How did the design and construction of their warships compare with ours? What range and power had their guns? How heavy was their armor and what was its metallurgy? Were they ahead of us in electronics development? The Navy wanted the answers to these and a thousand other technical questions.
To obtain the desired information, investigators had to enter Japan with the occupation forces, before manufacturing plants, equipment, materials and records could be destroyed and experienced personnel dispersed.
NavTechJap, which became the abbreviated designation for the US Naval Technical Mission to Japan, was established on 14 August 1945 by directive of Commander in Chief and Chief of Naval Operations. The formation of the Mission was in accordance with the provisions of the intelligence appendix contained in the plans for Operation Blacklist, which provided for the occupation of Japan. Capt. C.G. Grimes, USN, who was Fleet Intelligence Officer in Charge of Technical Intelligence for Joint Intelligence Center Pacific Ocean Areas (JICPOA), was designated Chief of the Mission.
The surrender of the Japanese in mid-August required that the basic organization be equipped and prepared to leave Pearl Harbor by 1 September 1945, approximately two weeks after the directive establishing the Mission had been issued, in order to obtain the advantages of early exploitation of targets. The nucleus of the initial organization was recruited from technical and language personnel attached to JICPOA and technical personnel flown to Pearl Harbor from various continental naval activities. This group was designated JICPOA Team No. 29 and consisted of approximately 105 officers and 84 enlisted men. It sailed from Pearl Harbor on 1 September 1945 aboard USS Shelby (APA 105) and was part of the convoy which entered Sasebo Naval Harbor on 23 September 1945 -- the initial occupation in Kyushu.
Another group, somewhat smaller than Team 29, was organized and designated JICPOA Team No. 30. This group joined the Third Amphibious Corps in the occupation of certain areas in China. Elements of the Intelligence Groups of Commander Seventh Fleet joined at Sasebo, and on 28 September all units were consolidated as NavTechJap.
While the Mission was enroute to Japan, dispatches were received from Commander Third Fleet requesting that a naval technical intelligence team be sent immediately to Yokosuka to exploit targets in that area. A representative of the Mission was flown from Saipan to Tokyo to consult with the Staff, Commander Third Fleet, and upon arrival of the unit in Sasebo, a team of approximately 25 officers and enlisted men left for Yokosuka. Shortly thereafter, a request was received from Commander Fifth Fleet (the Third Fleet having been relieved) requesting that a team enter Kure with the initial Army landing in that port. This team joined at Okinawa the convoy assembling for Kure and landed there on 7 October 1945.
Within an period of three weeks from the initial landing at Sasebo, technical intelligence teams stemming from the headquarters of the Mission at Sasebo had entered Tokyo, Yokohama, Yokosuka, Jure, Horishima, Osaka, Nagoya, Kyoto, Maizuru, Matsujawa, Kochi, Fukuyama, Okayawa, Nagasaki, Kumamoto, Moji, Shimonoseki, Kogoshima and Fukuoka, with or shortly after the initial landing of the Army or Marine units in these cities.
Within four weeks, technical intelligence teams were established in or within easy reach of all major industrial centers in the main Japanese Islands of Kyushu, Honshu, Shikoku and Hokkaido, and teams had entered China and Korea. The purpose was to fan out quickly available talent at headquarters so that qualified representatives of the Mission would be available in all parts of the Empire to evaluate targets, to interrogate Japanese naval and civilian personnel, and to report in summary form, the intelligence value of that area. A secondary purpose was to provide qualified Navy personnel in each area who could clear all naval equipment for demolition and who could when necessary instruct Army or Marine personnel in methods of demolition.
The magnitude of the task assigned to the Mission presented almost immediately two major difficulties. One was the increasing necessity for well-equipped and competent technicians to cover the vast field of Japanese naval developments. Qualified specialists and experts had already been requested from the Bureau of Ships, the Bureau of Ordnance, the Bureau of Yards and Docks and the Bureau of Medicine and Surgery. This problem was quickly solved by the immediate action of the bureaus concerned. The best officers and technicians in their respective fields were made available, and in not a few instances that personnel had a valuable knowledge of the Japanese and their language through having either been born in Japan or having lived there before the war.
The second, but nonetheless important difficulty confronting the Mission, was one of location. Sasebo, located on the island of Kyushu, is in a provincial and agricultural area of Japan, as far removed from the scientific and technical centers in the vicinity of Tokyo as it is possible to be and yet remain on the main islands of the Empire. It was evident from the very beginning that this headquarters location would add to the complexities of obtaining information, make difficult the interrogation of Japanese scientists, engineers and naval officers, and would not permit adequate liaison with the Military Intelligence Section of the General Staff of the Supreme Commander for the Allied Powers (SCAP). Every day the Mission attempted to operate with headquarters at Sasebo only served to prove the handicap which that location placed upon it. It was remote from all the industrial centers of Japan; communications were poor; and all intelligence units operating in the Empire, such as US Strategic Bombing Survey (USSBS), the Compton-Moreland Scientific Survey, the Air Technical Intelligence Group, and the Military Intelligence Section of SCAP had headquarters in Tokyo. The function of the Naval Technical Mission to Japan had to be correlated with the activities of these groups in order that all intelligence units could profit from the disclosures obtained by each.
The basic technical intelligence instruction from SCAP, dated 2 October 1945, directed that the Assistant Chief of Staff, G-2 [intelligence], coordinate and supervise the exploitation of intelligence targets in Japan and Korea. Location of headquarters in Tokyo thus became mandatory and immediate steps were taken to obtain permission to shift the headquarters of the Mission to this central location. Permission was finally granted just prior to 1 November 1945 to relocate the headquarters of the Mission in Tokyo.
All logistic support for the Mission, such as food and quarters for the overflow of officers and men billeted in Tokyo, Army winter uniforms for all personnel, and maintenance of automotive equipment were provided by the Army. The Mission could not have satisfactorily completed its work in Japan without this assistance.
The administrative offices of the Mission remained aboard Blackford, but the office of the Chief of the Mission was established in the Meiji Building in the downtown section of Tokyo. The Technical Department, under whose cognizance came the responsibility for accomplishing the specific tasks of the Mission, was also established in the Meiji Building and space was allocated for conferences and interrogations. Thus the working unit was in close proximity to other intelligence units and liaison offices, an arrangement which provided a very satisfactory and efficient method of operation.
By 1 November 1945 the Mission had grown to approximately 295 officers, 125 enlisted men and 10 naval technicians. Among the officers was a delegation of approximately 23 British technical specialists and language officers, an able and experienced group which cooperated effectively on many difficult investigations. There was a constant turn-over in the personnel attached to the Mission due to the arrival of specialists and the detachment of officers having completed their assignments.
In addition, there were two other activities in the Technical Department. One was the Progress and Reports Section which was charged with the responsibility of filing intelligence material, and with the receiving, editing, typing, and final printing of the technical reports of the Mission. This section also correlated the activities of each section to eliminate duplication and maintained progress data on the exploitation of each target so that the overall completion of the Mission's work could be predicted. It is interesting to note in passing that nearly all typists in this section, about 20 in all, were Japanese civilians. A considerable amount of drafting (some 3000 items were eventually drafted) was necessary in connection with preparation of reports, and this work was originally done largely by Japanese obtained form the Ship Construction Section of the Technical Department of the Japanese Navy Ministry.
The other activity in the Technical Department was designated Technical Liaison, G-2, SCAP. Immediately on arrival of the Mission in Tokyo, an officer was detailed as NavTechJap Liaison Officer to Military Intelligence Section, G-2, SCAP. This officer attended all General Headquarters, SCAP policy-forming conferences and meetings which affected naval intelligence. He cleared all naval intelligence targets with and passed all intelligence material and information gathered by the Mission to the Military Intelligence Section, G-2. This close cooperation between the two organizations benefited both and resulted in a respect and admiration for the quality of work which both organizations were doing. It immeasurably improved the quality of the overall intelligence gathered in this area.
In addition to the Technical and Executive Departments, a separate Special Intelligence Group was maintained. This group was employed in the exploitation of such non-technical targets as were requested by higher authority, or as were left uncompleted on the departure from Japan of the U.S. Strategic Bombing Survey.
Figure 1 presents graphically the overall organization of the Mission.
On 1 November 1945, Commander Fifth Fleet ordered the Chief of the Mission to designate one officer for each Army, Corps and Division area in Japan, who, in addition to his duties with NavTechJap, would act as liaison officer from the Fifth Fleet to the Army unit. The estimated officer requirements for this liaison service was 25 senior officers. The Fifth Fleet Liaison Officers were established to place a qualified naval officer with each Army unit who could initiate action to clear naval problems arising in the Army unit and who could make recommendations to the Army, when requested, on methods of demolition of Japanese Navy equipment. Figure 2 shows the organization of the Liaison Service.
Another helpful guide was the "Report on Scientific Intelligence Survey in Japan, 1 November 1945" (the so-called "Compton-Moreland Report") summarizing the findings of a small group of scientists who, in September and October 1945, made a quick survey of the Japanese organization for scientific research and development. In fact, members of that mission, before publication of their report, gave advance suggestion to NavTechJap concerning certain fields of devices meriting immediate detailed investigation.
With "Intelligence Targets Japan" as a guide, technicians and specialists in a particular field were assigned one or more targets. The activities of the individual investigations were closely supervised and coordinated by the section heads. As requested, key Japanese naval personnel and scientists were produced by the Japanese Liaison Office for interview and interrogation. In nearly all instances one or more of the language officers assigned to NavTechJap were present at these interviews to interpret both questions and answers. Visits were then made to locations where equipment and documents could be found. When deemed advisable, documents and samples of the equipment were seized and sent to one of the four NavTechJap collection centers which had been established at Sasebo, Yokosuka, Kure, and Kobe, where they were prepared for shipment to the United States.
After completion of the field work, the investigators returned to Tokyo where a complete report was first written in long hand. A staff of editors processed each report to determine its completeness and acceptability. The head of the cognizant Technical Department section reviewed the report for technical and engineering accuracy. No officer or technician was permitted to return to the United States until his report had been edited and accepted. Once accepted, the report was typed by the Japanese personnel, in the Progress and Reports Section and made ready for shipment to the printer. In many instances it was necessary to do more than simply investigate the material on hand. For example, a new model, 20-cylinder diesel engine was about fifty percent completed when Japan surrendered and all construction and development of war material stopped. The engine showed promising possibilities. The originating Japanese engineers and scientists were located and brought back to complete its construction at the expense of the Japanese government. Upon completion, tests were run to determine its performance.
The search for data and equipment on Japanese petroleum research seemed hopeless, until the remains of a laboratory were discovered at Ofuna. Most of the documents, data, etc., were said to have been destroyed, but enough remained to indicate that a sizeable establishment was once in operation there. Again the Japanese engineers, draftsmen, scientists and research men formerly employed in the laboratory were assembled to duplicate plans, drawing and experimental data which had been developed. Strangely enough, the Japanese scientists took considerable pride in accomplishing this work to demonstrate the extent of their advancement. The net result was a complete disclosure of Japan's petroleum research.
Editorial work was highly important. Since there were to be nearly two hundred separate reports, uniformity in arrangement was desirable. No effort was made to standardize the author's style, though clarity of expression, accuracy of statements and figures and adequate cross-referencing were necessary if the reports were to be of value. A proper segregation of descriptive matter and tabular statistics was sought, and much material placed at the end of the reports as appendices or enclosures to avoid cluttering up the text. A summary was provided at the beginning of each report to give a quick picture to the reader not interested in detailed descriptions and figures. References were give to other NavTechJap reports on similar or related subjects or to those prepared by other activities such as USSBS, ATIG [should be ATIS (Allied Translation and Intelligence Section)], and TLID.
NavTechJap and JICPOA worked so closely on the production of reports that the problems of one were the direct concern of the other. Difficulty in obtaining an adequate number of typists was matched by the need of capable layout personnel, and the demand for draftsmen was perhaps the hardest of all to solve. About 1 May, for instance, when all possible sail was being crowded to complete the project, NavTechJap had 10 draftsmen on this work, JICPOA furnished 5, Naval Shipyard, Pearl Harbor supplied 25, the 30th Engineer Topographical Battalion at Schofield 6, Naval Shipyard, Mare Island 35, and Naval Shipyard, San Francisco, 15.
All naval activities had common problems resulting form the loss of highpoint, trained personnel and the demobilization of the Naval Reserve. But the work of the draftsman, photographer, printer, required highly specialized skill which made replacement by inexperienced personnel (even when available), a very slow procedure. Consequently the small group of qualified personnel worked under extreme and unceasing pressure. Especial commendation is due JICPOA whose resourcefulness, untiring effort, and admirable "know-how" contributed so much to the success of the concluding phase of this Mission.
NavTechJap investigators, unarmed and often alone, visited scores of places in Japan, both urban and rural, and never once were molested or threatened. Usually the American was ignored, little curiosity being displayed by Japanese adults. When they were asked for information, friendliness and willing cooperation were the general rule.
Of considerable interest was the observation that the Japanese Army and Navy both deliberately spurned the scientist, whose knowledge, laboratories and research equipment might have contributed so much toward a more successful prosecution of the war by the Japanese. The scientist recognized this and felt deeply injured over the lack of confidence in his ability and his loyalty. Little organized research was carried on during the war. A corollary to this, is the fact that by such policy Japan failed, in general, to realize those tremendous and permanent scientific advances that the modern nation gains from huge wartime expenditures for research.
The common concept that the Japanese lack originality and are merely an imitative people is in need of qualification. They entered the fields of science and mechanical industry only a comparatively few years ago. The sensible thing was to engage in wholesale copying until they caught up with other countries. Had they proceeded independently in scientific research and discovery, they would always have been fifty years behind. The Japanese may be especially adept at copying but evidence of their originality and ingenuity is not lacking.
The Japanese received very little effective help from the Germans or the Italians. It is true that the Japanese I-400 type submarines were equipped with Schnorkel, but it is understood the Japanese saw a German submarine in Hong Kong and copied the Schnorkel features. A Japanese submarine crew was sent to Germany for training, but all hands were lost on the trip back. Some assistance was received from Germany pertaining to electronics, but Japan was still well behind us in the design of this equipment. Such information as the Japanese obtained was largely of a general rather than specific nature. The single important exception seems to have been the assistance given by Germany in the sonar field. Some of the Japanese equipment was almost an exact copy of captured British equipment.
At the time of the Pearl Harbor attack, Japan had a strong and well equipped navy, with ships that were of good design and rugged construction. Three of them, the battleships Yamato and Musashi, and the aircraft carrier Shinano, were the largest, and in many respects, the most powerful warships in the world. Yamato and Musashi had standard displacement of 63,000 tons each (when fully loaded, 73,000 tons) and a speed of 28 knots. Their main battery, consisting of nine 46 cm. (18.1-inch) guns had a maximum range of 45,000 yards. This is noteworthy in itself, since they were the largest naval guns in the world.
To match this, the largest United States battleship was the West Virginia of 32,400 tons standard displacement, 21 knots speed, and main battery of eight 16-inch guns.
During the latter part of the war, surface ship production was largely abandoned by the Japanese in favor of submarine production, and during 1944 they brought out the I-400 class, three huge submarines whose primary mission undoubtedly was bombing the Panama Canal and cities of the United States. They had a displacement of 5,550 tons each, a length of 400 feet, a maximum speed of 19.7 knots surfaced and 7 submerged, and cruising range of 34,000 miles at 16 knots. Eight torpedo tubes and one 5.5-inch deck gun comprised the armament. In addition, in a hangar tube (11.6 ft. diameter) on main deck, each submarine carried three bombing planes, each weighing about four tons, capable of 290 knots speed, and carrying a bomb of 0.8 tons on one 18-inch airplane torpedo.
By comparison, our largest submarine was Nautilus, with a displacement of 2730 tons, a length of 371 feet, and speed of 17 knots surfaced and 8.5 submerged and a cruising range of 15,000 miles. The armament consisted of eight tubes for 21-inch torpedoes and two 5-inch guns which were later replaced by 3-inch.
The Japanese developed very successfully torpedoes of three different types, using pure oxygen, air, and electricity for propulsion. There was nothing unusual about the 18-inch, air-driven torpedo, but the 21-inch electric type, with a range of 7500 yards at 30 knots, was an effective weapon because it left no wake, was easy to manufacture and hence used extensively.
In time of war persons of every nationality show unlimited courage and self-sacrifice, but never before was the willingness of the individual soldier to destroy himself so incorporated into the wartime policy of a nation. When Japan was forced to change from offensive to defensive warfare, she realized it would cost the lives of many brave men, but coolly and efficiently she devised plans and equipment which would take numerous enemy lives in exchange for each native son.
The best known of these implements of self-destruction was the Kamikaze plane, which was considered not so much a projectile carrier as the projectile itself, with a human being as part of its steering and control mechanism. The men who volunteered for this one-way ride were a select group of Japan's best pilots, and there were always more volunteers than planes.
The Baka Bomb and its human control was a variation of the same idea of death in and from the air.
On the surface of the water, it took the form of Shinyo, a small special attack boat which utilized the explosive charge in its bow by ramming the side of the intended victim. These motor boats were collected in special attack basins along the coast or carried on mother ships. Such suicide craft were manned by middle school boys of 15 and 16 years of age. It is reported that a supply of volunteer pilots was obtained because of special privileges, early responsibility, fast promotion, and the promise of a posthumous monetary award to the volunteer's parents.
Underwater opportunities for destruction stimulated the Japanese imagination. The Kaiten ("Great Undertaking") was a one-man submarine which was substantially an altered torpedo having human control and additional fuel capacity inserted between the torpedo warhead and the torpedo engine. Six Kaiten were carried on the deck of I-type submarines and connected by tubes through which the pilot could enter the torpedo and start on his journey without the submarine having to surface. These midget or suicide subs were manned by young volunteers of 18 to 20 years, attracted by much the same inducements offered the Shinyo pilots. The Japanese claimed great success in the encounters between Kaiten and enemy shipping.
The Japanese had amphibious tanks 35 feet long, that rode "piggy back" on submarines. In preparation for an attack, the submarine would surface, and, after the tank had drained, it would be boarded by a crew of one officer and six men and a landing party of 35 men. The tank would then be driven off the sub, or the later would submerge, leaving the water-borne tank ready to proceed under her own power. When the Nipponese strategy turned defensive in 1944, these sea-going tanks were modified to include torpedo cradles. Upon reaching an objective, both torpedoes would be released at short range. No attempt to return ashore for re-loading would have been made, as the expendable tank would have simply been scuttled on the spot, and the brave but hapless crew would join their honorable ancestors. (These mechanical oddities were never known to have been used operationally although about 100 were built.)
Still another, though less well-known suicide group, was the Fukuru, or "Crouching Dragons." Had the war reached the stage of repelling an amphibious landing on the shores of Honshu, the Fukuru were prepared and equipped to walk underwater and ram an explosive bomb against the hull of an enemy landing craft. These "underwater kamikazes" wore diving suits equipped with two oxygen tanks, submarine-type air cleaning devices, and tubes for liquid food, and could operate effectively in water 50 feet deep, walk underwater more than a mile an hour, and stay underwater for ten hours. At the war's end, 4,000 Fukurus were at the Yokosuka Naval Base, of whom 1200 were fully trained.
Loss of much of her shipping capacity and the resulting fuel and food shortage caused Japan to give consideration to suggestions by her oceanographers that ocean currents be utilized for transportation of necessities. Since 90% of the drift bottles set adrift in the Japanese Sea off the east coast of Korea reached the northern part of Honshu it seemed feasible to use the Kuroshio (Japan Current) for the transportation of soya beans from Manchuria and other goods from Formosa, Nansei Shoto, etc., to Japan proper. A small wooden ship of 200 tons was successfully floated form Fusan to Honshu. Then plans were made for floating metal drums which would drift below the surface but some in every lot would be equipped with radios, and at intervals would rise and be contacted by land stations in order that their movements could be traced. Loss of the Philippines meantime, prevented carrying out the plan.
Japan was far behind us in the field of electronics, but her experiments with a "Death Ray" may have the unique outcome of saving countless lives threatened by tuberculosis. These experiments showed a pronounced effect on the lungs of the animals tested, and further research was contemplated toward a possible cure for tuberculosis. It was noticed that higher frequencies affected the brain. The investigators realized that heat was an evident factor but were sure that frequency was important also. The frequency characteristic could be associated with the resonance dimensions of the head and body respectively. It is quite possible that Japanese or American investigators may develop treatment for tuberculosis and for certain brain disorder that will have great therapeutic value. A mass chest X-ray program for the diagnosis of tuberculosis was interrupted by the war, but Japan was using an "immunization" technique that should be further investigated.
The Japanese medical officers observed that most cases of night-blindness occurred with pilots having liver trouble and whose secretion of the bile was not normal. Acting on this hint, they developed a preparation named "Mogozai" whose ingredients stimulate the secretion of the bile and the absorption of Vitamin A, so necessary for the retina of the eye. The vision of the dark-adapted eye when taking this preparation improved from 11/2 to 2 times. This means, looking at the same object, the eye can see if from twice the distance.
More notable, and certainly more far reaching, is the discovery of two drugs by Japanese who were searching for some therapeutic agent resembling chlorophyll, with its power of converting sunlight into energy. These were derived from neocyaine and named Koha and Shiko (meaning Rainbow Wave and Violet Light). The drugs improve general body resistance and stimulate regeneration of tissue. The Japanese have demonstrated remarkable results when used in leprosy cases. Burns and frostbite responded with gratifying acceleration, while benzine burns and boiling water burns especially, showed quick improvement.
Of considerable interest is an unusual type of hangar construction that the Japanese had developed. It was called the "Diamond Truss," from the diamond-shaped pattern formed by the intersecting arches. It is in reality a hangar made of a series of intersecting skew arches. In this novel design, the skewed arches form the longitudinal bracing of the structure in addition to taking the regular loading. The design resulted in a tremendous saving of steel. At first glance it would appear that the cost of fabrication of such an unorthodox structure would be prohibitive, but actually, no bent plates or structural shapes were necessary and standardization on the sizes of hangars kept the steel detailing to a minimum. The entire structural frame is made up of plates and angles. To avoid complicated framing at the intersections of the arches, the top and bottom chords of the arches were cut and framed into gusset plates. This type of construction might well receive consideration by our architects and builders for any structure where large roofing areas are involved, such as hangars, garages, factory and mill buildings, armories, and gymnasia.
Petroleum was the "Achilles Heel" in the Japanese armor, and her lack of this precious fuel was the fundamental cause of her downfall. When the Japanese super-battleship Yamato made her suicidal sortie southwest of Kyushu in the waning months of the war, she was powered by edible refined soya bean oil. US Navy planes sank the soy bean-burning warship on 7 April 1945 when she was intercepted enroute to attack American shipping at Okinawa.
Lack of oil resources kept scores of Nipponese ships lying immobile in Kure and other ports and many of her battleships and cruisers were sitting-duck targets, easily sunk by bombs and torpedoes dropped by our airmen.
Japan's efforts to find substitute fuels were frantic (and to a limited extent effective), but entirely inadequate. Until the beginning of the war, the Japanese Navy's chief source of diesel and bunker fuel was imports from California. This stockpile was exhausted in 1942 and cracked residues form Sumatra and Borneo crudes were then utilized as bunker fuels. In 1944, due to Japanese tanker losses to US submarines, research and practical testing were undertaken on both diesel and boiler fuels to develop substitutes. By the spring of 1945 aircraft carriers were utilized as tankers to bring motor gasoline from Singapore to be used as charging stock in the manufacture of even more desperately needed aviation fuel.
Satisfactory diesel fuels were produced form coconut oil, hydro cracked; pressed copra oil; esterfied copra oil; and soya bean oil. Pine root oil was used too, but had a tendency to leave gummy deposits in the engine. A determined effort was made to develop an industry for converting coal into oil, but the results were comparatively insignificant. As a matter of fact, the outputs of oil from shale at Fushan, until 1944, exceeded the combined output from all coal conversion processes.
During the last year of the war, the Japanese had considerable success with a program for producing alcohol and using alcoholic aviation fuels. For instance, they were able to produce one pound of ethyl alcohol from the fermentation of eleven pounds of sweet potatoes. This in turn necessitated vital decisions about which varieties of potatoes were best for food and which best for fuel, and how the two should be apportioned to keep the nation alive to fight.
By the spring of 1944, the supply of cane sugar and molasses from Formosa, Java, and the Philippines was decreasing and more emphasis was placed on Manchurian grain as a raw material source of ethyl alcohol. Finally, butanol plants were converted to the production of ethyl alcohol. Thus the Japanese were converting rubber into gasoline for war purposes while in America gasoline was being converted into rubber, with the same end in view.
During the existence of the Mission, 350 officers and 260 enlisted men (Army, Navy and Marines), 29 British officers and men, and 16 naval technicians, (a total of 655) reported for duty.
A total of 185 separate reports comprising approximately 10,000 printed pages, were prepared and 500 copes of each were printed. Few sets of these rare reports still exist. The Navy Department Library owns an incomplete set of 154 reports, which were acquired in January 2005.
Approximately 3500 documents were seized and shipped to the Washington Document Center and the technical bureaus of the Navy Department. These records are located in Record Group 38.4.15 at the National Archives in College Park, Maryland. Records of the Naval Technical Misison to Europe are also located in Record Group 38.4.15.
Approximately 15,000 pieces of equipment were seized and shipped to the United States for laboratory investigation. The largest items were two 18.1-inch guns shipped from Kure, each 75 feet long and weighing 180 tons.
|Title [Report Number]||Call Number in|
|Summary Report (History of the Mission)||D820.S2 U529 1946|
|Aircraft Arrangements and Handling Facilities in Japanese
Naval Vessels [A-11].
|D820.S2 U522 A-11|
|Japanese Naval Photography [A-39].||D820.S2 U522 A-39|
|Japanese Airborne Radar [E-02].||D820.S2 U524 E-02|
|Japanese Land-Based Radar [E-03].||D820.S2 U524 E-03|
|Japanese Centimeter Wave Technique [E-04].||D820.S2 U524 E-04|
|Japanese Radio and Radar Direction Finders [E-05].||D820.S2 U524 E-05|
|Japanese Anti-Radar Coverings [E-06].||D820.S2 U524 E-06|
|Japanese Radar Countermeasures and Visual Signal Display
|D820.S2 U524 E-07|
|Japanese Radio Equipment [E-08].||D820.S2 U524 E-08|
|Japanese Navigational Aids [E-09].||D820.S2 U524 E-09|
|Japanese Sonar and ASDIC [E-10].||D820.S2 U524 E-10|
|Japanese Communication Systems [E-11].||D820.S2 U524 E-11|
|Japanese Experimental Radar [E-12].||D820.S2 U524 E-12|
|Japanese Electronic Tubes [E-13].||D820.S2 U524 E-13|
|Japanese Magnetic Airborne Detector [E-14].||D820.S2 U524 E-14|
|Power Supplies for Japanese Electronics [E-15].||D820.S2 U524 E-15|
|Japanese Radio, Radar, and Sonar Equipment [E-17].||D820.S2 U524 E-17|
|Japanese Radio Apparatus Construction Methods [E-18].||D820.S2 U524 E-18|
|Japanese Electronic Equipment Construction Materials [E-19].||D820.S2 U524 E-19|
|Japanese R.F. Transmission Lines, Wave Guides, Wave Guide Fittings, and Dielectric Materials [E-20].||D820.S2 U524 E-20|
|Japanese Radio Frequency Measuring Technique [E-22].||D820.S2 U524 E-22|
|Japanese Insulation Materials [E-23].||D820.S2 U524 E-23|
|Japanese Electronic Harbor Protection Equipment [E-26].||D820.S2 U524 E-26|
|Japanese Electronics -- General [E-28].||D820.S2 U524 E-28|
|Japanese Electronics Training and Operating Techniques [E-29].||D820.S2 U524 E-29|
|Japanese Electronics -- Miscellaneous [E-30(N)].||D820.S2 U524 E-30(N)|
|Data Relative to Life in the Jungle and on Sea Islands, and Data on Composition of Insecticides [M-01].||D820.S2 U525 M-01|
|Dentistry in the Japanese Armed Forces [M-02].||D820.S2 U525 M-02|
|Information Relative to Venereal Disease Control in Japan [M-04].||D820.S2 U525 M-04|
|Japanese Bacteriological Warfare [M-05].||D820.S2 U525 M-05|
|Aero, Surface, and Submarine Medicine and Research in the Japanese Navy [M-06].||D820.S2 U525 M-06|
|Preventive Medicine and Public Health Organization and Facilities in the Japanese Navy [M-09].||D820.S2 U525 M-09|
|Bacteriology and Chemistry in the Japanese Navy [M-10].||D820.S2 U525 M-10|
|General Medicine and Special Diseases in the Japanese Navy [M-11].||D820.S2 U525 M-11|
|Pharmacology and Malariology in Japan -- Civilian and Naval [M-12].||D820.S2 U525 M-12|
|Neuropsychiatry in the Japanese Armed Forces [M-D].||D820.S2 U525 M-D|
|Japanese Torpedoes and Tubes -- Article 1 -- Ship and Kaiten Torpedoes [O-01-1].||D820.S2 U527 O-01-1|
|Japanese Guided Missiles [O-02].||D820.S2 U527 O-02|
|Japanese Countermeasures and Defensive Organization Against U.S. Mines [O-03].||D820.S2 U527 O-03|
|Japanese Mines [O-04].||D820.S2 U527 O-04|
|Japanese Naval Mining Organization and Operational Techniques [O-05].||D820.S2 U527 O-05|
|Japanese Bomb Disposal Methods [O-06].||D820.S2 U527 O-06|
|Ship Signatures and Related Data [O-07].||D820.S2 U527 O-07|
|Japanese Depth Charges [O-08].||D820.S2 U527 O-08|
|Japanese Propellants -- Article 1 -- The Use and Manufacture of Ortho Tolyl Urethane for Stabilizing Rocket and Gun Propellants [O-10-1].||D820.S2 U527 O-10-1|
|Japanese Propellants -- Article 2 -- Rocket and Gun Propellants, General [O-10-2].||D820.S2 U527 O-10-2|
|Japanese Propellants -- Article 3 -- Research on Non-Volatile Solvent Powers [O-10-3].||D820.S2 U527 O-10-3|
|Japanese Illuminating and Colored Burst Projectiles [O-11].||D820.S2 U527 O-11|
|Japanese Navy Ammunition Cases for 5cm and Larger Caliber Guns [O-14].||D820.S2 U527 O-14|
|Japanese Steel Manufacturing Methods [O-15].||D820.S2 U527 O-15|
|Japanese Heavy Armor [O-16].||D820.S2 U527 O-16|
|Japanese Ordnance Fuzes [O-18].||D820.S2 U527 O-18|
|Japanese Ammunition Primers [O-20].||D820.S2 U527 O-20|
|Japanese Interior Ballistics [O-21].||D820.S2 U527 O-21|
|Japanese Tracers [O-22].||D820.S2 U527 O-22|
|Japanese Bombs [O-23].||D820.S2 U527 O-23|
|Description and Operations of Japanese Type 3 Photoelectric Fuse [O-24].||D820.S2 U527 O-24|
|Japanese Explosives [O-25].||D820.S2 U527 O-25|
|Japanese Navy Powder Bags [O-26].||D820.S2 U527 O-26|
|Japanese Incendiary Mixtures [O-27].||D820.S2 U527 O-27|
|Japanese Fire Control [O-29].||D820.S2 U527 O-29|
|Japanese Anti-Aircraft Fire Control [O-30].||D820.S2 U527 O-30|
|Japanese Surface and General Fire Control [O-31].||D820.S2 U527 O-31|
|Japanese Torpedo Fire Control [O-32].||D820.S2 U527 O-32|
|Japanese Demolition Methods [O-35].||D820.S2 U527 O-35|
|Japanese Light Armor, Article 1 [O-36-1].||D820.S2 U527 O-36-1|
|Japanese Light Armor, Article 2 [O-36-2].||D820.S2 U527 O-36-2|
|Japanese Ordnance Research, Testing and Training [O-38].||D820.S2 U527 O-38|
|Japanese Ordnance Research, Article 1 -- Gunfire Testing of Bombs at the Kamegakubi Proving Ground [O-39-1].||D820.S2 U527 O-39-1|
|Japanese Ordnance Research, Article 2 -- Experimental Research on Super High Velocity Guns and Projectiles [O-39-2].||D820.S2 U527 O-39-2|
|Japanese Ordnance Research, Article 3 -- Torpedo Models [O-39-3].||D820.S2 U527 O-39-3|
|Japanese Ordnance Research, Article 4 -- Laboratory Procedures [O-39-4].||D820.S2 U527 O-39-4|
|Japanese Research in Airborne Acoustics and Earthwaves [O-41].||D820.S2 U527 O-41|
|Japanese Ordnance Equipment -- Internal Recorders, Wave and Tide Meters, Torpedo Recovery Gear, Underwater Locators [O-42].||D820.S2 U527 O-42|
|Effectiveness of Japanese AA Fire [O-44].||D820.S2 U527 O-44|
|Japanese 18" Guns and Mounts [O-45(N)].||D820.S2 U527 O-45(N)|
|Japanese Naval Guns and Mounts, Article 2 -- AA Machine Guns and Mounts [O-47(N)-2].||D820.S2 U527 O-47(N)-2|
|Japanese Muzzle Brakes and Flash Hiders [O-49(N)].||D820.S2 U527 O-49(N)|
|Hydraulic Pumps in Japanese Naval Ordnance [O-53(N)].||D820.S2 U527 O-53(N)|
|Japanese Naval Guns [O-54(N)].||D820.S2 U527 O-54(N)|
|Defenses of Tsushima and Entrance to Sea of Japan [O-55(N)].||D820.S2 U527 O-55(N)|
|Characteristics of Japanese Naval Vessels, Article 2 -- Surface Warship Machinery Design [S-01-2].||D820.S2 U528 S-01-2|
|Characteristics of Japanese Naval Vessels, Article 3 -- Surface Warship Hull Design [S-01-3].||D820.S2 U528 S-01-3|
|Characteristics of Japanese Naval Vessels, Article 4 -- Surface Warship Machinery Design (Plans and Documents) [S-01-4].||D820.S2 U528 S-01-4|
|Characteristics of Japanese Naval Vessels, Article 5 -- Shipboard Electrical Equipment [S-01-5].||D820.S2 U528 S-01-5|
|Characteristics of Japanese Naval Vessels, Article 6 -- Submarines Supplement I [S-01-6].||D820.S2 U528 S-01-6|
|Characteristics of Japanese Naval Vessels, Article 7 -- Submarines -- Supplement II [S-01-7].||D820.S2 U528 S-01-7|
|Characteristics of Japanese Naval Vessels, Article 8 -- Portable Gasoline-Driven Pump Unit [S-01-8].||D820.S2 U528 S-01-8|
|Characteristics of Japanese Naval Vessels, Article 9 -- Underwater Protection [S-01-9].||D820.S2 U528 S-01-9|
|Characteristics of Japanese Naval Vessels, Article 10 -- Landing Craft [S-01-10].||D820.S2 U528 S-01-10|
|Characteristics of Japanese Naval Vessels, Article 11 -- Main and Auxiliary Machinery [S-01-11].||D820.S2 U528 S-01-11|
|Characteristics of Japanese Naval Vessels, Article 12 -- Boilers and Machinery [S-01-12].||D820.S2 U528 S-01-12|
|Characteristics of Japanese Naval Vessels, Article 13 -- Gas Turbines [S-01-13].||D820.S2 U528 S-01-13|
|Japanese Suicide Craft [S-02].||D820.S2 U528 S-02|
|Photographs of Important Japanese Naval Units Afloat [S-03].||D820.S2 U528 S-03|
|Reports of Damage to Japanese Warships, Article 1 -- Nagato (BB), Katsuragi (CV), Haruna (BB), Aoba (CA), Ise (BB), Amagi (CV), Ryuho (CVL), Oyodo (CL), Tone (CA), Hyuga (BB), Aso (CV), Suzutsuki (DD) [S-06-1].||D820.S2 U528 S-06-1|
|Reports of Damage to Japanese Warships, Article 2 -- Yamato (BB), Musashi (BB), Taiho (CV), Shinano (CV) [S-06-2].||D820.S2 U528 S-06-2|
|Reports of Damage to Japanese Warships, Article 3 -- Japanese Records of Major Warship Losses [S-06-3].||D820.S2 U528 S-06-3|
|Survey of Operable or Salvable Japanese Merchant Vessels [S-11].||D820.S2 U528 S-11|
|General Arrangement and Capacity Plans of Japanese Standard Type Merchant Ships [S-12].||D820.S2 U528 S-12|
|Japanese Submarines Operations [S-17]||D820.S2 U528 S-17|
|Japanese Submarine Equipment [S-19].||D820.S2 U528 S-19|
|Japanese Anti-Submarine Warfare [S-24].||D820.S2 U528 S-24|
|Japanese Minesweeping Gear and Equipment [S-28].||D820.S2 U528 S-28|
|Japanese Degaussing [S-37].||D820.S2 U528 S-37|
|Japanese Ships -- Miscellaneous Items [S-40].||D820.S2 U528 S-40|
|Japanese Navy -- Diesel Engines [S-42].||D820.S2 U528 S-42|
|Japanese Naval Vessels -- Own Ships Noise [S-43].||D820.S2 U528 S-43|
|Japanese Navy Paints [S-59].||D820.S2 U528 S-59|
|Welding in Japanese Naval Construction [S-81(N)].||D820.S2 U528 S-81(N)|
|Provisions for Military Conversion of Japanese Merchant Ships [S-82(N)].||D820.S2 U528 S-82(N)|
|Japanese Model Basins [S-83(N)].||D820.S2 U528 S-83(N)|
|Japanese Damage Control [S-84(N)].||D820.S2 U528 S-84(N)|
|Special Underwater Attack Units (Fukuryu) and Harbor Defense Measures [S-91(N)].||D820.S2 U528 S-91(N)|
|Lead-Acid Storage Batteries Used by the Japanese Navy [S-92(N)].||D820.S2 U528 S-92(N)|
|Tenth Military Experimental Station, Murotsu, Honshu, Japan [S-93(N)].||D820.S2 U528 S-93(N)|
|Japanese Evaluation of US Anti-Submarine Harbor Defenses [S-94(N)].||D820.S2 U528 S-94(N)|
|Woods, Textiles, Rubber, and Plastics Used in Japanese Naval Vessels [S-95(N)].||D820.S2 U528 S-95(N)|
|Japanese Deck Coverings [S-96(N)].||D820.S2 U528 S-96(N)|
|Japanese Anchors and Anchor Chain [S-97(N)].||D820.S2 U528 S-97(N)|
|Japanese Infra-Red Devices, Article 1 -- Control for Guided Missiles [X-02-1].||D820.S2 U526 X-02-1|
|Japanese Infra-Red Devices, Article 2 -- Heat Locater Equipment [X-02-2].||D820.S2 U526 X-02-2|
|Japanese Infra-Red Devices, Article 3 -- Research Development, and Manufacture of Infra-Red Equipment [X-02-3].||D820.S2 U526 X-02-3|
|Japanese Ultra-Violet Communication Equipment [X-03].||D820.S2 U526 X-03|
|Japanese Geophysical Research [X-06].||D820.S2 U526 X-06|
|Earthquake Resistant Construction in Japan [X-12].||D820.S2 U526 X-12|
|Japanese Metallurgy, Article 1 -- High Temperature Alloys for Gas Turbines, Rocket Nozzles, and Lines [X-13-1].||D820.S2 U526 X-13-1|
|Japanese Metallurgy, Article 2 -- Recovery of Aluminum from Clay and Shale [X-13-2].||D820.S2 U526 X-13-2|
|Japanese Metallurgy, Article 3 -- Atomic Structure Relative to Dynamic Properties [X-13-3].||D820.S2 U526 X-13-3|
|Quality of Japanese Electric Wires and Cables [X-14].||D820.S2 U526 X-14|
|Japanese Aerology [X-16].||D820.S2 U526 X-16|
|Japanese Meteorological Instruments [X-17].||D820.S2 U526 X-17|
|Japanese Hydrography, Article 1 -- Organization, Operations, and Methods [X-18-1].||D820.S2 U526 X-18-1|
|Japanese Hydrography, Article 2 -- Wind and Weather Data, Including High Altitude Radar Maps [X-18-2].||D820.S2 U526 X-18-2|
|Japanese Hydrography, Article 3 -- Wartime Activities of International Latitude Observatory, Misusawa, Iwate Prefecture, Japan [X-18-3].||D820.S2 U526 X-18-3|
|Japanese Fungus, Moisture-Proofing, and Antifungus Data [X-20].||D820.S2 U526 X-20|
|Japanese Use of Balloons for Barrage, Bombing, and Aerology [X-21].||D820.S2 U526 X-21|
|Bombproof Construction in Japan [X-31].||D820.S2 U526 X-31|
|Camouflage of Japanese Ships and Naval Installations [X-32].||D820.S2 U526 X-32|
|Design of Japanese Structures [X-33].||D820.S2 U526 X-33|
|Japanese Welding Standards [X-36(N)].||D820.S2 U526 X-36(N)|
|Japanese Methods of High Frequency Induction Heating and Melting [X-37(N)].||D820.S2 U526 X-37(N)|
|Japanese Fuels and Lubricants, Article 1 -- Fuel and Lubricant Technology [X-38(N)-1].||D820.S2 U526 X-38(N)-1|
|Japanese Fuels and Lubricants, Article 3 -- Naval Research on Alcohol Fuel [X-38(N)-3].||D820.S2 U526 X-38(N)-3|
|Japanese Fuels and Lubricants, Article 4 -- Pine Root Oil Program [X-38(N)-4].||D820.S2 U526 X-38(N)-4|
|Japanese Fuels and Lubricants, Article 5 -- Research on Rocket Fuels of the Hydrogen Peroxide-Hydrazine Type [X-38(N)-5].||D820.S2 U526 X-38(N)-5|
|Japanese Fuels and Lubricants, Article 6 -- Research on Diesel and Boiler Fuel at the First Naval Fuel Depot, Ofuna [X-38(N)-6].||D820.S2 U526 X-38(N)-6|
|Japanese Fuels and Lubricants, Article 7 -- Progress in the Synthesis of Liquid Fuels from Coal [X-38(N)-7].||D820.S2 U526 X-38(N)-7|
|Japanese Fuels and Lubricants, Article 8 -- Naval Research on Lubricants [X-38(N)-8].||D820.S2 U526 X-38(N)-8|
|Japanese Fuels and Lubricants, Article 9 -- Fundamental Hydrocarbon Research [X-38(N)-9].||D820.S2 U526 X-38(N)-9|
|Japanese Fuels and Lubricants, Article 10 -- Miscellaneous Oil Technology and Refining Installations [X-38(N)-10].||D820.S2 U526 X-38(N)-10|
|Miscellaneous Reports of Various Japanese Naval Research Activities [X-39(N)].||D820.S2 U526 X-39(N)|
|Oceanography in Japan [X-40(N)].||D820.S2 U526 X-40(N)|
|Japanese Naval Guns and Mounts, Article 1 -- Mounts Under 18" [X-47(N)-1]||D820.S2 U526 X-40(N)|
|Summary Report [History of the Mission]|
|A-11||Aircraft Arrangements and Handling Facilities in Japanese Naval Vessels.|
|A-39||Japanese Naval Photography.|
Documents and Intelligence Reports:
|D-II E-3||Japanese Navy League.|
|D-II E-8||Gakuto Kaiyo Kai-Sea Students Association.|
|E-01||Japanese Submarine and Shipborne Radar.|
|E-02||Japanese Airborne Radar.|
|E-03||Japanese Land-Based Radar.|
|E-04||Japanese Centimeter Wave Technique.|
|E-05||Japanese Radio and Radar Direction Finders.|
|E-06||Japanese Anti-Radar Coverings.|
|E-07||Japanese Radar Countermeasures and Visual Signal Display Equipment.|
|E-08||Japanese Radio Equipment.|
|E-09||Japanese Navigational Aids.|
|E-10||Japanese Sonar and ASDIC.|
|E-11||Japanese Communication Systems.|
|E-12||Japanese Experimental Radar.|
|E-13||Japanese Electronic Tubes.|
|E-14||Japanese Magnetic Airborne Detector.|
|E-15||Power Supplies for Japanese Electronics.|
|E-17||Japanese Radio, Radar, and Sonar Equipment.|
|E-18||Japanese Radio Apparatus Construction Methods.|
|E-19||Japanese Electronic Equipment Construction Materials.|
|E-20||Japanese R.F. Transmission Lines, Wave Guides, Wave Guide Fittings, and Dielectric Materials.|
|E-22||Japanese Radio Frequency Measuring Technique.|
|E-23||Japanese Insulation Materials.|
|E-26||Japanese Electronic Harbor Protection Equipment.|
|E-28||Japanese Electronics -- General.|
|E-29||Japanese Electronics Training and Operating Techniques.|
|E-30(N)||Japanese Electronics -- Miscellaneous.|
|M-01||Data Relative to Life in the Jungle and on Sea Islands, and Data on Composition of Insecticides.|
|M-02||Dentistry in the Japanese Armed Forces.|
|M-03||Podiatry in the Japanese Navy.|
|M-04||Information Relative to Venereal Disease Control in Japan.|
|M-05||Japanese Bacteriological Warfare.|
|M-06||Aero, Surface, and Submarine Medicine and Research in the Japanese Navy.|
|M-07||Opportunity for Infection of Naval Personnel With Tuberculosis in Japan.|
|M-09||Preventive Medicine and Public Health Organization and Facilities in the Japanese Navy.|
|M-10||Bacteriology and Chemistry in the Japanese Navy.|
|M-11||General Medicine and Special Diseases in the Japanese Navy.|
|M-12||Pharmacology and Malariology in Japan -- Civilian and Naval.|
|O-01-1||Japanese Torpedoes and Tubes -- Article 1 -- Ship and Kaiten Torpedoes.|
|O-02||Japanese Guided Missiles.|
|O-03||Japanese Countermeasures and Defensive Organization Against US Mines.|
|O-05||Japanese Naval Mining Organization and Operational Techniques.|
|O-06||Japanese Bomb Disposal Methods.|
|O-07||Ship Signatures and Related Data.|
|O-08||Japanese Depth Charges.|
|O-10-1||Japanese Propellants -- Article 1 -- The Use and Manufacture of Ortho Tolyl Urethane for Stabilizing Rocket and Gun Propellants.|
|O-10-2||Japanese Propellants -- Article 2 -- Rocket and Gun Propellants, General.|
|O-10-3||Japanese Propellants -- Article 3 -- Research on Non-Volatile Solvent Powers.|
|O-11||Japanese Illuminating and Colored Burst Projectiles.|
|O-14||Japanese Navy Ammunition Cases for 5cm and Larger Caliber Guns.|
|O-15||Japanese Steel Manufacturing Methods.|
|O-16||Japanese Heavy Armor.|
|O-18||Japanese Ordnance Fuzes.|
|O-20||Japanese Ammunition Primers.|
|O-21||Japanese Interior Ballistics.|
|O-24||Description and Operations of Japanese Type 3 Photoelectric Fuse.|
|O-26||Japanese Navy Powder Bags.|
|O-27||Japanese Incendiary Mixtures.|
|O-29||Japanese Fire Control.|
|O-30||Japanese Anti-Aircraft Fire Control.|
|O-31||Japanese Surface and General Fire Control.|
|O-32||Japanese Torpedo Fire Control.|
|O-35||Japanese Demolition Methods.|
|O-36-1||Japanese Light Armor, Article 1.|
|O-36-2||Japanese Light Armor, Article 2.|
|O-38||Japanese Ordnance Research, Testing and Training.|
|O-39-1||Japanese Ordnance Research, Article 1 -- Gunfire Testing of Bombs at the Kamegakubi Proving Ground.|
|O-39-2||Japanese Ordnance Research, Article 2 -- Experimental Research on Super High Velocity Guns and Projectiles.|
|O-39-3||Japanese Ordnance Research, Article 3 -- Torpedo Models.|
|O-39-4||Japanese Ordnance Research, Article 4 -- Laboratory Procedures.|
|O-41||Japanese Research in Airborne Acoustics and Earthwaves.|
|O-42||Japanese Ordnance Equipment -- Internal Recorders, Wave and Tide Meters, Torpedo Recovery Gear, Underwater Locators.|
|O-44||Effectiveness of Japanese AA Fire.|
|O-45(N)||Japanese 18" Guns and Mounts.|
|O-47(N)-2||Japanese Naval Guns and Mounts, Article 2 -- AA Machine Guns and Mounts.|
|O-49(N)||Japanese Muzzle Brakes and Flash Hiders.|
|O-53(N)||Hydraulic Pumps in Japanese Naval Ordnance.|
|O-54(N)||Japanese Naval Guns.|
|O-55(N)||Defenses of Tsushima and Entrance to Sea of Japan.|
|S-01-2||Characteristics of Japanese Naval Vessels, Article 2 -- Surface Warship Machinery Design.|
|S-01-3||Characteristics of Japanese Naval Vessels, Article 3 -- Surface Warship Hull Design.|
|S-01-4||Characteristics of Japanese Naval Vessels, Article 4 -- Surface Warship Machinery Design (Plans and Documents).|
|S-01-5||Characteristics of Japanese Naval Vessels, Article 5 -- Shipboard Electrical Equipment.|
|S-01-6||Characteristics of Japanese Naval Vessels, Article 6 -- Submarines, -- Supplement I.|
|S-01-7||Characteristics of Japanese Naval Vessels, Article 7 -- Submarines -- Supplement II.|
|S-01-8||Characteristics of Japanese Naval Vessels, Article 8 -- Portable Gasoline-Driven Pump Unit.|
|S-01-9||Characteristics of Japanese Naval Vessels, Article 9 -- Underwater Protection.|
|S-01-10||Characteristics of Japanese Naval Vessels, Article 10 -- Landing Craft.|
|S-01-11||Characteristics of Japanese Naval Vessels, Article 11 -- Main and Auxiliary Machinery.|
|S-01-12||Characteristics of Japanese Naval Vessels, Article 12 -- Boilers and Machinery.|
|S-01-13||Characteristics of Japanese Naval Vessels, Article 13 -- Gas Turbines.|
|S-02||Japanese Suicide Craft.|
|S-03||Photographs of Important Japanese Naval Units Afloat.|
|S-06-1||Reports of Damage to Japanese Warships, Article 1 -- Nagato (BB), Katsuragi (CV), Haruna (BB), Aoba (CA), Ise (BB), Amagi (CV), Ryuho (CVL), Oyodo (CL), Tone (CA), Hyuga (BB), Aso (CV), Suzutsuki (DD).|
|S-06-2||Reports of Damage to Japanese Warships, Article 2 -- Yamato (BB), Musashi (BB), Taiho (CV), Shinano (CV).|
|S-06-3||Reports of Damage to Japanese Warships, Article 3 -- Japanese Records of Major Warship Losses.|
|S-11||Survey of Operable or Salvable Japanese Merchant Vessels.|
|S-12||General Arrangement and Capacity Plans of Japanese Standard Type Merchant Ships.|
|S-19||Japanese Submarine Equipment.|
|S-24||Japanese Anti-Submarine Warfare.|
|S-28||Japanese Minesweeping Gear and Equipment.|
|S-40||Japanese Ships -- Miscellaneous Items.|
|S-42||Japanese Navy -- Diesel Engines.|
|S-43||Japanese Naval Vessels -- Own Ships Noise.|
|S-59||Japanese Navy Paints.|
|S-81(N)||Welding in Japanese Naval Construction.|
|S-82(N)||Provisions for Military Conversion of Japanese Merchant Ships.|
|S-83(N)||Japanese Model Basins.|
|S-84(N)||Japanese Damage Control.|
|S-91(N)||Special Underwater Attack Units (Fukuryu) and Harbor Defense Measures.|
|S-92(N)||Lead-Acid Storage Batteries Used by the Japanese Navy.|
|S-93(N)||Tenth Military Experimental Station, Murotsu, Honshu, Japan.|
|S-94(N)||Japanese Evaluation of US Anti-Submarine Harbor Defenses.|
|S-95(N)||Woods, Textiles, Rubber, and Plastics Used in Japanese Naval Vessels.|
|S-96(N)||Japanese Deck Coverings.|
|X-02-1||Japanese Infra-Red Devices, Article 1 -- Control for Guided Missiles.|
|X-02-2||Japanese Infra-Red Devices, Article 2 -- Heat Locater Equipment.|
|X-02-3||Japanese Infra-Red Devices, Article 3 -- Research Development, and Manufacture of Infra-Red Equipment.|
|X-03||Japanese Ultra-Violet Communication Equipment.|
|X-06||Japanese Geophysical Research.|
|X-12||Earthquake Resistant Construction in Japan.|
|X-13-1||Japanese Metallurgy, Article 1 -- High Temperature Alloys for Gas Turbines, Rocket Nozzles, and Lines.|
|X-13-2||Japanese Metallurgy, Article 2 -- Recovery of Aluminum from Clay and Shale.|
|X-13-3||Japanese Metallurgy, Article 3 -- Atomic Structure Relative to Dynamic Properties.|
|X-14||Quality of Japanese Electric Wires and Cables.|
|X-17||Japanese Meteorological Instruments.|
|X-18-1||Japanese Hydrography, Article 1 -- Organization, Operations, and Methods.|
|X-18-2||Japanese Hydrography, Article 2 -- Wind and Weather Data, Including High Altitude Radar Maps.|
|X-18-3||Japanese Hydrography, Article 3 -- Wartime Activities of International Latitude Observatory, Misusawa, Iwate Prefecture, Japan.|
|X-20||Japanese Fungus, Moisture-Proofing, and Antifungus Data.|
|X-21||Japanese Use of Balloons for Barrage, Bombing, and Aerology.|
|X-31||Bombproof Construction in Japan.|
|X-32||Camouflage of Japanese Ships and Naval Installations.|
|X-33||Design of Japanese Structures.|
|X-36(N)||Japanese Welding Standards.|
|X-37(N)||Japanese Methods of High Frequency Induction Heating and Melting.|
|X-38(N)-1||Japanese Fuels and Lubricants, Article 1 -- Fuel and Lubricant Technology.|
|X-38(N)-2||Japanese Fuels and Lubricants, Article 2 -- Naval research on Aviation Gasoline.|
|X-38(N)-3||Japanese Fuels and Lubricants, Article 3 -- Naval Research on Alcohol Fuel.|
|X-38(N)-4||Japanese Fuels and Lubricants, Article 4 -- Pine Root Oil Program.|
|X-38(N)-5||Japanese Fuels and Lubricants, Article 5 -- Research on Rocket Fuels of the Hydrogen Peroxide-Hydrazine Type.|
|X-38(N)-6||Japanese Fuels and Lubricants, Article 6 -- Research on Diesel and Boiler Fuel at the First Naval Fuel Depot, Ofuna.|
|X-38(N)-7||Japanese Fuels and Lubricants, Article 7 -- Progress in the Synthesis of Liquid Fuels from Coal.|
|X-38(N)-8||Japanese Fuels and Lubricants, Article 8 -- Naval Research on Lubricants.|
|X-38(N)-9||Japanese Fuels and Lubricants, Article 9 -- Fundamental Hydrocarbon Research.|
|X-38(N)-10||Japanese Fuels and Lubricants, Article 10 -- Miscellaneous Oil Technology and Refining Installations.|
|X-39(N)||Miscellaneous Reports of Various Japanese Naval Research Activities.|
|X-40(N)||Oceanography in Japan.|
Adapted from: US Naval Technical Mission to Japan. Summary Report. (San Francisco, CA: US Naval Technical Mission to Japan, 1946): 1-13.