF SCIENCES, GEORGIAN SSR Thunderstorms, hail, cloud modification Institute of Geophysics, Tbilisi Bukhikashvilli, A. V.: 1958 (Director) Kurdiani, I. G. Kartsivadze, A. I. Okudzhaval A. M. ACADEMY OF SCIENCES, KAZAKH SSR Chemical composition of water Baktorov, A. B.: 1958 A-3 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 CONFIDENTIAL CHIEF DIRECTORATE OF THE HYDROMETEOROLOGICAL SERVICE Main Geophysical Observatory, Leningrad All types of cloud physics research with emphasis on convective clouds; cloud modification studies Ashkipova, E. P.: 1957 Bashkirova, G. M.: 1957 (SA); 1953 (SA) Braxilevich, V. V.: 1950 (SA) Budilova, Ye. P.: 1954 (CA) Chestnaya, I. I.: 1955 a,b; 1951; 1948 Chikirova, G. A.: 1956 (CA) Chukanin, K. I.: 1959 (CA) Churinova, M. P.: 1955; 1951 Chuvayev, A. P.: 1957 a,b,c1d,e; 1957 (SA); 1957 alb�cld (CA); 1956 (C) a,b; 1955 (CA); 1954 (SA 1953 a,b,c; 1953 a,b,c (CA); 1950 Dergach, A. �L.: 1959 a,b,c Dianov, I. M.: 1959 (CA) Drozdov, O. A.: 1955 Dubov, A. S.: 1949 ); (CA) Mikhailovskaya, V. V.: 1958 (CA); 1956 (CA) Minin, I. K.: 1956 (P) Mbrachevskiy, V. G.: 1959 (SA); 1959 a,b (CA); 1958 a,b (CA); 1957 (CA) Morozyanskiy, A. L.: 1956 (P) Myvkhyurya, V. I.: 1956 (P) Nikandrov, G. T.: 1957 (CA); 1957 a,b (SA); 1956 a,b (SA) Nikandrov, V. Ya.: (Vice Director): 1959 (SA); 1959 (CA); 1957 a,b; 1957 (CA); 1956 a,b; 1953; 1953 a,b (SA); 1953 (CA); 1951; 1950 (SA); Dvali, Ye. R.: 1956 1950 (CA) Frenkel, Ya. I.: 1953; 1950; 1946 (SA) Ogorodnov, D. Ye.: 1956 (CA) Gaevskiy, V. L.: 1955 Osipova, G. I.: 1957 Gigineyshvili, V. M.: 1953 (BA) Pastukh, V. P.: 1957 (SA) Gordon, I. Z.: 1951 Pershina, T. A.: 1956 (CA) Imyanitov, I. M.: 1958 (SA); 1957; Pinegin, G. N.: 1954 (CA) 1957 a,b,c,d (SA); 1956 a,b; 1956 a,b,c,d (SA); 1952 a,b; 1950; 1949 a,b Khimach, M. A.: 1956, 1954 (CA) Kolokolov, V. P.: 1957; 1956 (SA); 1956 (CA) Krasikov, P. N.: 1959 (SA); 1957 (SA); 1957 (CA); 1956 (SA); 1953; 1953 (CA) Krasilishchikov, L. B.: 1956 (P) Kryukova, G. T.: 1954 (CA) Kulik, M. M.: 1957 a,b,c (CA) Ledokhovich, A. A.: 1959 (SA); 1959 a,b (CA) 1956 (SA); 1956 (CA) Loch, B. F.: 1956 a,b Makhotkin, L. G.: 1959; 1958 (SA) Namontov, N. V.: 1957 (CA) Matveyev, L. T.: 1959 a,b; 1956 (SA) A-4 CONFIDENTIAL Piotrovich, V. V.: 1958; 1956; 1949 Polyakova' Ye. A.: 1956; 1953 (SA) Rabinovich, B. I.: 1957 (CA) Reynet, Ya. Yu.: 1956 Sal'man, E. M.: 1957 Selezneva, Ye, S.: 1956; 1953; 1950; 1948 a,b; 1946 Sereyev, O. D.: 1953 (CA) Shifrin, K. S.: 1958; 1957 (SA); 1955 a,b; 1953 (CA); 1951 alb Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 CONFIDENTIAL . Shishkin, N. S.: 1957 alb; 1956 a,b; 1955 alb; 1954 a,b1c,d; 1954 a,b (SA); 1953 alb; 1952 alb; 1951 alb, eldlelf; 1949; 1948; 1946; 1946 (CA) Shtal', V.: 1958 a,b (SA) Shvets, M. Ye.: 1955; 1951 alb; 1948 (CA) Selitskaya, V. I.: 1959 (CA) Solov'yev, A. D.: 1958 (CA); 1956 a,b. Sokhrina: 1957 (CA) Strelitsoval M. B.: 1956 (CA) Tarasov, A. V.: 1957 (CA) Timofeev, M. P.: 1955; 1948 (CA); 1948 (SA) Vasil'chenko, I. V.: 1958 Vinograd, P. L.: 1956 Vorontsov, P. A.: 1959 (SA); 1956; 1955; 1954 (SA) Voskana, A. I.: 1957 (SA) Voskresenkiy, A. I.: 1959; 1959 a,b, el (SA); 1957 (SA) Zabrodskiy, G. M.: 1959 (SA) Zamorskiy, A. I.: 1956; 1955 a,b; 1953; 1952; 1951 a,b; 1950 a,b; 1948 alb,c�d�e Zaytsev, V. A.: 1959 (SA); 1959 (CA); 1956 (SA); 1956 (CA); 1950; 1948 a, b, old. Ziganov, N. P.: 1956 (CA) Zykova, V. V.: 1956 Central Aerological Observatory, Dolgoprudnaya, near Moscow All types of cloud physics research with emphasis on stratiform clouds, cloud modification. Bergun, K. I.: 1953 Borovikov, A. M.: 1953; 1952; 1952 (CA); 1948 Britayev, A. A.: 1959 (SA); 1956 Buikovskayal S. N.: 1958 (CA), Chernikov, A. A.: 1958 (CA) Federova, A. A.: 1956 Gayvoronsky, I. I.: 1949 Gorelik, A. G.: 1958 (SA) Khrgian, A. Kh.: 1956 (SA); 1953 (SA); 1953; 1952; 1952 (SA) A-5 Kimarat'yev, N. N.: 1959 ' Korneyev, A. N.: 1959 (SA); 1959 (CA) Kostarev, V. V.: 1958 (CA) KOtov, N. P.: 1958 Krutskaya, L. I.: 1958 Malkina, A. D.: 1958; 1957;' 1952 (SA) Marfenko, O. V.: 1952 (CA) Mazin, I. P.: 1958 (CA); 1956 (CA); 1953 (CA); 1952;1952 GONFIDENTIAj (CA) Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 Minervin, V. Ye.: 1958 (SA); 1956 Pinus, N. Z.: 1957; 1956; 1953 Reshchikov, A. A.: 1952 (SA) Reshetov, V. D.: 1959 a,b. Seregin, Ya. A.: 1958 Shmeter, S. M.: 1957 (SA); 1952 Shupyatskiy, A. B.: 1959 a,b; 1958; 1957 Shur, G. V.: 1957; 1957 (CA) Stepanenko, V. D.: 1958 Tonkova, Z. V.: 1952 (CA) Trubnikov, B. N.: 1959 (CA) Tsitovich, T. A.: 1959 Zak, Ye. G.: 1952 (SA) a,b; 1952 1949 (CA); Odessa Scientific Research Geophysical Observatory Structure of fog Akinov, M. N.: 1957 Scientific Research Institute of Hydrometeorological Instrument Construction, Moscow Instrument development Nepomnyashchiy, S. I.: 1959; 1958 State Hydrological Institute, Leningrad Chemical composition of precipitation Voronkov, P. P.: 1954 Sverdlovsk Geophysical Observatory Atmospheric electricity Paramonov, N. A.: 1956; 1950 a,b. Tashkent Scientific Research Geophysics Observatpry, Tashkent Atmospheric electricity Chernyayskiy, E. A.: 1957; 1954; 1948 Kazakov, G. I.: 1954 Kulagin, D. I.: 1955 alb; 1954; 1952; 1950 A-6 CONFIDENTIAL Approved for Release: 2018/01/30 006541158 Approved for Release 2018/01/30 006541158 CONFIDENTIAL Tbilisi Scientific Research Hydrometeorological Institute Tbilisi Thunderstorms, hail, cloud modification Bartishvili, I. T.: 1957 Gigineishvili, V. M. Kbmaladze, G. N.: 1959 Lominadze, V. P. Ukrainian Scientific Research Hydrometeorological Institute, Kiev (including Kiev Geophysical Observatory) Showers, thunderstorms, thunderstorm electricity, atmospheric electricity Muchnik, V. M.: 1958 a,blc; 1956 alb,c,; 1956 (SA); 1955 a,b; 1955 (CA); 1954 a,b; 1953; 1952 a,b,c1d; 1949 alb. CHIEF DIRECTORATE OF THE CIVIL AIR FLEET State Scientific Research Institute, Civil Air Fleet Shelkovinokov, M. S.: 1957 CHIEF DIRECTORATE OF THE NORTHERN SEA ROUTE Arctic and Antarctic Scientific Research Institute Stratified clouds, cloud modification MINISTRY OF THE CHEMICAL INDUSTRY Scientific Institute of Fertilizers and Insecto-Fungicides,Moscow Aerosols, fog formation Amelin, A. G.: 1956 (SA); 1955 (SA); 1951 Belyakov, M. I.: 1955 (CA); 1955 (CA) Fuks, N. A.: 1958 (SA); 1956 (SA) Yankovskiy, S. S.: 1958 (CA) A-7 CONFIDENTIAL Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 MINISTRY OF DEFENSE Air Engineering Academy imeni Mozhayskiy, Leningrad Ledokhovic, H. A.: 1957 (CA) Matveyev, L. T.: 1957 also identified with GGO Zaytsev, V. A.: 1957 (SA) also identified with GGO Department of Meteorological Service VVS (Airforce) Prokhodiko, M. P.: 1957 Snegerev, V. I.: 1957 MINISTRY OF ELECTRIC POWER STATIONS All Union Scientific Research Institute of Hydraulic Engineering Freezing bulk water Bibikov, D. N.: 1956 MINISTRY OF HIGHER EDUCATION Byelorussian State University imeni V. F. Lenina, Minsk (Formerly Minsk State University) Thunderstorm electricity Arabadzhi, V. I.: 1959; 1957 a,b; 1956 alb,c,d,e,f; 1955; 1953 alb,c; 1952; 1950 Irkutsk State University imeni A. A. Zhdanov, Irkutsk Chemical composition of precipitation. Votintsev, K. K.: 1954 Leningrad Hydrometeorological Institute, Leningrad Ice particles formation, precipitation, chemical composition of precipitation, Bowen theory on rainfall. Aleshina, G. I.: 1956 (CA) Belyashoval M. A.: 1956 (CA) Chili, A. V.: 1958 (CA) Dmitriyev, A. A.: 1958 (SA); 1958 (CA Approved for Release: 2018/01/30 006541158 Approved for Release 2018/01/30 006541158 ---a-5EFIDENT1241,� Kachurin, L. G.: 1959; 1956 a,b; 1956 a,b (SA); 1953; 1951 a,b; 1950 Kudravtseva, V. I.: � 1956 (CA) Lomanov, S. I.: 1956 (CA) NeStarova, M. I.: 1956 (CA) Serebryakova, A. A.: 1956 (CA) Seryakova, L. P.: 1956 (CA) Tverskaya, N. P.: 1958; 1956 (SA); 1954; 1953 alb; 1951; 1950; 1949 Yudina, N. P.: 1958 (CA) Zaytseva, N. A,: 1956 (CA) Zhavoronkina, T. K.: 1958 (SA) Leningrad State University imeni A. A. Zhdanov, Leningrad Atmospheric nuclei; chemical composition of precipitation; behavior of water and ice particles, convective clouds, hail, cloud modification. Bayandina, F. I.: 1956 (P) Breido, Ts. G.: 1956; 1955 Budyko, M. I.: 1957; 1946 (SA) Grabovskiy, R. I.: 1956; 1955; 1954; 1952 a,b,c; 1951 Kiryukhin, B. V. (Prof.): 1959 (CA); 1956; 1956 (SA); 1951 Lyapin, E. S.: 1946 (CA) Milin, V. B.: 1956 a,b (SA); 1954; 1953 (SA) Pevzner, S. I.: 1956 (CA) Tverskoy, P. N.: 1956 a,b (CA); 1954; 1949 a,b; 1948 (SA); 1947 a,b. Moscow Engineering Physics Institute Laboratory studies of convection cells. Laipiderskiy, V. I.: 1956 Moscow State University imeni N. V. Lomonosov, Moscow Freezing small water volumes; moisture transport and heat balance. Belyayev, F. I.: 1958 (CA); 1956 a,b (CA); 1950 a,b Kolesnikov, A. G.: 1958 (SA); 1956 a,b (SA) Raunner, Yu. L.: 1956 Rusanov, V. I.: 1956 Rostov State University Electrostatic precipitators Litvinov, V. F.: 1955 (CA) Litvinova, N. N.: 1955 (CA) A-9 �61911TIVEI4TDAT Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 006541158 CONFIDENTIAL. APPENDIX B LEADING CONTRIBUTORS TO SOVIET CLOUD PHYSICS PROGRESS On the basis of the available scientific literature it is possible to list Soviet scientists who have made important contributions to the various areas of research. Asterisks designate particularly productive scientists. 1. Atmospheric nuclei and precipitation chemistry S. A. Durov Ya. I. Frenkel *R. I. Grabovskiy (author of a book on this subject in 1956) N. S. Smirnov 2. Cloud droplet spectra and liquid-water contents in clouds. *A. Kh. Khrgian (author of book on physics of the atmosphere in 1953) I. P. Mazin Ye. S. Selezneva *Ye. B. Zak *V. A. Zaytsev 3. Raindrop spectra *I. V. Litvinov *N. V. Krasnogorskaya A. Ye. Mikirov 4. Ice crystals and snowflakes *Ye. B. Zak *A. D. Zamorskiy (author of book on subject in 1955) 5. Cloud formation and structure A. G. Amelin *A. P. Chuvayev N. I. Grishin *L. N. Gutman *N. V. Kolobkov (author of book on thunderstorms and squalls in 1951) V. S. Kozarin L. T. Matveyev K. S. Shifrin B-1 Approved for Release: 2018/01/30 006541158 Approved for Release: 2018/01/30 C06541158 �GeNFI-BENTLeir- *N. S. Shishkin (author of book on clouds, precipitation and thunderstorms in 1954) N. P. Timofeev *N. I. Vulf�son 6. Precipitation processes B. V. Deryagin *L. G. Kachurin B. V. Kiryukhin *L. M. Levin *V. Ya. Nikandrov P. S. Prokhorov *N. S. Shishkin (author of book on clouds, precipitation and thunderstorms in 1954) N. P. Tverskaya 7. Atmospheric electricity V. I..Arabadzhi Ts, G. Breydo *A. P. Chuvayev _Ya. I. Frenkel *I. M. Imyanitov (author of book on instruments and methods for studies of atmospheric electricity) P. L. Kapitsa N. V. Kolobkov *L. M. Levin *V. M. Muchnik *N. S. Shishkin I. S. Stekol'nikov (author of several books on lightning) P. N. Tverskoy a. Instruments I. M. Imyanitov N. V. Krasnogorskaya A. A. Ledokhovich B. F. Loch N. Z. Pinus V. A. Zaytsev 9. Radar meteorology M. F. Dolukhanov A. G. Gorelik V. V. Kostarev *V. M. Muchnik B-2 Approved for for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 CONFIDENTIAL *A. B. Shupyatskiy ic-D. M. VYsokovskiy 10. Cloud seeding ans weather control *A. P. Chuvayev *I. M. Imyanitov *V. Ya. Nikandrov P. N. Krasikov V. G. Morachevskiy V. V. Petrovich A. D. Solov'yev A. I. Voskresensky B-3 CONFIDENTIAL 116_ Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 APPENDIX C BIBLIOGRAPHY OF ARTICLES'REVIEWELCMARCH 19597TOEIFEBRUARY 1960 ALEKANDROV, E. L., 1959: Sixth All-Union Cloud Conference. Izvest, Akad. Nauk SSSR, Ser. Geofiz., no 10, 1526-1527. ANON., 1951: Artificial rain. Nauk i Zhizn'. v. 23, no 5, p. 51. BALABANOVA, V. N., N. Sh, BIBILASHVILI, A. I. KARTSIVADZE, B. V. KIRYUKHIN and G. K. SULAKVELIDZE, 1959: Experiments on the modification of cumulus clouds in the Alazani Valley. Izv. Akad. Nauk SSSR, Ser. Geofiz., no 2, 262-275. BASHKIROVA, G. M., and T. A. PERSHINA, 1956: Some data from observations of the shapes of snowflakes. Trudy Glavnoy Geofiz. Obs., no 57 (119), 19-35. BUKHIKASHVILI, A. V., 1958: Twenty-five years of the Institute of Geophysics, Academy of Sciences, Georgian SSR. Izv. Akad. Nauk SSSR, Ser. Geofiz., no 10, 1153-1161. CHESTNAYA) I. 1955: Fluctuations of the lower limit of stratus clouds. Trudy Glavnoy Geofiz. Obs., no 54, 24-30, CHUVAYEV, A. P., 1957a: An experiment in controlling the development of strongly convective clouds in northwestern European USSR. Trudy Glavnoy Geofiz. Obs., no 67 (129), 59-103. , 1957b: Modern possibilities for preventing storms and hail. Trudy Glavnoy Geofiz. Obs., no 74, 71-102. DENYAGIN, B. V. and S. S. DUKHIN, 1957: The influence of thermophoresis on the coagulation of droplets in clouds. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 6, 779-784. DMITRIYEV, A. A. and A. V. CHILI, 1958: On meteor showers and precipi- tation. Trudy Morskogo Gidrofiz, Inst., v. 12, 181-190. DRIVING, A. Ia. and A. I. SMIRNOVA, 1958: Clouds in the stratosphere. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 3, 337-346. DVALI, Ye. R., 1956: The electric field of the atmosphere during precipitation. Trudy Glavnoy Geofiz. Obs., no 58 (120) 69-74. C-1 _COLIEIDENT-14-1,� Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 _eettftvENTrzr-- FEDOROVI Ye. K., 1950: A word about atmospheric phenomena of electrical origin by Lomonosov and the present concept of atmospheric electricity. Izvest. Akad, Nauk SSSR, Ser. Geograf. i Moscow, V. 14, no 1, 25-36. 1958: Controlling weather and climate. Soviet Bloc International Geophysical Year Information, U.S. Department of Commerce. Office of Tech. Services, Aug. 15, 1958, p. 4-16. FEIGEL'SON, Ye. M., 1951: Radiational properties of stratus clouds. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 4, 92-117. GORELIX, A. G., V. V. KOSTAREV and A. A.'CHERNIKOV, 1958: Radar measurement of turbulent motions in clouds. Meteor. i Gidrol., no 5, 12-19, GRABOVSKIY, R. I., 1954: The formation of clouds and atmospheric precipitation. Priroda, no 10, 91-95 IMYANITOV, I. M., 1956: Methods of measuring the gradients of con- ductivity and ion concentration of the atmosphere. Trudy Glavnoy Geofiz. Obs., 58 (120), 3-7. 1 M. M. KULIK and A. P. CHUVAYEV, 1957: Preliminary data on experiments for controlling the development and the change in the electrical state of strongly convective clouds in the southern regions of European USSR and in the Transcaucasus. Trudy Glavnoy Geofiz. Obs., no 67 (129), 33-58. , and V. V. MIKHAYLOVSKAYA, 1958: Aircraft instrument for measuring charges of precipitation particles. Pribory i Tekh. Eks., no 2, 86-91. 9 p N. P. ZIGANOV and M. B. STREL'TSOVA, 1956: Instrument for long-term measurements of intensity of the atmospheric electric field under complex meteorological conditions. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 7, 1121-1127. KHIMACH, M. A., 1956: The precipitation of ice from supercooled clouds and fog. Trudy Glavnoy Geofiz. Obs., no 27 (119), 44-49 KOSTAREV, V. V., 1958: Experience in radar troposphere sounding. Trudy Tsentral. Aero.'Obs., no 20, 3-16. KRASIKOV, P. N. and G. A. CHIKIROVA, 1956: The microphysical characteristics of local fogs. Trudy Glavnoy Geofiz. Obs., no 57 (119), 88-100. C-2 CONFIDENTIAL Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 _CONPIREffilizikt 1 and N. V. MAMONTOV, 1957: Determining the sizes of particles isomorphous with ice used in experiments'of the phase transformation of water. Trudy Glavnoy Geofiz. Obs., no 67 (129), 144-152. KRASNOGORSKAYA, N. V., 1956: The results of measuring electric charges on precipitation particles in the free atmosphere. Izvest. Akad, Nauk SSSR, Ser. Geofiz., no 7, 844-852. LAKTIONOV, A. G., 1958: Distribution of aerosol particles in the free atmosphere. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 3, 419-421. LEBEDEVA, N. V., 1955: Consideration of the role of dynamic turbulence in the development of convection. Meteor. i. Gidrol., no 2, 21-26. LEDOKOVICH, A. A. and V. A. ZAYTSEV, 1956: Remote measurement of air temperature and humidity from airplanes. Trudy Glavnoy Geofiz. Obs., no 63 (125), 177-183. LEVIN, L. M. 1957: The intake of aerosol samples. Izvest. Akad, Nauk SSSR, Ser. Geofiz., no 7, 87-101. LITVINOV, I. V., 1957: The distribution function of liquid particles in rainfall. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 6, 838-839 1958: The origin of multilayered hailstones. Izvest. Akad. Nauk SSSR, Ser. Geofiz.) no 2, 277-279 LOCH, B. F., 1956a: Narrow-sector recording of atmospherics. Trudy Glavnoy Geofiz. Obs., 58 (120)) 42-46 1956b: Experimental observations on the number of storm discharges. Trudy Glavnoy Geofiz. Obs., 58 (120), 47-52. MANUA, E. F. and Ye. K. i,EDCROV, 1957: The water balance of a cloud system. Izvest. Akad. Nauk SSSR) Ser. Geofiz., no 5, 658-663. MIKIROV, A. E., 1957: Measurement of particle size distribution in clouds and fog. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 4, 512-515. MINERVIN, V. Ye.) 1956: Concerning measurements of moisture and ice in supercooled clouds and some errors in these measurements. Trudy Tsentral. Aero. Obs., no 17, 15-35. MUCHNIK, V,HM.� 1952: Electrification in the collision of balls and drops in an electrical field. Trudy Glavnoy Geofiz. Obs., 35, no 97) 35-41. 0-3 Approved for for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 eetientrnirr-- 1955: Relation of storm formation to the intensity of precipitations. Meteor. i Gidrol., no 9, 31-33. , 1956a: The nature of the thunderstorm. Nauka i Zhizni, v. 23, no 6, 41-43 , 1956b: On possible electrification mechanism of hydrometeors in cumulus rain clouds. Trudy Glavnoy Geofiz. Obs., 58 (120), 53-57. , 1958a: Detection of thunderstorm and rainstorms by the radar of a storm identification station. Trudy Tsentral, Aero. Obs., no 20, 73-80 , ) 1958b: Some radar characteristics of rainstorm and thunderstorm cells. Trudy Tsentral. Aero. Obs., no 20, 82-87. MYAKISHEV, G. Ya., 1958: Artificial precipitation. Nauka i Zhizn', no 4, 77-78. ' NEPOMNYASHCHIY, S. I., 1959: New airplane meteorograph for vertical sounding of the atmosphere. Meteor. i Gidrol., no 1, 51-54. NIKANDROVA, G. T. and A. P. CHUVAYEV, 1957: Investigation of the transition in cloud microstructure under modification by solid carbon dioxide. Trudy Glavnoy Geofiz. Obs., no 67 (129)2 104-113. PARAMONOV, N. A., 1950: The unitary variation of atmospheric electrical potential. Dokl. Akad. Nauk SSSR, v. 90, no 1, 37-38. PROKHOROV, P. S. and L. F. LEONOV, 1952: The effect of a saturation deficit on the process of collision and coalescence of water drops. Kolloid Zhur., 14/ no 1, 66-72. PSHENAY-SEVERIN, S. V., 1957: Effect of hydrodynamic interaction between small cloud drops upon their falling speed. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 8, 1945-1051. PUZANOV, V. P. and V. I. AKKURATOV, 1952: The mechanism of formation of certain types of hailstones. Meteor. i Gidrol., no 2, 29-33. REYNET, Ya, Yu., 1956: A combination meter for atmospheric ions. Trudy Glavnoy Geofiz, Obs., 58 (120), 23-30. SALEZNEVA, Ya. S., 1953: Conditions that determine the quality of cumulus clouds. Meteor. i Gidrol., no 2, C-4 Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 SERGIYEVA, A. P.-, 1958: The electric charges of cloud particles. Izvest, Akad. Nauk SSSR, Ser. Geofiz., no 3, 347-357. SHISHKIN, N. S., 1954: Dimensions of rain drops. Priroda, no 10, 90-92. , 1955a: Effect of size distribution of cloud particles on the size of rain drops. Trudy Glavnoy Geofiz. Obs., no 54 (116) 78-80. � 1955b: Using the layer method for forecasting the vertical force of convective clouds. Trudy Glavnoy Geofiz. Obs., no 54, 96-103. � 1956a: Investigations of clouds yielding precipitation in the form of snow. Trudy Glavnoy Geofiz. Obs., no 57 (119)) 11-112. 1956b: Some results of research on thunderclouds and cloudbursts. Trudy Glavnoy Geofiz, Obs., no 63 1125), 3-21., MAL', V. and V. MORACHEVSKIY, 1958a: Is it possible to actively influence the weather: .Sovetskaya Aviatsiya (a newspaper), Feb 8, p. 4. 1958b: Active influence on the weather. Priroda� V. SHUPIATSKIY,' A. B., 1958: and the water content Obs., no 20, 56-66. 47, no 90 85-88. Radar measurements of the mean drop size in heavy rainstorms. Trudy Tsentral. Aero. SHVETS, M. E., 1955: Condensation of water vapor in the atmosphere. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 6, 547-551. SMIRNOV, N. S.; 1956: The problem of the effect of an atomic explosion on the state of the atmospheric. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 10, 1227-1231. SOKOLOV, V.; 1958: Weather observations by radar. Sovetskaya Aviatsiya, no 274, Nov 22, p. 3. SOLOV'YEVI V. A.; 1956: On one method of measuring the charges and size of cloud (fog) droplets. Trudy Glavnoy Geofiz. Obs., 58 (120), 31-41. C-5 Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 �COTTMENTI*L� STEPANENKO, V. D.0 1958: Improving the meteorological target detection efficiency of the "Kobal't" radar. Trudy Tsentral. Aero. Obs., no 20, 67-72. TSYGANOV, G. P., 1957: Experience of meteorological servicing of tower control area and utilization of radar station "RUPOR" at the air weather station of the Civil Air Fleet at Rostov-on-Don. Meteor. i Gidrol., no 6, 46-47. TVERSKAYA, N. P., 1951: The temperature of evaporating drops. Izvest. Akad. Nauk SSSR, Ser. Geograf. i Geofiz., 15 (1), 74-81. , 1953: Heat transfer and evaporation of a drop in a current. Izvest. Akad. Nauk SSSR, Ser. Geofiz.', no 3, 259-263. VOSKANOV, A. I., I. M. IMYANITOV, M. M. KULIK and A. P. CHUVAYEV, 1957: The possibility of safe passage of aircraft through thunder- storm areas. Trudy Glavnoy Geofiz. Ohs., no 67 (129) 114-120. VOSKRESENSKIY, A. I., V. G. MORACHEVSKIY and V. Ya. NIKANDROV, 1957: The use of dry ice for dispersing clouds in the Arctic. Problemy Arktiki, sbornik statey (Problems of the Arctic, A Collection of Articles), no 2, Leningrad, 133,-139. VOTINTSEV, K. K., 1954: Chemical composition of the waters from atmospheric precipitation in the Baykal Area. Dokl. Akad. Nauk SSSR, v. 95, no 5, 979-981 VUL'FSON, N. I., 1953: Method of study of convective movements in the free atmosphere. Doklady Akad. Nauk SSSR, v. 91, no 2, 233-236. , 1956a: Conditions of formation of cumulus clouds in mountainous regions. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 7, 821-830. � 1956b: Method of studying convective movement in the free atmosphere. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 5, 549-561. , 1954: Convective movements in cumulous clouds. Dikl. Akad. Nauk SSSR, 97, no 1, 77-80 ZHAVORONKINA, T. K., 1958: The chemical composition of atmospheric precipitation. Meteor. i Gidrol., no 9, 22-24. / and A. A. DMITRIYEV, 1958: The distribution of concentration of chlorine in atmospheric precipitation over a continent. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 3, 330-336. C.6 CONFIDENTIAL Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 �CONFIBBN:24AL APPENDIX D BIBLIOGRAPHY OF ARTICLES IDENTIFIED BUT NOT AVAILABLE FOR COMPLETE REVIEW This list supplements previously published bibliographies. ANON., 1956: Aircraft radar fOr weather observations. Voprosy Radiolokatsionnoy Tekhniki, no 1. 1 1958a: Weather observations by radar. Sovetskaya Aviatsiya, Nov 22, 1958, p. 4. , 1958b: Aircraft breaks up thunderstorm. Sovetskaya Aviatsiya, Aug. 13, 1958,q6. 4. , 1959: Artificial atmospheric precipitations: Vest. Akad. Nauk SSSR, no 7, July 1959, p. 70. ARABADZHI, V. I., 1959: On the electrical properties of thunderstorm precipitation. Dokl. Akad. Nauk SSSR, 127, no 2, 298-301. BALABANOVA, V. N., 1959: Effects of temperature of supercooled fog ,on crystallization by silver iodide aerosols. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 6, 924-929. BARANOV, A. M., 1958: The vertical expansion of clouds of the upper layer over the European part of the USSR. Meteor. i Gidrol., no 6, 22-25. BARTISHVILI, I. T., 1957: On methods of measuring precipitation in mountain conditions. Trudy, Tbilisskogo NauChno-Issled. Gidrol. Inst.Orypusk no 2, 189-203. BEKTOROV� A. B., 1958: Magnesium chloride in the Salfe Lakes of northern Kazakhstan. Vast. Akad. Nauk Kazakhskoy SSSR, no 5, 6&73, BIBILASHVILI, N. Sh., A. M. ZAYTSEVA, A. A. ORDZHONIKIDZE, and G. K. SULAKEVELIDZE, 1959: Influence of changes in the vertical component of wind velocity on the formation of intensive showers and hail. Dokl. Akad, Nauk SSSR, 128, no 3, 521-524. BOCHAROV, Ye, I., 1958a: The special transparency of the clouds. Izvest. Akad, Nauk SSSR, Ser. Geofiz., no 5, 678-685, D-1 Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 OnNFTMINTTAI. 1 1958b: The attenuation of infrared radiation by water mists. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 5, 791-795. BRITAYEV, A. A. and A. N. KORNEEV, L959: Growth of ice crystals by coalescence. Trudy Tsentral. Aero. Obs., no 30, 73-80. CHIRVINSKIY, P. N., 1954: The first observers of ball lightnings. Priroda, V. XLIII no 8, p. 116. CHUVAYEV, A. P., 1957: Experiment in controlling the development of powerful convective clouds over large areas. Trudy Glavnoy Geofiz. Obs., no 72, 127-133. DERGACH, A. L., 1959a: The microphysical characteristics of a low cloud cover and fog. Trudy Arctic and Antarctic Sci. Res. Inst., v. 228, no 1, 55-67. 1 1959b: The results of the study of ,frontal clouds. Trudy Arctic and Antarctic Sci. Res. Inst., v. 2280 ho. 1, 100-112. 1 1959c: Study of a cumulonimbus cloud without an anvil. Trudy Arctic and Antarctic Sci. Res. Inst., v. 228, no 10 148-154., DRIVING, A. Ya., N. V. ZOLOTAVINA, M. N. POCOZOVA and A. L. SM1RNOVA, 1958: Investigation_of atmospheric stratification and con- densation products by searchlight sounding. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 5, 613-624. FEIGEL'SON, Ye. M., 1959: The radiational cooling of stratus clouds. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 6, 847-857. GROMOVA, T. N. and A. D. SOLOV'YEV, 1958: Laboratory equipment for analyzing artificial fogs. Trudy Tsentral. Aero. Obs., no 19, 101. INYANITOVI I. M., V. P. KOLOKOLOV, 1956: Investigating the distribution of induced and free electrical charges on aircraft surfaces. Trudy GlavnoyGeofiz. Obs., p. 8-16. IZERGIN, A. M., 1959: Convective electrical currents atmosphere- earth. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 6, 919-923. KACHURIN, L. G., 1956: The formation of glazed frost and hoar frost in supercooled fog. Trudy Glavnoy Geofiz. Obs., no 57 (119) D-2 CONFIDENTIAL Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 �ekeliKpggrziL__ , 1959: Comparison between various evations for freezing of supercooled water aerosols. Izvest. Akad, Nauk SSSR, Ser. Geofiz., no 1, 122-130. , G. I. ALESHINA, M. A. BELYASHOVA, V. I. ZALIVINA, V. I. KUDRYAVTSEVA, M. I. NESTEROVA, A. A. SEREBRYAKOVA, and L. P. SERYAKOVA, 1956: Analysis of the precipitation zones of stratiform frontal clouds. Trudy Lenin. Gidrometeor. Inst. no 5-6, 208-241. KHMALADZE, G. N., 1959: Scientific session at the Tbilisi Scientific Research Hydrometeorological Institute. Meteor. i Gidrol., no 2, 70-71. KLINOV, F. Ya., 1958: Polar snow. Izvest. Akad. Nauk SSSR, Ser._ Geofiz., no 5, 796-799. , 1957: Ice crystals and ice mists in the atmosphere. Priroda, no 2. KOGAN-BELETSKIY, G., 1958: About encounters with electric storm and hail during flights at high altitudes. Sovetskaya.AViatsiya, July 291 1958, p. 2 KONDRAT'YEV, N. N., 1959: Methods and some results of base line phototheodolite clouds. Trudy Tsentral Aero. Obs., no 30, 84-94. KORNEYEV, A. N. AND B. N. TRUBNIKOV, 1959: Application of the replica method in the study of cloud elements. Trudy Tsentral, Aero. Obs. no 30, 81-83. KOTOV, N. F., 1958: Use of the results of radar studies of clouds for improving the work of the network of storm warning stations. Trudy Tsentral, Aero. Obs., no 20, 17-25. KRASIKOV, P. N. and I. M. DIANOV, 1959: An artificial rainmaking method. Byulleten' Izobreteniy, no 5, 49. KRUTSKAYA, L. I., 1958: Methods for computing the number of ice nuclei forming under the action of cooling reagents. Trudy Tsentral. Aero. Obs., no 19, 81-100. LEDOKHOVICH, A. A. and V. A. ZAYTSEV, 1959: An air-borne electrical meteorograph (SEM-1). Trudy Arctic and Antarctic Set. Res. Inst., V. 228, no 1, 162-167. D-3 CONFIDENTIAL Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 IAL LEVIN, L. LI 1958a: Fluctuations of microstructural characteristics of clouds. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 12, 1510-1513. , 1958b: On the size distribution functions of cloud droplets. Optical density of a cloud. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 10, 1211-1221. 0�����������=I , 1959: Electrostatic deposition of aersol particles from flow over large bodies. Izvest. Akad. Nauk SSSR. Ser. Geofiz., no 7, 1073-1075. LITVINOV, I. V., 1959: Method for measuring the distribution of size of snowflakes. Izvest. Akad, Nauk SSSR� Ser. Geofiz., no 7, 1011-1017. MAKHOTKIN, L. G., 1959: On C. G. Breydo's formula for the limiting charge on drops. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 2, 330-331. 1 and V. A. SOLOV'YEVI 1958: Role of electric charges in the coagulation of fog drops. Trudy Glavnoy Geofiz. Obs., no 73, 116-122. MATVEYEVI L. T., 1959a: On the theory of cloud formation and con- densation trails under the influence of mixing. Meteor. i Gidrol., no 3, 3-9. 1959b: Several questions on the theory of the formation and evolution of stratiform clouds. Trudy Arctic and Antarctic Sci. Res. Inst., v. 228, no 1, 14-37. MIKIROV, A. Ye., 1959: On small angles of the scattering indicatrix. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 2, 228-295. MIN, V. B., 1954: About the anomalous electric fields in the atmosphere. Dokl. Akad. Nauk SSSR, v. XCV� no 5, 983-986. MINERVIN, V. Ye., I. P. MAZIN and S. N. BUIKOVSKAYA, 1958: New data on the water content of clouds. Trudy Tsentral. Aero. Obs., no 19, 3-32. MORACHEVSKM V. G. and V. Ya. NIKANDROV, 1959: The effectiveness of CO2 particles and AgI smoke in dissipating supercooled low clouds and fog. Trudy Arctic and Antarctic Sci. Res. Inst.; v. 228, no 1, 135-145. NASILOV, D. N., 1956: Radio meteorology. (No other information available.) D-4 CONFIDENTIAL Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 NEPONVYASHCHIY0 S. I., 1958: Meteor. i Gidrol., no 6, NIKANDROV, V. Ya., 1959: Some Arctic. Trudy Arctic and 146-148. Comb-type radiosonde with electric motor. 47-49. data on the water content of fog in the Antarctic Sci. Res. Inst., v. 228; no 1, PINUS, N. Z., 1957: Atmospheric turbulence commensurate with dimensions of airplanes. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 3, 395-400. PIOTROVICH, V. V., 1958: On the reasons for the increase of the crystals of "intra-water" ice in overcooled water. Meteor. i. Gddrol., no 12, 42-43, PSHENAY-SEVERINI S. V., 1958: Hydrodynamics interaction of cloud drops at short distances. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 10, 1254-1257. , 1959: On the mutual approach of aerosol particles in a sound field due to Oseen's hydrodynamic forces. Dokl. Akad. Nauk SSSR, 125, no 4, 775-778. PUDOVKINA, I. B., 1954: A study of atmospheric electricity on the Elbrus, Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 3, 288-292. RESEE10V, V. D., 1959a: Investigation of unipolar aerosol charges. Trudy Tsentral. Aero. Obs., no 30, 53-61. � 1959b: Problem of atmospheric electricity and aerosols. Trudy Tsentral, Aero. Obs., no 30, 62-72, ROVINSKIY, F. Ya.� 1959: New method for registration of water droplets. Izvest. Akad. Nauk SSSR Ser. Geofiz., no 7, 1076-1078. SEREGIN, Yu, A., 1958: Dispersion from the earth of supercooled fogs by silver iodide aerosol. Trudy Tsentral. Aero. Obs., no 19, 68-80. SERGIYEVA, A. P., 1959: Electrical charges of cloud droplets. Izvest. Akad. Nauk SSSR, Ser. Geofiz., no 7, 1018-1025, SHIFRIN, K. S. and Yu. I. RABINOVICH, 1957: The spectral indicatrices of large water drops and the spectral polarization of rainbows. Izvest. Akad. Nauk SSSR Ser. Geofiz., no 12, 1491-1506. D-5 Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 SHPAK, I. S., and L. P. MURZIN, 1957: A squall in the region of the Tsimla Reservoir on 25 June 1956. Meteor. i Gidrol., no 4, 28-30. 645360. SHUPYATSKIY, A. B., 1959a: Determining the shape and speed of falling drops. Meteor. i Gidrol., no 5, 42-43. 1959b: Radar scattering by nonspherical particles. Trudy Tsentral. Aero. Obs., no 30, 39-52. SULAKUELIDZE, G., 1959: Microphysical traps dropped from airplane. Sovetskaya Avlatsiya, July 1, 1959, p. 4. TKACHENKO, A. V., 1958: Use of the layer method for forecasting the convective cloud cover of cloudbursts and thunderstorms. Meteor. i Gidrol., no 9, 24-27. TSITOVICH, T. A., 1959: On the formation of the subfrontal portions of warm frontal cloud systems. Trudy Tsentral Aero. Obs., no 30, 3-38. TVERSKAYA, N. P., 1958: Study of the collision and coalescence of charged drops. Trudy Glavnoy Geofiz. Obs.� no 73, 123-131. , and N. P. YUDINA, 1956: Experimental investigation of water-drop conjoining. Trudy Lenin. Gidrometeor. Inst., no 5-6, 263-267. VASIL�CHENKO, I. V., 1958: Calculations of the characteristics of a convective cloud stream. Trudy Glavnoy Geofiz. Obs., no 82, 22-25. VOLKOV, P. A., 1958: On the mechanism of breakage of air bubbles. Meteor. i Gidrol.� no 12, 38-40. VORONTSOV, P. A., 1959: The aerological characteristics(of sea fog. Trudy Arctic and Antarctic Sci. Res. Inst., V. 228, no 10 38-54. , and.V. I. SELITSKAYA, 1959: The vertical structure of summer fog in the Kickson Island region. Trudy Arctic and Antarctic Sci. Res. Inst., v. 228, no 1, 87-99. VOSKRESENSKIY, A. I., 1959: Organization and methods of studying fog and clouds. Trudy Arctic and Antarctic Sci. Res. Inst., v. 228, no 1, 5-13. D-6 T_AL Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 VOSKRESENKIY, A. 1.4959 and K. I. CHUKANIN, 1959: The meteorological conditions of icing in St and Sc clouds. Trudy Arctic and Antarctic Sci, Res. Inst., Vol. 228, no 1, 124-134. 1 and A. A. LEDOKHOVICH, 1959: The Lo-4 thermohygrometer. Trudy Arctic and Antarctic Sci. Res. Inst., Vol. 228, no 1, 168-175. ) and V. G. MORACHEVSKIY, 1959: Equipment for seeding supercooled clouds and fog from an airplane. Trudy Arctic and Antarctic Sci. Res. Inst., Vol. 228, no 1, 155-161. VULiFSON, N. I., 1959: On the mechanism of instability release in the free atmosphere. Dokl. Akad. Nauk SSSR, 126, no 6, 1244-1247. ZABRODSKIY, G. M. and V. G. MORACHEVSKIY, 1959: A study of the trans- parency of clouds and fog. Trudy Arctic and Antarctic Sci. Res. Inst., Vol. 228, no 1, 68-86. ZAK, Ye. G. and A. A. FEDOROVA, 1958: Results of radar observations of formation and development of precipitation in cumulonimbus clouds. Trudy Tsentral Aero. Obs., No. 19, 33-67. ZAMORSKIY, A. D., 1953: Drizzle and glazed frost at low temperatures. Meteor. i Gidrol., No. 4, ZAYTSEV, V. A., and A. A. LEDOKHOVICH, 1959: The temperature near the upper boundary of air mass fogs and stratus clouds. Trudy Arctic and Antarctic Sci. Res. Inst., Vol. 228, No 1, 113-123. D-7 -eati-H-BRE-TAL- Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 �CONEIDEMPZ415-- UNCLASSIFIED REFERENCES 1. Izvestiya Akademii Nauk SSSR Seriya Geofizicheskaya, no 10, Oct 59, pp 152 -1527, 2. FBIS, USSR, L5598, 18 Jun 1958, 3. The Status of Research and Man ower in Meteorology, Washington, Publication 75 S-NRC 19 4. Imyanitov, I. M., Instruments and Methods for Study of Atmogheric Electricity, Gostekhizdat, 1957, pp. 483, U 5. Muchnik, V. M., 1958: Detection of Thunderstorms and Rainstorms by the Radar of a Storm Irtifli.cation Station. Trudy Tsentral. Aero. Obs., No. 20, 78-80 (b)(3 6. Muchnik, V. M., 1958: Some Radar Characteristics of Rainstorm and Thunderstorm Cells. Trudy Tsentral. Aero. Obs., No. 20, 82-87F--] (b)(3 7. Stepanenko, V. D., 1958: Improving the Meteorological Target Detection Efficiency of the "Kobalgt" Radar. Trudy Tsentral. Aero., Obs No. 20, 67-72; (b)(3 0,1)9, 8. Kostarev, V. V., 1958: Experience in Radar Troposphere Sounding. Trudy Tsentral. Aero. Obs., No. 20, 3-1 9. Sokolov, V., 1958: Weather Obse � ns by Radar. Sovetskaya Aviatsiya, No, 274, No. 22, p. 3 10. Vysokovskiy, D. M., 1952: Dispersion and Absorption of Microradio Waves in Atmospheric Formations (rain, snow, cloudiness and fog) and Radio Location, Uspekhi Fiz. Nauk., 47, 11. Shupyatskiy, A. B., 1958: Radar Measurements of the Mean Drop Size and the Water Content in Heavy Rainstorms. Trudy Tsentral. Aero. Obs., No. 20, 56-66, 12. Gorelik, A. G., V. V. Kostarev and A. A. Chernikov, 1958: Radar Measurement of Turbulent Motions in Clouds..i Meteor. i Gidrol., No. 5, 12-19, 13. Imyanitov, I. M., M. M. Kulik and A. P. Chuvayev, 1957: Preliminary Data on Experiments for Controlling the Development and the Change in the Electrical State of Strongly Convective Clouds in the Southern Regions of European USSR and in thfrarscaucasus. Trudy Glavnoy Geofiz. Obs., No. 68 (129), 33-58, R-1 ---corrirmtmam, (b)(3) (b)(3) (b)(3) (b)(3 (b)(3 (b)(3 (b)(3 (b)(3 (b)(3 Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 14. Chuvayev, A. P., 1956: On the Conditions that are Favorable to Artificially Induced Precipitation from Large Cumulus Clouds. Meteor. i Gidrol., No. 11, 15-20 15. Voskanov, A. I., I. M. Imyanitov, M. M. Kulik and A. P. Chuvayev, 1957: The Possibility of Safe Passage of Aircraft Through Thunderstorm Areas, Trudy Glavnoy Geofiz. Obs., No. 67 (129) 114-120, 18. Imyanitov, I. M., M. M. Kulik and A. P. Chuvayev, 1957: Investi- gations of Thunderstorm Zones in the Southern Regions of European USSR and the Transcaucasus. Trudy Glavnoy Geofiz. Obs., No. 67 (129), 3-32, 19. Gordon, J. Z., 1951: Investigation of the Eva oration Process of Dry Ice. Trudy Glavnoy Geofiz Obs., No. 013, 21. Sovetskiy Plot, 3 Jan 1957, 22. Lebedeva, N. V., 1955: How are Clouds and Rain Formed? All- Union Society for the Propagation of Political and Scientific Knowledge, Moscow, "Znaniyen Publishing House, pp 24, 23. Nikandrov, V. Ya., 1957: The Problem of the Artificial Control of Cloud and Fog, presented at the IUGG meeting in Toronto, Canada, Mimeographed in English, pp. 13 24. OTS, PB 131632-27, 15 Aug 58, Soviet Bloc International Geophysical Year Information, p. 9 25. Belolserkovskiy, V. 1958: Three Days Fight with Clouds, Moskva, No 9, pp 160-170 26. Golikov, A., 1960: Sun in the Fog, Ogonek, No 6, 27. Pettersen, S. et al, 1957: Cloud and Weather Modification -- A Group of Field Experiments, Meteorological Monographs, no 11, July, p. 93, 28. Solov'yev, V. A., 1956: On the method of measuring the charges and size of cloud (fo) droplets. Trudy Glavnoy Geofiz. Obs., 58 (120), 31-41 29. Myakishev, G. Ya., 1958: Artificial Precipitation. Nauka i Zhizn', No. 4, 77-78, R-2 NFIDENTIAL (b)(3) (b)(3) (b)(3) (b)(3) (b)(3) (b)(3) (b)(3) (b)(3) (b)(3) (b)() (b)(3) (b)(3) (b)(3) Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 CONFIDENTIAL 30. Balabanova, V. N., N. Sh. Bibilashvili, A. I. Kartsivadze, B. V. Kiryukhin and G. K. Sulakvelidze, 1959: EXperiments on the Modification of Cumulus Clouds in the Alazani Valley. Izv. Akad. Nauk SSSR, Ser, Geofiz., No. 2, 262-275, 31. Shtal�, V. and V. Morachevskiy, 1958: ' Is it Possible to Actively Influence to Weather? Sovetskaya Aviatsiya, 8 Feb, p. 4, 32. Shtal', V. and V. Morachevskiy, 1958: Active Influence on the Weather. Priroda, Vol. 47, No. 9, 85-88, 34. Bukhikashvili, A. V., 1958: Twenty-five Years of the Institute of Geophysics, Academy of Sciences, Georgian SSR. Izv. Akad. Nauk SSSR, Ser. Geofiz., No, 10, 1153-1161, 35. Voskresenkiy, A. I., V. G. Morachevskiy and V. Ya. Nikandrov, 1957: The use of Dry Ice for Dispersing Clouds in the Arctic. Problems of the Arctic, _A Collection of Articles, No. 2, Leningrad, 133-139�1----- (b)(3 (b)(3 (b)(3 (b)(3 (b)(3 36. Morachevskiy, V. G. and V. Ya, Nikandrov, 1959: The Effective- ness of CO2 Particles and AgI Smoke in Dissipating Supercooled Low Clouds and Fog. Trudy. Arcrc and Antarctic Sci. Res, Inst., Vol. 228, No. 1, 135-145,1 (b)(3 37. Chuvayev, A. P., 1957: Modern Possibilities for Preventin Storms and Hail. Trudy Glavnoy Geofiz. Obs., No. 74, 71-102 (b)(3) R-3 'ENTIAL Approved for Release: 2018/01/30 C06541158 Approved for Release: 2018/01/30 C06541158 CONFIDENTIAL Approved for Release: 2018/01/30 C06541158