THE SOVIET ATOMIC ENERGY PROGRAM

i-,-1!"1' I Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: IA-R DP79R01012A022200020001-4 RET whenttachtil to Top Secret Document ? Automatically downgraded to bkIt.:11,LT wnen nuen in iorm is aetacned from controlled document. CONTROL AND COVER SHEET FOR TOP SECRET DOCUMENT . DOCUMENT DESCRIPTION SOURCE DOC. NO. DOC. DATE COPY NO. NUMBER OF PAGES NUMBER OF ATTACHMENTS C IA/JAE IC 0038001 NIE 11-2A-63 rec. 2 Oct 1963 dtd. 2 July 1963 cy# M,2 66 pages total none REGISTRY CIA CONTROL NO. DATE DOCUMENT RECEI'ijO 4 LOGGED BY ATTENTION: This form will be placed on top of and attached to each Top Secret document received by the Central Intelligence Agency or classified Top Secret within the ,CIA and will remain attached to the document until such time as it is downgraded, destroyed, or transmitted outside of CIA. Access to Top Secret matter is limited to Top Secret Control personnel and those individuals whose official duties relate to the matter. Top Secret Control Officers who receive and/or release the attached Top Secret material will sign this form and indicate period of custody in the left-hand columns provided. Each individual who sees the Top Secret document will sign and indicate the date of handling in the right-hand columns. REFERRED TO RECEIVED RELEASED SEEN BY OFFICE SIGNATURE 1 DATE TIME DATE TIME SIGNATURE OFFICE/DIV. 1 DATE dT d? 3- OCT i 1963 3 - OCT 13 STAT to i-Ve=" 8001 196: STAT 0/il ?,y- ocici NOTICE OF DETACHMENT: When this form is detached from Top Secret material it shall be completed in the appropriate spaces below and transmitted to Central Top Secret Control for record. DOWNGRADED DESTROYED DISPATCHED (OUTSIDE CIA) TO By (Signature) TO BY (Signature) WITNESSED BY (Signature) BY (Signature) OFFICE DATE OFFICE ......"-.._ DATE OFFICE DATE Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 (40) r MYEN Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Tops NIE 11-2A-63 2 JULY 1963 TS 0038001 NATIONAL INTELLIGENCE ESTIMATE NUMBER 11-2A-63 The Soviet Atomic Energy Program LIMITED DISTRIBUTION Submitted by the DIRECTOR OF CENTRAL INTELLIGENCE Concurred in by the UNITED STATES INTELLIGENCE BOARD As indicated overleaf 2 JULY 1963 TOP SE Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 1 q Copy No 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TOP SECRET This estimate was prepared and agreed upon by the Joint Atomic Energy Intelligence Committee which is composed of representatives of the Central Intelligence Agency and the intelligence organizations of the Departments of State, Defense, the Army, the Navy, the Air Force, AEC, NSA, and FBI. Concurring: Director of Intelligence and Research, Department of State Director, Defense Intelligence Agency Assistant Chief of Staff for Intelligence, Department of the Army Assistant Chief of Naval Operations (Intelligence), Department of the Navy Assistant Chief of Staff, Intelligence, USAF Director for Intelligence, Joint Staff The Atomic Energy Commission Representative to the USIB Director of the National Security Agency Abstaining: The Assistant Director, Federal Bureau of Investigation, the subject being outside of his jurisdiction. 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. GROUP 1 Excluded from automatic downgrading and declassification TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 I Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TOP SECRET NATIONAL INTELLIGENCE ESTIMATE THE SOVIET ATOMIC ENERGY PROGRAM NUMBER 11-2A-63 2 JULY 1963 This estimate supersedes NIE I1-2A-62, 16 May 1962. This estimate was prepared and agreed upon by the Joint Atomic Energy Intelligence Committee, which is composed of representatives of the Departments of State, Army, Navy, Air Force, the Atomic Energy Commission, the Defense Intelligence Agency, the National Security Agency and the Central Intelligence Agency. The representative of the Federal Bureau of Investigation abstained, the subject being outside his jurisdiction. TOP SECRET TS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 I Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TOP SECRET TABLE OF CONTENTS Page THE PROBLEM 1 PRINCIPAL CONCLUSIONS 1 SUMMARY 4 DISCUSSION I. ORGANIZATION OF THE SOVIET ATOMIC ENERGY PRO- GRAM 25 II. NUCLEAR REACTOR PROGRAM Research and Testing Reactors 27 Nuclear Electric Power Program 27 Marine Nuclear Propulsion Systems 28 Aerospace Applications 29 III. FISSIONABLE MATERIALS PRODUCTION Uranium Ore Procurement 32 Uranium Feed Materials 33 Plutonium-Equivalent Production 34 U-235 Production 35 Other Nuclear Materials 38 IV. SOVIET NUCLEAR WEAPONS PROGRAM Nuclear Weapon Rearch and Development Installations 39 Weapon Development Program 41 Low-Yield Devices 41 Theromonuclear Weapon Developments 42 High Altitude Tests 43 Nuclear Weapons and Systems 44 Delivery Systems Information 44 Weapon Production and Stockpiling Sites 45 National Assembly-Stockpile Sites 47 Operational Storage Sites 47 Military Regional Depots 48 IRBM/MRBM Support 48 ICBM Support 48 Naval Nuclear Weapon Storage 49 TOP SECRET IS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 ii TOP SECRET Page Soviet Nuclear Weapon Storage in the European Satellites 49 Logistics 49 Command and Control 50 V. FUTURE WEAPON DEVELOPMENT AND TESTING 51 VI. SOVIET TECHNICAL CAPABILITIES IN SCIENTIFIC FIELDS RELATED TO NUCLEAR ENERGY 53 ANNEX A: EVALUATION OF SOVIET NUCLEAR TESTS (29 Au- gust 1949-25 December 1962) 57 LIST OF TABLES Page TABLE II. Estimated Soviet Fissionable Materials Production . . 12, 37 TABLE III. Soviet Research Reactors and Reactor Experiments . 14 TABLE IV. Soviet Nuclear Power Stations and Experimental Cen- ters 18 TABLE V. Estimated Characteristics of Soviet Nuclear Sub- marines 20 TABLE VI. Soviet Heavy Water Production 39 LIST OF MAPS Page FIGURE 1. Nuclear Weapon Research and Test Areas - 7 FIGURE 2. Nuclear Materials Production Sites 21 FIGURE 3. Soviet Nuclear Electric Power Reactor Sites 23 TS 0038001 TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TOP SECRET 1 THE SOVIET ATOMIC ENERGY PROGRAM THE PROBLEM To estimate the current status and probable future course of the Soviet atomic energy program to mid-1968. PRINCIPAL CONCLUSIONS Nuclear Testing and Technology 1. The Soviets have a highly developed nuclear weapon tech- nology which differs in design philosophy and emphasis from that of the West. They have tested thermonuclear devices in very high yields (up to 63 megatons) well above any in Western ex- perience, and in this range have achieved an outstanding yield-to- weight performance. They have also shown an excellent per- formance in thermonuclear devices of lower yields, down to about two megatons. In the submegaton thermonuclear class, their yield-to-weight performance has improved considerably but has not equaled that of the West. 2. The Soviets have conducted many tests below 50 kilotons. 3 Weapon Stockpiles 3. A small number of individually produced weapons for interim use could be fabricated within a few months after device testing. TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 IS 0038001 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 2 TOP SECRET Thus, a few weapons with very high yields of up to 100 MT could now be available. However, we believe that the Soviet time lag between nuclear tests of a device and initial stockpile entry of a serially produced weaponized version is about two years at a mini- mum. On this basis, some of the new devices tested in 1961 could be entering stockpile during the latter part of 1963 if a priority development is assumed. It is estimated, however, that this could be done only on a limited scale, and that, in general, the devices tested in 1961-1962 would be stockpiled in 1964 and 1965. We believe that weapons currently stockpiled are derived primarily from devices tested in 1958 or earlier; these weapons range in yield from a few kilotons up to 6 megatons. Requirements for Further Testing 4. Soviet nuclear weapon technology appears to be highly sophisticated and adequate for present delivery systems, but significant advancements can still be made through further de- velopment and -testing. Probably one of the strongest require- ments is in the area of high-altitude effects of nuclear weapons. The Soviets conducted several such tests in 1961-1962, but prob- ably need additional tests to obtain weapon effects data pertinent to antimissile development and countermeasures. They also lack direct information on effects of high-yield weapons on hardened ground targets and on the effects of lower-yield weap- ons on deep underwater targets. The Soviets probably also have requirements to conduct further tests to improve yield-to-weight ratios particularly in the lower weight range and to develop new weapon capabilities such as light-weight thermonuclear warheads for smaller missile systems, and very small weapons for tactical employment. 5. We believe that the Soviets are continuing a vigorous weap- ons research and development program, and that they are main- taining a posture to resume nuclear testing promptly if a decision is made. Fissionable Materials Production 6. We estimate the mid-1963 "cumulative Soviet production of fissionable materials at about 15,000 kilograms of plutonium TS 0038001 TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 4 TOP SECRET 3 equivalent and 130,000 kilograms of U-235.1 These quantities are somewhat lower than previously estimated for mid-1963, as the result of further analysis and additional evidence. The So- viets are continuing to expand their fissionable material produc- tion capability at a significant rate. We estimate that by mid- 1968 cumulative production will amount to about 35,000 kilo- grams of plutonium equivalent and 380,000 kilograms of U-235. Reactor Development 7. Soviet research reactor development continues to be com- petent in most areas and is unique in a few. However, the orig- inal, unrealistic Soviet nuclear electric program has been aban- doned and they are now proceeding with one which is more com- mensurate with their economic requirements and the state of their reactor technology. Moreover, the Soviets have encountered nu- merous difficulties with the nuclear propulsion of the icebreaker LENIN, and there is considerable evidence of similar difficulties with Soviet nuclear powered submarines. Soviet work on ion propulsion and nuclear auxiliary power supplied for space appli- cations is continuing, and we believe that they have a program to develop materials suitable for nuclear rocket motors. The So- viet aircraft nuclear propulsion program appears to have been delayed and may have been cut back or even canceled. 1 See page 13 for the views of the Assistant Chief of Naval Operations (In- telligence) . TOP SECRET TS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: 'CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 4 TOP SECRET SUMMARY I. SOVIET NUCLEAR WEAPON PROGRAM 1961-1962 Soviet Nuclear Tests 8. Between 1 September 1961 and 25 De- cember 1962 112 nu- clear tests which brings the total number of detected Soviet tests to 186. (See Figure 1 and Annex A.) A tabulation of tests to date is as follows: YEAR Semipa- latinsk 1949-1958 42 1961 16 1962 28 LOCATIONS Novaya Zemlya 27 25 36 Total . . . 86 88 Sary Shagan-Ka- pustin Yar 4 4 3 11 Totskoye 1 0 0 1 9. Only low-yield tests have occurred at Semipalatinsk since 1957. Test operations at Semipalatinsk have included ground bursts, air drops, and tower shots; some of these tests were designed to determine the effects of nu- clear detonations on arrays of military equip- ment. Only two underground tests have been detected, both near Semipalatinsk?one in 1961 and one in February 1962. 10. Except for several missile-associated tests in the Kapustin Yar and Sary Shagan areas, all high-yield tests since 1957 have been held at Novaya Zemlya. In addition, there have been some lower-yield air-bursts at the Novaya Zemlya test areas near the center of the island, and several low-yield detonations on or under the sea off the southern coast. We be- lieve that the majority of airburst tests in the Novaya Zemlya area were delivered by medium and heavy bombers. In addition, Soviet state- ments and various intelligence sources indi- cate that a number of the 1961 and 1962 Novaya Zemlya tests probably involved Opera- tional missile systems. 11. Several tests in the 1961 and 1962 series were conducted at high altitudes. In Septem- ber 1961; a 25 KT shot was conducted near the Kapustin Yar rangehead; it probably involved a surface-to-air missile warhead. Another, in October 1961, at Kapustin Yar involved deto- nation of a 200 KT warhead; it probably was designed to provide data on effects at high altitudes. In addition, five very high altitude tests were conducted on the Kapustin Yar- Sary Shagan missile test ranges, two in 1961 and three in 1962. The 1961 tests yielded about 1 KT each, whereas two of the 1962 tests yielded about 200 KT, and the third about 2 MT. The test devices were delivered by medium range (1020 n.m.) missiles fired from the Kapustin Yar rangehead. We be- lieve that these tests provided basic high alti- tude effects data and other data applicable to the antimissile problem. Weapon -Development Program 12. Fission Weapon Developments. From 1949 through 1958, the Soviets conducted about 40 tests of low-yield devices (1-200 KT) By 1958, the Soviets had developed implosion warheads ranging in yield from about 1 to 200 KT. IS 0038001 TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 50X1 50X1 50X1 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 13 1961 and 35 in 1962. TOP SECRET 27 fission tests in 50X1 50X1 50X1 IThe 1962 test series, where the majority of fission tests were 10 KT or under, 14. 15. Thermonuclear Weapon Developments. Between 1955 and 19518, tests of full-scale thermonuclear devices were held by the So- viets at a variety of yields from about 200 KT to 7.6 MT. Over two-thirds of the tests were between 1 and 5 MT. 16. Of the 112 tests of the 1961-62 series, 50 were thermonuclear devices with yields rang- ing from about 150 kilotons to 63 megatons. We esti- mate that yield-to-weight ratios of some of their nuclear devices have been substantially improved over 1958. In addition, new weight classes appeared with yields ranging from 25-63 megatons, which permit the develop- ment of weapons with yields up to 100 mega- tons. 17. The two largest Soviet detonations (30 MT and 63 MT) were both clean thermonu- clear devices. As a normal (dirty) weapon, the 63 megaton device could yield 100 mega- tons. The Soviets also tested a new thermo- nuclear design at yields from 3 to 25 mega- tons. Weapon and Systems 19. A small number of individually produced weapons for interim use could be fabricated 50X1 within a few months after device testing. Thus, a few weapons with very high yields of up to 100 MT could now be available. How- ever, we believe that the Soviet time lag be- tween nuclear tests of a device and initial stockpile entry of a serially produced weap- onized version is about two years at a mini- mum. On this basis, some of the new devices tested in 1961 could be entering stockpile dur- ing the latter part of 1963 if a priority develop- ment is assumed. It is estimated, however, that this could be done only on a limited scale, and that, in general, the devices tested in 1961-1962 would be stockpiled in 1964 and 1965. 50X1 50X1 50X1 Future Weapon Development and Testing 20. The status of Soviet nuclear wear50X1 technology, while highly sophisticated and in most respects apparently adequate for their present delivery systems, is such that sig- nificant advancements can still be made through further development and testing. Such advances can be made in at least four areas: (a) adaptation of present designs to meet the needs of future delivery systems; (b) development of very small weapons for tactical employment; and (c) improvement in yield- to-weight ratios. 21. Probably one of the strongest require- ments for further Soviet nuclear testing is in the area of high-altitude effects of nuclear weapons. The Soviets have not detonated a warhead in the vicinity of a re-entering missile 50X1 nosecone, nor do we have firm evidence that the Soviets have placed instrument pods near their high altitude bursts. We also have no TOP SECRET IS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 6 TOP .SECRET knowledge of Soviet activities in providing information on effects upon hardened missile launch sites. Other areas where the Soviets- require additional effects information may exist; in particular, the Soviets lack experi- ence with very deep underwater bursts. 22. We believe the Soviets are currently maintaining a vigorous weapon research and development program and are in a posture to resume nuclear testing promptly if a de- cision is made. Organization and Facilities 23. The Soviet atomic energy program is directed by two organizations recently placed under the supervision of the newly created Supreme Council of the National Economy. One of these, the State Production Committee for Medium Machine Building, USSR, is re- sponsible for the overall direction of the atomic energy program including the produc- tion of fissionable materials and nuclear weap- ons. The Ministry of Defense participates with this Committee in the development, test- ing, and stockpiling of nuclear weapons. The other organization, the State Committee for the Utilization of Atomic Energy, is responsible for nonmilitary applications of the program and all official contacts with the atomic energy programs of foreign countries. 24. The USSR maintains a substantial de- gree of control over the atomic energy activi- ties of the Soviet Bloc nations through inter- locking associations of top Soviet personnel and by means of bilateral agreements and the Standing Committee for Peaceful Uses of Atomic Energy of the Council for Mutual Economic Aid (CEMA). This relationship is such that the Soviets have precluded the de- velopment of an independent nuclear military capability by the other participating nations. Communist China, an observer rather than a member of CEMA, has proceeded independ- ently with its own nuclear program since the TS 0038001 withdrawal of Soviet technical aid in mid- 1960.2 25. The oldest Soviet center specifically con- cerned with nuclear weapon research, design, and development is located at Sarova about 200 miles east of Moscow. A second nuclear weapon research and development center, near Kash in the Urals, probably became opera- tional late in 1959. Although the installa- tion, which is quite similar to Sarova, is con- siderably smaller than that center, we believe it represents a major addition to the Soviet nu- clear weapon development potential. There is evidence that there is a research and develop- ment establishment, probably concerned with nuclear weapon systems development at the Kerch/Bagerovo airfield in the Crimea. The Soviet nuclear weapon program has also been supported by research conducted at a number of other institutes in the USSR probably in- cluding the Institute of Atomic Energy, Mos- cow; the Physics Institute, Obninsk; Physical- Technical Institute, Sukhumi; and especially the Institute of Chemical Physics, Moscow. Weapon Fabrication Sites 26. Nuclear weapon fabrication complexes have been identified in the Urals at Nizhnyaya Tura and at Yuryuzan. A possible third com- plex is located in Central Siberia near Kras- noyarsk. National reserve stockpile sites are co-located with these complexes. Weapon Stockpile Sites 27. The Soviet nuclear weapon logistic sys- tem includes (a) National Reserve Stockpile facilities at interior locations; (b) National Assembly Stockpile sites located near major order-of-battle concentrations; and (c) Re- gional and Operational storage sites at mili- tary bases for the direct support of military operations. TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 SECRET USSR: NUCLEAR WEAPON RESEARCH AND TEST AREAS Figure 1 KINGDOM NORTH SEA AMSTERDAM w ? N FEDERAL Reptmut GERMANy. ..7:4?St I GERMANY Nrz' PRAGUE 4? POLAND z EN.\A ? it (vC PENHAGEN1 ',STOCKHOLM 0 SEA N O\R W A Y SWEDEN SI. ? Novorossly k BLAC S HUM SEA OBNINSK \** pow:. vvvi FINLAND_/\ HELSINKI rmansk BARENTS NOVAYA ZE VA 40 60 80 100 120 140 160 a SIBERIAN SEA ', KARA SEA MO OW SAROVA o Kirov Kazan _Ufa KERCH//7 EROVO Urarsk? KAPUSTIN YAR TOTSKOYE V.Elatumi TUR EY ) 40 Xrevan IRAQ: Astrakhan' Gary., KASLI 0 AvA% Provederuya 180 BERING SEA Pe SEA OF OKHOTSK Pa"'?"ko 160 Omsk aku ?Bar naul SE/vCrirdi LATINSK TEHERAN? IRAN ovodsk h Lake Baikal oC"" 8ian lid oKzykOrda ?Monk'', SARY-SHAGAN (1401 Lake Balkhash IoAlma?At i AFGHANISTAN c.,574.,A,?: KABUL IlLrena.,A% prA.LPINDIQ0c (StIVre'iaranzNO ..S MO ULAN BATOR 0.- CHINA NGOLIA CHINA 100 37856 6-63 SECRET 3 SEA OF JAPAN KYO k Weapons Research and Development ce Nuclear Test Sites SECRET OrtOra, I Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 3 TOP SECRET 28. Between 1951 and 1955, the USSR acti- vated a total of about 6 stockpile sites of all classes. Over the next three years at least 17 additional stockpile sites of all classes were activated, bringing the total to about 23 at the end of 1958. This expansion supported primarily the growing nuclear capability of the Soviet strategic bomber force which was then rapidly converting to jet aircraft, and a limited development of nuclear capability in Naval and Tactical Aviation and probably ground and naval forces as well. Since 1958, a third stage of rapidly accelerated stockpile site construction has coincided with the de- ployment of strategic and tactical missiles with a nuclear capability, and with a wider distribution of nuclear weapons among Soviet military forces. In this period, the USSR has substantially increased the capacity of about two-thirds of the previously existing stockpile sites, and has more than doubled the total number of stockpile sites. 29. The National Reserve Stockpiles and the National Assembly Stockpile facilities are characterized by isolation, extreme security, hardened bunkers (either earth-mounded or underground) and self-sufficiency in housing and other services required by the permanent cadres. 30. Operational and regional military stor- age sites now positively identified include three generations of airfield sites, sites at two staging bases in the Arctic, regional military depots resembling in design the third genera- tion airfield sites, and a naval site used pri- marily to support missile-carrying submarines. These sites are typically situated apart from other facilities at their associated base, and are characterized by stringent physical secu- rity and by hardened storage bunkers. 31. We believe that nuclear warheads are available to all operational ICBM, IRBM, and MRBM complexes either on-site or at nearby 9 storage facilities. Soviet ground forces may have field storage facilities in addition to the regional depots which probably serve them. Some nuclear storage probably is required by 50X1 50X1 TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 10 TOP SECRET Naval Aviation for its BADGER-delivered air- to-surface missile. We have no evidence of nuclear storage facilities at surface-to-air mis- sile sites. No nuclear warhead storage facili- ties have been identified in European satellites nor is there definitive information that nuclear weapons have been deployed to any of the Soviet forces stationed there. Command and Control 32. In the USSR, the Presidium of the Party Central Committee exercises ultimate control over nuclear weapons, and its author- izations govern their use, storage, movement and issuance. In a war situation, control would be exercised by the Presidium Chair- man in his capacity as Supreme High Com- mander who, through the Ministry of De- fense, would authorize the principal com- manders of the forces directly concerned to use nuclear weapons. 33. We believe that the national stockpile storage sites are administered by the State Production Committee for Medium Machine Building, and operational storage sites by the Ministry of Defense. The Committee for State Security (KGB) is responsible for the security of nuclear stockpile facilities, pro- vides their guard force and is responsible for escorting movements of nuclear weapons to and from national stockpile facilities and mil- itary depots. There is some evidence that responsibility for the management of logis- tical functions, such as storing, maintaining and delivery of nuclear weapons in support of military operations has been assigned to or- ganizations operating in direct support of the major force components of the Ministry of Defense. 34. The flow of orders from the Supreme High Command is arranged so as to achieve maximum control and minimum delay in ac- tion. In the Strategic Rocket Forces, for in- stance, orders pass through the Commander and his main Staff directly to regiments re- sponsible for nuclear fire. In the case of Theatre Forces, once employment of nuclear weapons has been authorized, responsibility for alerting forces and ordering execution of nuclear fire is delegated to major joint service commanders at the Military District, Group of Forces, or Front Level. The Commander at this level may allow his subordinate corn- manders down to Army level some discretion in authorizing the use of nuclear weapons, but it is evidently rare for commanders below that level to have any such discretion. In the case of special nuclear attack groups of tactical missiles and artillery, the Joint Serv- ice Commander evidently issues the order to prepare and execute nuclear fire directly to the units concerned, and their immediate superiors merely supervise execution of the order. Presumably Long Range Aviation, the Naval Forces and the Air Defense Forces op- erate in similar fashion. 35. There is abundant evidence that the USSR was seriously preoccupied with the problem of improving its command and con- trol procedures for nuclear weapons from 1959 through at least 1961. The intro- duction of strategic missiles had complicated the problem of central control and had made more rapid response an urgent necessity. In addition, Soviet Theatre forces under field conditions many of the logistical practices and procedures gov- erning the issue and servicing of nuclear weapons were cumbersome and operationally impractical. Some streamlining of the con- trol system has probably occured by now, al- though precise details are not yet known. 36. We have no evidence to indicate whether or not the Soviets have either con- sidered or installed mechanical or electronic IS 0038001 TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 50X1 50X1 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TOP SECRET 11 safeguards in their nuclear weapon control procedures? (such as permissive links) . II. FISSIONABLE MATERIALS PRODUCTION (See Figure 2) Uranium Ore Procurement 37. Soviet Bloc uranium reserves are esti- mated at several hundred thousand tons in medium grade ores and an even greater quan- tity in low grade deposits. A number of well- designed ore concentration plants of 500 to 1000 metric tons capacity are currently in operation, and active prospecting for addi- tional orebodies continues. 38. We estimate that the annual procure- ment of uranium ore by the Soviet Union is currently 20,000 metric tons of recoverable metal equivalent and will gradually increase to 25,000 metric tons per year over the next five years. The cumulative recoverable metal ?through mid-1963 is estimated at 190,000 metric tons and-through mid-1968 at 300,000 metric tons. These amounts of ore, which could be higher or lower by as much as 50%, are believed to be sufficient for the fis- sionable material production estimated here- in and for a substantial stockpile in addition. Uranium Feed Materials 39. Uranium metal and other feed mate- rials are produced at Elektrostal, near Mos- cow; at Gla,zov, just west of the Urals; and at Novosibirsk in Central Siberia. The large size of these facilities and the process im- provement detailed in the Soviet published literature suggest that the USSR has ade- quate feed materials plant capacity for the program estimated herein. Plutonium-Equivalent 40. Three major plutonium-equivalent pro- duction sites have been identified in the USSR. The earliest and largest is located near Kyshtym in the _ Urals, the second is collo- cated with the U-235 production complex at the atomic energy site north of Tomsk in Central Siberia, and the third is located within the large atomic energy site northeast of Krasnoyarsk in Central Siberia. Review of all available information led to the conclu- sion that there are no other major produc- tion reactor sites in operation in the USSR. 41. We estimate that mid-1963 Soviet cu- mulative plutonium-equivalent production is about 15,000 kilograms. Interpretation of available data would permit a mid-1963 cumu- lative production estimate as large as 23,000 kilograms; however, it is almost certain that actual mid-1963 cumulative production is not less than 12,000 kilograms. 42. It is estimated that annual plutonium- equivalent production will increase at a rate consistent with performance during the period 1958-1962, resulting in a cumulative pluto- nium-equivalent production of about 35,000 kilograms by mid-1968. (See Table II.) Even with an extremely high priority effort, the cumulative plutonium-equivalent stock- pile would not exceed 45,000 kilograms by mid-1968. Alternatively, the minimum likely cumulative production by that date will not be less than 25,000 kilograms. 43. Highly irradiated plutonium will be produced as a byproduct of the nuclear power and propulsion programs of the USSR in amounts gradually increasing to about 600 kilograms per year in 1968, and has been in- cluded in Table II. This production could be used in weapons by mixing with plutonium produced at considerably lower irradiation levels and would have other uses. U-235 Production 44. Three large gaseous diffusion isotope separation complexes capable of concentrat- ing U-235 up to weapon-grade production are in operation in the USSR; one at Verkh- TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 IS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 12 TOP SECRET Neyvinsk in the Urals, one north of Tomsk in Central Siberia, and the third at Angarsk in the Lake Baykal region. A fourth large gaseous diffusion complex is under construc- tion north of Zaozerniy near Krasnoyarsk. We believe that no undetected large gaseous Table II ESTIMATED SOVIET FISSIONABLE MATERIALS PRODUCTION (Cumulative Production in Kilograms Rounded) U-235 MID-YEAR (93% )8,5 TOTAL AVAILABLE FOR WEAPON USE PLUTONIUM EQUIVALENT 1950 25 25 100 . 1951 160 160 330 1952 600 600 550 1953 1,550 1,550 1,000 1954 3,350 3,350 1,600 1955 6,300 6,300 2,200 1956 10,500 10,500 2,900 1957 16,500 16,000 3,800 1958 24,500 24,000 4,500 1959 36,500 35,500 6,000 1960 53,000 51,000 8,000 1961 72,000 70,000 9,700 1962 100,000 96,000 12,000 1963 130,000 125,000 15,000 1964 170,000 165,000 18,000 1965 210,000 200,000 22,000 1966 260,000 250,000 26,000 1967. 320,000 310,000 30,000 1968 380,000 370,000 35,000 8 Production of less highly enriched uranium is in- cluded as equivalent quantities of 93% material. Non-weapon uses of plutonium are expected to be negligible during the period of this estimate. See Page 13 for view of the Assistant Chief of Naval Operations (Intelligence) , Department of the Navy. Our current and future estimates of cumulative production of fissionable materials represents some decrease from those estimated in NIE 11-2A-62. These changes are the result of further analyses and the acquisition of additional information. How- ever, it should be noted that the margin of error involved in any one year's value of cumulative pro- duction is larger than the magnitude of these changes. IS 0038001 diffusion plant is currently in operation. Continued construction of large gaseous dif- fusion plants in the USSR suggests that sig- nificant U-235 production by other means such as the ultracentrifuge is unlikely. 45. Early Soviet gaseous diffusion plant op- erating efficiencies are derived from informa- tion supplied by German scientists who worked on the program through 1952. Later plant operating efficiencies have been extrapolated from this base primarily on advances in So- viet compressor technology and changes in process building design. Changes in process building design indicate the use of an improved barrier starting in 1958. The efficiency of this barrier can only be esti- mated, since there are no data on its operat- ing characteristics. 46. Our estimate of U-235 production is based upon estimated electric power consump- tion, available site data, and on estimated plant operating efficiencies. Estimates of the growth of electric power supplies taken in conjunction with agailable site data indicate that the Soviet U-235 program is still under- going significant expansion. It is believed that the current program of expansion will not be completed before 1968. 47. Our estimate of total Soviet cumulative U-235 production is presented in Table II in terms of cumulative production of uranium enriched to 93 percent U-235 content. It in- cludes the 93 percent equivalent of material produced at lesser enrichment. Estimated expenditures for weapon tests and non-weapon uses have been subtracted from the value of cumulative U-235 production to give our esti- mate of equivalent 93 percent U-235 available for weapon use. 48. It is estimated that the Soviet cumula- tive U-235 production for mid-1963 is 130,000 TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 I, Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TOP SECRET kilograms.7 It is unlikely that actual Soviet cumulative production in mid-1963 could be less than 80,000 kilograms or more than 180,000 kilograms. We estimate that the mid- 1968 cumulative production will be 380,000 kilograms and that the actual U-235 produc- tion would not be less than 190,000 kilograms or more than 570,000 kilograms. Other Nuclear Materials 49. Thorium and U-233. A moderate in- terest in the procurement of thorium ores was noted during the 1946 and 1952 period. The only certain evidence of the production of U-233 from thorium is the single appearance of U-233 on 22 November 1955 in the thermo- nuclear weapon test JOE 19. 50. Lithium. Lithium ores have been ob- tained primarily from three areas in the USSR. Soviet nuclear weapons have probably been using lithium enriched in the lithium-6 iso- tope since late 1955. The locations of So- viet lithium-6 isotope separation plants have not been positively identified, but could be located in certain facilities at the Nizhnaya Tura and Novosibirsk atomic energy sites. 51. Tritium. We are unable to determine which of the Soviet reactor sites is used to produce tritium or the amount of tritium produced. 52. Zirconium. Zirconium-niobium alloys are used to clad fuel elements for the nuclear reactors of the icebreaker LENIN and by impli- cation the nuclear submarine cores. Ade- quate zirconium-niobium production capacity The Assistant Chief of Naval Operations (In- telligence) , Department of the Navy, believes that the lower limit of the estimated value for the cumu- lative production of U-235 is the more nearly cor- rect. He believes that the evidential base is in- sufficient to support the production efficiency which a higher cumulative total would require. 13 is believed available for the needs of the So- viet atomic energy program. 53. Beryllium. The USSR processes large reserves of beryllium ore at Izumrud in the Urals, and established, in the pre-war period, a combine there to manufacture beryllium- copper and other alloys. Returned German scientists have reported interest in beryllium metal shapes at the Elektrostal feed materials plant as early as 1946. Sufficient quantities of beryllium ore and metal producing facilities are believed available to support both nuclear weapons and reactor programs of the USSR. 54. Polonium. Reactor-produced polonium has been available for use in nuclear weapons initiators since at least as early as 1950. 55. Heavy water. Since 1945 the USSR has operated heavy water (D20) production plants at some 8 locations, using at least 4 different processes. All the plants are relatively small, but it is believed that cumulative production has been adequate for Soviet needs. We esti- mate that the current annual production of heavy water is about 90 metric tons per year and the cumulative production through mid- 1963 about 1,100 metric tons. The actual production could be up to 50% more than that estimated if hydrogen distillation processes were adopted at all plants, or if an unknown large additional facility exists. III. NUCLEAR REACTOR PROGRAM Research and Testing 56. The Soviets have constructed, and are currently operating, 23 research reactors of 13 different types within the USSR, and have supplied 12 foreign countries with research reactors. (See Table III.) While in recent years the Soviets have adopted the light-water moderated and cooled IRT swimming-pool type as their general purpose research reactor, they have also built a few research reactors of unique design which have proved to be TOP SECRET TS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 50X1 50X1 50X1 LOOM) SI .1321D3S d01 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Table III SOVIET RESEARCH REACTORS AND REACTOR EXPERIMENTS Max. Thermal Power Neutron Flux Reactor Thermal (neutrons/ Date Designation Location (KW) cm2 sec) Fuel Moderator Coolant Critical Operating Research Reactors 1. Fursov Pile Moscow Inst. of 500 A.E. (max) .. 45 tons of natural Graphite Air 1946 2. TR (rebuilt) Moscow, Inst. of 2,500 2.5x1013 270 kg of 2% Heavy Water 4.5 Heavy June Theoretical & enriched U tons Water 1957 Exp. Physics 3. RPT?III Moscow Inst. of 20,000 2x1014 90% enriched U Beryllium & Water (20 Under A.E.6x10" Water atms.) const. (flux trap) 4. BR-1 Fast Obninsk 0.10 .. 12 Kg Pu none none Early Reactor 1955 5. BR-3 combined fast thermal re- actor Obninsk 0.05 Pu none none Mid- 1957 6. VVR-2 (rebuilt) Moscow Inst. of A.E. 3,000 4x1013 45 kg of 10% en- riched U Water Water 1955 Remarks Similar to US CP-1, served as prototype for 1st Soviet production reactor. Originally a 500 kw proto- type for Soviet heavy water production re- actors. Critical in April 1949. Rebuilt version has 9 vertical & 52 horizontal experimental channels. Old RPT loop facilities to be retained; 200 atm. coolant loop; 60- atm. helium loop; 2.5 MW power loop. Uranium & copper re- flectors. Uranium & water reflec- tor. Original version critical in 1952. Tank-type re- actor designed for test- ing of shielding ma- terials & configuration. Now has 5 horizontal channels with choppers, 3 vertical channels, & a "neutron multiplier" (spent fuel elements in a tank adjacent to reactor). ? Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 13203S dal. UDS d0.1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 7. VVR?S Moscow, Moscow' State Univ. 2,000 2.5x1013 60 kg of 10% en- riched U Water Water 1955 8. VVR?S Tashkent, Inst. of Nuclear Physies 2,000 2.5x1013 60 kg of 10% en- riched U Water Water Late 1959 9. IRT Moscow Inst. of A.E. 2,000 3.2x1013 40 kg of 10% en- riched U Water Water Nov. 1957 10. IRT Tbilisi 2,000 3.2x1013 40 kg of 10% en- riched U Water Water Nov. 1959 11. IRT Moscow Inst. of Physical Engi- neering 2,000 3.2x1013 40 kg of 10% en- riched IJ Water Water 1962 12. IRT Riga 2,000 3.2x1013 40 kg of 10% en- riched U Water Water 1962 13. IRT Minsk 1,000 1.6x1013 40 kg of 10% en- riched U Water Water 1962 14. IRT Tomsk 1,000 1.6x1013 40 kg of 10% en- riched U Water Water 1962 15. IRT Sverdlovsk 1,000 1.6x1013 40 kg of 10% en- riched U Water Water 1962 16. VVR?M Leningrad Physical- Technical Insti- tute 10,000 lx1014 20 kg of 20% en- riched U Water Water Dec. 1959 17. VVR?M Kiev Physical Tech- nical Inst. 10,000 lx1014 20 kg of 20% en- riched U Water Water Feb. 1960 18. Intermediate Flus Trap (SM-2) Melekess, Ul'yanovsk 50,000 2.2x1014 13 kg of 90% en- riched UO2 in a Water Water Oct. 1961; Oblast Ni matrix Full Power Nov. 1962 19. IBR (Merry-go- Dubna Joint Inst. 1 Ave. 1017 during UO2 impregnated Graphite Water June round) of Nuclear Re- 100,000 burst in graphite Pu 1960 search Max. 02 in stator Tank-type; 10 vertical channels, 9 horizontal channels. Supplied to Rumania; Hungary, Czechoslovakia, E. Ger., Poland & Egypt. Tank-type; 10 vertical channels; 9 horizontal channels. Swimming-pool type for use in universities & institutes. Reactor to be modified to 4000 KW using 36% 15-235. Swimming-pool type for use in universities & institutes. Same as above. Same as above. Same as above. Same as above. Same as above. Beryllium reflected, used for neutron diffraction studies, probably in con- nection with solid-state work in Leningrad. Beryllium reflected, used for isotope production, prod. of trans U ele- ments. Be0 reflected, central water cavity where max. ther- mal neutron flux is ob- tained. Used with a 1 km time of flight spectrometer. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 13103S d01. 1.008C00 SI 1311D3S d01 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Reactor Designation 20. Isotope Reactor (IR) 21. BR-5 Fast Re- actor 22. VVR?Ts 23. OR Location Power Thermal (KW) Max. Thermal Neutron Flux (neutrons/ cm2 sec) Unknown-Possibly 50,000 3-4.5x1013 Kyshtym Obninsk Alma Ata Table III (Continued) Fuel Moderator Operating Research Reactors 3 tons of 2% en- Graphite riched U 5,000 101s (fast) 50 kg Pu Oxide None 10,000 1x1014 Moscow Inst. of 20,000 A.E. 1. Fast Zero Power Obninsk Critical Assembly (BFS) 1. Beryllium Physi- cal Reactor (BFR) 2. BR-2 Fast Re- actor 3. UF 6 Gas-fueled reactor Obninsk Obninsk Moscow A.E. 25 kg of 20% en- riched U U-unknown con- centration Water Organic Fluid- possibly isopro- pyl-diphenyl Low Power Reactor Experiments Now in Operation U discs Date Coolant Critical Water Remarks 1952 Experimental facility for production of isotopes. Uranium & nickel re- flector. Sodium June 1958; full power July 1959 Water 1963 Same as moder- ator No Longer in Operation 0.05 . . U308 with 20% Beryllium metal none enriched U 100 Pu-U none 10" (fast) Inst. of 1.5 2.7x101? UF with 90% en- Beryllium metal none riched U Specialized radio-chemical research reactor. Prob. The first organic cooled & 1962 moderated reactor in the Soviet Union. 1962 Used to study large di- luted reactors ? Aug. Zero-power critical assem- 1954 bly, bare & reflected. Mercury Early Uranium reflector. (Dis- 1956 mantled to make BR- 5). Aug. Probably dismantled. 1957 Declassified in Part-Sanitized Copy Approved for Release @50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 13103S d01 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 TOP SECRET 17 valuable experimental facilities. These in- clude a pulsed reactor which provides a burst of neutrons over a period of 40 microseconds; a plutonium fueled, sodium cooled, fast reac- tor; and a 50 megawatt, intermediate fluxtrap reactor. 57. The Soviet series of fast reactors are being used in the development of breeder-type reactors for the production of electric power and, it is believed, in connection with the de- velopment of compact propulsion reactor sys- tems and/or as an auxiliary power source. Nuclear Electric Power 58. Following the successful operation of a 5 electrical megawatt (MWe) nuclear electric power station at Obninsk in June 1954, the USSR announced plans in February 1956 for the installation of 2000-2500 MWe of nuclear generating capacity by the end of 1960. This ambitious program was cut back considerably in 1958 and has consistently been slipping be- hind subsequently revised schedules. Soviet officials have stated that their nuclear power program was reduced for economic reasons, since their nuclear reactors are not yet com- petitive with conventional power sources ex- cept in special locations. However, it is also certain that Soviets underestimated the en- gineering difficulties in a major nuclear power program. (See Table IV and Figure 3.) 59. We estimate that, including the dual- purpose reactors in Siberia, the USSR will have about 500 MWe of nuclear generating capacity installed by the end of 1963 and about 1500 MWe by the end of 1968. 60. Soviet ?research on controlled thermo- nuclear reactions (CTR) began about the same time as the US. Both programs have been proceeding at about the same pace. It is estimated that the USSR will not achieve a useful controlled reaction within at least the next 3-5 years; and consequently will not attain useful power from nuclear fusion within the next decade. Marine Nuclear Propulsion Systems 61. Three different classes of nuclear pow- ered submarines are known to have been con- structed in the USSR and identified in opera- tional status. We estimate that a fourth class will be completed and undergo trials within a year or two and will probably have an improved propulsion system. 62. It is estimated that the Soviet Navy has about 26 nuclear submarines. The Northern Fleet has under its command about 20 nuclear submarines in operational or near operational status composed of ballistic missiles-carrying submarine of the "H" class and attack type ("N" class) submarines, while the Pacific Fleet is currently operating six cruise missile type submarines ("E" class) . We believe that the Soviets can fabricate at least the number of reactors needed to support the estimated construction program of 8 to 10 nuclear sub- marines per year. (See Table V.) 63. The reactor systems used on the nuclear < icebreaker, LENIN, and the nuclear sub- marines are of the pressurized-water type. It is believed that many of the design charac- teristics and the performance of the LENIN Power Plant are reflected in the submarine propulsion system, particularly for the early submarines. In general, the design and in- tegration of propulsion system components is poor compared to US standards and limits the reliability of their nuclear submarines. On at least five occasions in the past four years, propulsion plant failures have necessitated towing nuclear-propelled submarines back to base. We continue to estimate that Soviet technical and operational experience with pressurized-water reactor propulsion systems is limited in comparison to US experience. TOP SECRET IS 0038001 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 .1321D3S Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Station Location Tomsk Beloyarsk Novo Voronezh Obninsk Obninsk Table I-V SOVIET NUCLEAR POWER STATIONS AND EXPERIMENTAL CENTERS No. of Reactors and Type Elec. Power Per Reactor (MW) 3 reactors in var- 200 ious stages of (est.) construction Thermal Power Per Reactor (MW) Fuel Loading Per Reactor 1400 200 metric tons (est. of natural U peak power) 1 Graphite-moder- 100 286 90 metric tons of ated water 1.3% U metal cooled, pressure tube configura- tion Unit 2 200 1 water-moderated 210 water-cooled pressure vessel configuration Unit 2 360 1 Graphite-moder- 5 ated, water cooled, pressure tube configura- tion 1 package power water-moderat- ed water-cooled, pressure vessel '2 760 23 metric tons of 1.5% UO2 % 17 metric tons of natural UO2 (820 kg U-235 metal equivalent) 30 550 kg of 5% U . metal 10 . Conver- sion Ratio Annual Con- sump- tion ETP U-235 Per Reactor (Kg) Annual Produc- tion Pu Per Reactor (Kg) 0.8 400 0.65 at 74 66 begin- Ding of cycle, 0.55 at end 0.75 to 0.80 0.32 0 . 5 assumed Estimated date of Fuel Full Life- Power time Operation Remarks 1st reac- Construction to be tor crit- completed by end ical 1958; of 1968. in mid- 1960 at 100 MWe. 2 yrs 1963 Employs nuclear superheat. Est. schedule: 1st. reac- tor, 1963. 4 origi- nally planned. 1966 108 117 1 . 5 1963 Zr-Nb alloy clad fuel elements. 2 origi- nally planned. 3 100 days 1966 1954 First Soviet nuclear power station. Pro- totype of Beloyarsk reactors. Used ex- tensively for experi- ment as well as power production. 1959 Assembled for testing at Obninsk. Declassified in Part - Sanitized Copy Approved for Release @50-Yr 2014/02/20 : CIA-RDP79R01012A022200020001-4 CO 13?1D3S daL 1321D3S d01 L 008E00 SI Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Melekess, Ul'yanov- 1 boiling water re- 50 sk Oblast actor Bohunice (Czecho- slovakia) Rheinsberg (East Germany) 1 organic reactor (ARBUS) 1 gas-cooled heavy water reactor 1 pressurized water reactor similar to Novo- Voronezh 250 . 0.75 5 22.5 Kg 10-15% U-235 150 590 25,400 kg nat- ural U 0.60 assumed 70 265 19,600 kg UO2 . 75-0 . 80 36 1.5% 43 1965 Same type fuel ele- ment as large F'WR's. Plant fac- tor assumed 0.6. 1963 Package power re- actor. 1965 Possible trouble with pressure vessel in 1962. 40 1.5 yr. 1965 Progress very slow. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 20 TOP SECRET Aerospace Nuclear Applications 64. No installations concerned with an air- craft nuclear propulsion (ANP) program have been identified in the USSR, and there is no evidence that the Soviets have conducted a flying test bed experiment. The ANP pro- gram appears to have been delayed and may have been cut back or even canceled. In any event, we do not believe that a militarily use- ful nuclear powered aircraft could appear prior to 1968. 65. There is no specific evidence that the Soviets have a nuclear ramjet missile or a nu- clear rocket under development. Neverthe- less, the Soviet scientific literature indicates that an extensive research program exists which is capable of developing the materials and establishing the technology required. We estimate that the Soviets will not conduct a static test of either a nuclear rocket or a nu- clear ramjet engine before 1966, at the earliest. 66. An extensive effort appears to be under- way in the Soviet Union to develop a nuclear electric propulsion system for space vehicles. The contact ion engine program is the most advanced of the various electrical propulsion systems in a practical sense. If no major difficulties are encountered in developing a suitable nuclear power source, it is estimated that the Soviets could flight test a full-scale ion propulsion system operating at a power of about 75 KWe as early as 1964 or more probably 1965-1966. 67. There is substantial evidence that the Soviets are conducting research fundamental on the development of nuclear space power supplies capable of producing on the order of several hundred watts. We believe, that they could have a suitable thermoelectric device capable of generating about a kilowatt of elec- tric power in 1964. For higher power systems, we believe that the Soviets will probably use a turboconversion type nuclear power supply of about 100 KWe and that a system of this size could be flight tested as early as 1965. The Soviets have conducted extensive research on thermionic phenomena and the develop- ment of suitable high-temperature materials. Such a system would permit the direct conver- sion of heat to electricity. We estimate that a thermionic nuclear power supply will be- come available towards the end of this decade. Table V ESTIMATED CHARACTERISTICS OF SOVIET NUCLEAR SUBMARINES Class Type Length Over-all Beam (ft) (ft) Displace- ment in tons N A torpedo attack 330 32 surfaced submarine 3,800 submerged 4,300 Maximum Surface Speed (knots) Maximum Sub- merged Speed (knots) about 20 about 20 Estimated Maximum Depth (ft) Estimated Reactors Horsepower 750 15,000 hp. probably pres- surized water reactor. ? Ballistic Missile Firing 315 32 surfaced 3,500 submerged 4,000 about 20 about 20 750 15,000 hp. probably pres- surized water reactor. ? Cruise Missile Firing 385 33 surfaced 5,600 submerged 6,700 about 20 18 750 15,000 hp. probably pres- surized water reactor. TS 0038001 '- TOP SECRET Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 SECRET USSR: NUCLEAR MATERIALS PRODUCTION SITES ITED KINGDOM NORTH SEA 4,1:6STER0AM NO1-1. REPUBLIC PEDERAk.,6 E,,A_OL;SL 40 GERMANY rCOPENHAGEN 4477 C SEA 40 60 80 100 120' 140 160 Figure 2 NORWAY r- ? ;;;T I GERMANY 011, PRAGUE SWEDEN BARENTS ? %) POLAND./ ) EAST SIBERIAN SEA ??, **"... V Fula KARA SEA BERING ALEKSIN DNEPRO Novorosslys BLACK SEA EKTROST ERZHINSK GdRLOVKA ?Keay Itaron BEREZN ken g GLAZOV NORIL'SK Igarka KRASN ir VERKH NEY KYSHTYM Urarsk? Pc pavlov SEA OF OKHOTSK an _Batumi TUR EY )g KIROVA \ **Yerevan SLAQY Astrakhan Gu,'yey TOMSK ZAOZ RN Y? Under o tructto Kornsonloekk NO SIBIRS RASNOYARS A'R A L 0.. SEA ANGARSK ? ? *ULAN BATOR TEHERAN* oKyyl:Orda Lake Baikal oChna Ude \ ctiar"" CHINA -rhno a halinsk CHIRCHIK Lake Balkhash IRAN OAInna?A NGOLIA 90 AFGHANISTAN KABUL ..1 1.17167.: 2ArNALPINOt (Siel(u.stnel:puteN0 37857 6-63 SECRET thanaro JAPAN If% Plutonium dr U-235 kin U-Meta I LI Heavy Water GROW Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2014/02/20: CIA-RDP79R01012A022200020001-4 SECRET Figure 3 20 40 80 120 160 180 ? SEA ? . CO 0 ? / c 0 e 0/ ... 4 7 '''V. ? HELSINKI .::::: \,/ , , , , ' 1"