First Lieutenant Harold Ross Harris, Air Service, United States Army, 1922.
17 April 1923: At Wilbur Wright Field, Dayton, Ohio, First Lieutenant Harold Ross Harris set two Fédération Aéronautique Internationale (FAI) World Speed Records, flying a modified de Havilland XDH-4L powered by a Hall-Scott Liberty 375 engine. Lieutenant Harris averaged 184.03 kilometers per hour (114.35 miles per hour) over a 1,500 kilometer (932.1 miles) closed circuit,¹ and 183.82 kilometers per hour (114.22 miles per hour) over a 2,000 kilometer (1,242.7 mile) course. ²
Harold R. Harris was an important figure in the development of aircraft following World War I. He served as Engineering Officer for the U.S. Army at McCook Field and flew many experimental aircraft, setting records for speed and altitude, and worked on the development of airplanes, engines and other equipment. Harris was the first man to use a parachute to escape an airplane during an actual in-flight emergency.
In civil aviation, Harris was an executive with the company that would become Pan American World Airways. During World War II, he was chief of staff of the Air Transport Command, retiring with the rank of brigadier general, and then returning to commercial aviation as a vice president of Pan Am and later president of Northwest Airlines.
de Havilland XDH-4L A.S. 64593, FAI World Speed record holder. (FAI)
The XDH-4L was a variant of the Airco DH.4, designed by Geoffrey de Havilland. It was a two-place, single-engine biplane intended as a bomber, but the type served in virtually every capacity during World War I and the years following. At McCook Field, American-built DH-4s were commonly used as test beds for engines and other aeronautical equipment.
The standard Airco DH.4 had a crew of two. It was 30 feet, 8 inches (9.347 meters) long with a wingspan of 43 feet, 4 inches (13.208 meters) and height of 11 feet (3.353 meters). Empty weight was 2,387 pounds (1,085 kilograms) and loaded weight was 3,472 pounds (1,578 kilograms). British-built DH.4s were powered by a 1,240.54-cubic-inch-displacement (20.33 liter) liquid-cooled Rolls-Royce Eagle overhead cam 60° V-12 engine which produced 375 horsepower. A gear-reduction system kept propeller r.p.m. below engine speed for greater efficiency.
American-built DH.4 airplanes were produced by the Boeing Airplane Company, Dayton-Wright Airplane Company, Fisher Body Corporation, and Standard Aircraft Corporation. Most were powered by the Liberty L12 engine.
Major Henry H. Arnold standing beside the first Liberty 12 aircraft engine turned out for war use. “Hap” Arnold would later hold the 5-star rank of General of the Army and General of the Air Force. (U.S. Air Force)
The Liberty L12 aircraft engine was designed by Jesse G. Vincent of the Packard Motor Car Company and Elbert J. Hall of the Hall-Scott Motor Company. It was a water-cooled, normally-aspirated, 1,649.336-cubic-inch-displacement (27.028 liter) Liberty L-12 single overhead cam (SOHC) 45° V-12 engine with a compression ratio of 5.4:1. The Liberty produced 408 horsepower at 1,800 r.p.m. The L-12 as a right-hand tractor, direct-drive engine and it turned turned a two-bladed fixed-pitch wooden propeller. The Liberty 12 was 5 feet, 7.375 inches (1.711 meters) long, 2 feet, 3.0 inches (0.686 meters) wide, and 3 feet, 5.5 inches (1.054 meters) high. It weighed 844 pounds (383 kilograms). This engine was produced by Ford Motor Company, as well as the Buick and Cadillac Divisions of General Motors, The Lincoln Motor Company (which was formed by Henry Leland, the former manager of Cadillac, specifically to manufacture these aircraft engines), Marmon Motor Car Company and Packard. Hall-Scott was too small to produce engines in the numbers required.
Following World War I, many DH-4s were rebuilt by Boeing and Atlantic Aircraft. An improved version, the DH-4M, used a tubular steel framework instead of the usual wood construction. DH-4s remained in service with the United States Army as late as 1932.
De Havilland XDH-4L, U.S. Army Air Service serial number A.S. 64593, was used for engineering tests at McCook Field. It carried project number P193 painted on its rudder. At the time of the world speed records, it was powered by a Hall-Scott Liberty 375, a 375 horsepower version of the Liberty V-12 engine. The rear cockpit was faired over and a 185 gallon (700.3 liter) fuel tank installed for long range flights.
Lieutenants Oakland G. Kelly and John A. Macready with the fuel drums for their duration flight in front of the Fokker T-2, A.S. 64233. (U.S. Air Force)
16–17 April 1923: At Wilbur Wright Field, Dayton, Ohio, U.S. Army Air Service pilots Lieutenant Oakland George Kelly and Lieutenant John Arthur Macready set six Fédération Aéronautique Internationale (FAI) World Records for speed, distance and duration, flying the Nederlandse Vliegtuigenfabriek Fokker T-2, serial number A.S. 64233, which they planned to fly non-stop across the United States of America.
They flew 2,500 kilometers (1,553.428 miles) at an average speed of 115.60 kilometers per hour (51.83 miles per hour);¹ 3,000 kilometers (1,864.114 miles) at 115.27 kilometers per hour (71.63 miles per hour);² 3,500 kilometers (2,174.799 miles) at 114.82 kilometers per hour (71.35 miles per hour);³ 4,000 kilometers (2,485.485 miles) at 113.93 kilometers per hour (70.79 miles per hour);⁴ flew a total distance of 4,050 kilometers (2,517 miles);⁵ and stayed aloft for 36 hours, 4 minutes, 34 seconds.⁶ Their overall average speed was 112.26 kilometers per hour (69.76 miles per hour).
Lieutenant Oakley George Kelly, U.S. Army Air Service. (FAI)Lieutenant John A. Macready, U.S. Army Air Service
The Fokker F.IV was built by Anthony Fokker’s Nederlandse Vliegtuigenfabriek at Veere, Netherlands in 1921. The Air Service purchased two and designated the type T-2, with serial numbers A.S. 64233 and A.S. 64234.
Several modifications were made to prepare for the transcontinental flight. Normally flown by a single pilot in an open cockpit, a second set of controls was installed so that the airplane could be controlled from inside while the two pilots changed positions. On this flight, it carried 735 gallons (2,782 liters) of gasoline in three fuel tanks.
For its time, the Fokker was a large airplane: 49 feet (14.9 meters) long, with a wing span of 82 feet (25 meters). The high-wing monoplane was powered by a 1,649.3-cubic-inch-displacement (27.028 liter) liquid-cooled Liberty L12 single overhead cam (SOHC) 45° V-12 engine producing 420 horsepower. The airplane was designed to carry 8–10 passengers in an enclosed cabin.
The second Fokker T-2, A.S. 64234, also designated A-2 (ambulance). (U.S. Air Force)
From 2–3 May 1923, MacReady and Kelly succeeded in their non-stop transcontinental flight, flying from Roosevelt-Hazelhurst Field, Long Island, New York, to Rockwell Field (now, NAS North Island), San Diego, California, 2,470 miles (3,975 kilometers) in 26 hours, 50 minutes, 38.8 seconds, for an average speed of 92 miles per hour (148 kilometers per hour).
The U.S. Army Air Service transferred A.S. 64223 to the Smithsonian Institution in January 1924. It is on display at the National Air and Space Museum.
17 April 1913: Pioneer British aviator Gustav Wilhelm Hamel flew from Dover, England, across the English Channel and on to Cologne, Germany. Also on board his airplane was Frank Dupree,¹ a reporter for the London Standard. His airplane was a Blériot XI. ² The duration of the flight was 4 hours, 18 minutes.
FLIGHT reported:
HAMEL FLIES FROM DOVER TO COLOGNE.
AMONG the many extraordinary flights which have been accomplished, certainly not the least epoch-making, inasmuch as it was the first flight from England to Germany, was that made by Mr. Gustav Hamel last week, with a passenger, from Dover to Cologne. Starting from Dover Aerodrome (accompanied by Mr. F. Dupree, of the staff of the Standard, by whom arrangements for the flight had been made), he left Dover as 12.40 p.m. Making his way across the Channel, the French coast was picked up just south of Dunkirk, and then a course was set by the aid of the compass for Mechlin. Across Belgium and Holland the military Blériot sped its way, but the storms which had to be passed through put the pilot out a little in his reckoning, and when the Rhine was sighted it was at a point about 60 miles north of Cologne. This deviation lengthened the journey considerably, but Cologne was safely reached at 4.58 p.m., and on alighting the English travellers were courteously received by the German officers. The duration of the flight was 4 hrs. 18 mins., and the distance as the crow flies from point to point is 245 miles. In view of the deviation, Mr. Hamel estimates the distance covered at 320 miles. Altogether, Mr. Hamel passed over five countries.
The Blériot monoplane which was used was fitted with an 80 h.p. Gnome motor, which, by the way, was equipped with the famous F. and S. ball-bearings. ³ The fuel used was Shell spirit, of which forty gallons were carried, and there was sufficient left at the journey’s end to cover another 100 miles, a distance which would have taken the aviator well out of the German Empire. For lubrication purposes Wakefield “Castrol” was used.
The Machine for New Zealand.
Hamel’s great flight from Dover to Cologne was arranged by the Standard in conjunction with the Imperial Air Fleet Committee, of which Lord Desborough is President, and on conclusion of the flight the aeroplane was offered to and accepted by the New Zealand Government. A fund has now been opened with the object of paying for the machine, the cost of which has been in the meantime guaranteed by the Standard and Messrs. Wm. Coward and Co., Ltd.
—FLIGHT, No. 226 (No. 17, Vol. V.), 26 April 1913, at Page 466
A short film of preparations for the flight is available from British PATHÉ at:
Gustav Hamel was born in Germany, but he and his family emigrated to England in 1910, becoming subjects of the Crown. In 1911 he attended the Blériot flying school at Pau, France, and earned Aéro-Club de France‘s aviator certificate number 358, and the Royal Aero Club (R.Ae.C.) certificate number 64. He completed many “firsts” in aviation, including delivering the first official air mail. Hamel disappeared on another flight across the English Channel, 23 May 1914.
The Blériot XI was a single-seat, single-engine monoplane, designed by Raymond Saulnier and built by Louis Charles Joseph Blériot. It was 24 feet, 11 inches (7.595 meters) long with a wingspan of 27 feet, 11 inches (8.509 meters) and overall height of 8 feet, 10 inches (2.692 meters). The wings had a chord of 6 feet (1.829 meters). The airplane had an empty weight of 507 pounds (229.9 kilograms).
In its original configuration, the airplane was powered by an air-cooled, 3.774 liter (230.273 cubic inches) R.E.P. two-row, seven-cylinder fan engine (or “semi-radial”) which produced 30 horsepower at 1,500 r.p.m., driving a four-bladed paddle-type propeller. The R.E.P. engine weighed 54 kilograms (119 pounds). This engine was unreliable and was soon replaced by an air-cooled 3.534 liter (215.676 cubic inch) Alessandro Anzani & Co., 60° (some sources state 55°) three-cylinder “fan”-type radial engine (or W-3) and a highly-efficient Hélice Intégrale Chauvière two-bladed fixed-pitch propeller, which had a diameter of 6 feet, 8 inches (2.032 meters). The Anzani W-3 was a direct-drive, right-hand tractor engine which produced 25 horsepower at 1,400 r.p.m. It was 1.130 meters (3 feet 8.49 inches) long, 1.500 meters (4 feet, 11.01 inches) high, and 0.720 meters (2 feet, 4.35 inches) wide. The engine weighed 66 kilograms (145.5 pounds).
Blériot Type XI, front view.Blériot Type XI, side view.Blériot Type XI, top view.
The Anzani-powered Blériot XI had a maximum speed of 76 kilometers per hour (47 miles per hour) and its service ceiling was 1,000 meters (3,281 feet).
Gustav Hamel and his Blériot XI at Radnorshire, Knighton, England, 29th August 1913.
¹ Also reported in contemporary newspaper articles as “Frank Dupre,” and frequently described as “an American.”
² Although not specifically identified in contemporary newspaper articles, the airplane flown by Hamel on this date was a Blériot XI-2 Génie, a two-place variant which was powered by a Gnome Lambda 7-cylinder rotary engine. The weights, dimensions and performance very likely varied from those described above. It was accepted by New Zealand on 4 March 1913, and was shipped aboard the White Star Line passenger ship, S.S. Athenic. It arrived at Auckland on 29 September 1913. The airplane was named Britannia.
According the Air Force Museum of New Zealand:
The first flight was not undertaken until January 1914, when Joe Hammond, a New Zealander and Second Lieutenant in the Royal Flying Corps, was engaged to demonstrate the machine. After several test flights from the Epsom Showgrounds, he was ready to take up his first passenger. Rather than select one of the many dignitaries present, he took aloft an actress, Miss Esme McLennan of the Royal Pantomime Company. Hammond was released from duty for his lapse in protocol, and the aircraft put into storage in New Zealand. The New Zealand Government offered it for service in World War One, and it returned to the UK in October 1914.
The New Zealand Monoplane Britannia over the Auckland Exhibition Grounds, January 1914. (Air Force Museum of New Zealand)
Apollo 16 (AS-511) lifts off from Launch Complex 39A, Kennedy Space Center, Cape Canaveral, Florida, at 17:54:00 UTC, 16 April 1972. (NASA)
16 April 1972: At 17:54:00 UTC (12:54 p.m., Eastern Standard Time), Apollo 16 was launched from Launch Complex 39A at the Kennedy Space Center, Cape Canaveral, Florida. Aboard were Captain John Watts Young, United States Navy, the Mission Commander, on his fourth space flight; Lieutenant Commander Thomas Kenneth Mattingly II, U.S. Navy, Command Module Pilot, who had been scheduled for the Apollo 13 mission; and Lieutenant Colonel Charles Moss Duke, Jr., U.S. Air Force, Lunar Module Pilot. Apollo 16 was the tenth manned Apollo mission, and the fifth to land on The Moon. The landing site was in the Descartes Highlands.
Flight Crew of Apollo 16, left to right, Thomas K. Mattingly II, John W. Young, and Charles M. Duke, Jr. (NASA)
John Young had been a Navy test pilot before being assigned to NASA as an astronaut. He was the pilot for Gemini 3; backup pilot, Gemini 6A; commander, Gemini 10; command module pilot for Apollo 10; backup commander, Apollo 13; and commander, Apollo 16. He retired from the U.S. Navy in 1976 after 25 years of service. He would go on to command the first space shuttle flight, Columbia (STS-1) and then STS-9. He was scheduled to command Atlantis (STS-61-J). John Young retired from NASA in 2004, as one of the world’s most experienced astronauts.
John Watts Young (NASA)
The Saturn V lifted off at T + 000:00:00.59 and quickly accelerated, reaching Mach 1 one minute, 7.5 seconds after launch (T + 01:07.5). The S-IC first stage engines cut off and the stage separated at T + 02:43.5. The S-II stage continued to drive the space craft, and Apollo 16 entered Earth orbit at 18:05:56.21 UTC.
Apollo 16/Saturn V AS-511 at Pad 39A. (NASA AP16-KSC-71PC-771)
The Saturn V rocket was a three-stage, liquid-fueled heavy launch vehicle. Fully assembled with the Apollo Command and Service Module, it stood 363 feet (110.642 meters) tall. The first and second stages were 33 feet (10.058 meters) in diameter. Fully loaded and fueled the rocket weighed 6,200,000 pounds (2,812,273 kilograms).¹ It could lift a payload of 260,000 pounds (117,934 kilograms) to Low Earth Orbit.
A Saturn V S-IC first stage being lifted inside the vertical Assembly Building. (NASA 68-HC-70)
The first stage was designated Saturn S-IC. It was designed to lift the entire rocket to an altitude of 220,000 feet (67,056 meters) and accelerate to a speed of more than 5,100 miles per hour (8,280 kilometers per hour). The S-IC stage was built by Boeing at the Michoud Assembly Facility, New Orleans, Louisiana. It was 138 feet (42.062 meters) tall and had an empty weight of 290,000 pounds (131,542 kilograms). Fully fueled with 203,400 gallons (770,000 liters) of RP-1 and 318,065 gallons (1,204,000 liters) of liquid oxygen, the stage weighed 5,100,000 pounds (2,131,322 kilograms). It was propelled by five Rocketdyne F-1 engines, producing 1,522,000 pounds of thrust, each, for a total of 7,610,000 pounds of thrust at Sea Level. These engines were ignited seven seconds prior to lift off and the outer four burned for 168 seconds. The center engine was shut down after 142 seconds to reduce the rate of acceleration. The F-1 engines were built by the Rocketdyne Division of North American Aviation at Canoga Park, California.
A Saturn V S-II second stage being positioned above the S-IC first stage. (NASA MSFC-67-58331)
The Saturn S-II second stage was built by North American Aviation at Seal Beach, California. It was 81 feet, 7 inches (24.87 meters) tall and had the same diameter as the first stage. The second stage weighed 80,000 pounds (36,000 kilograms) empty and 1,060,000 pounds loaded. The propellant for the S-II was liquid hydrogen and liquid oxygen. The stage was powered by five Rocketdyne J-2 engines, also built at Canoga Park. Each engine produced 232,250 pounds of thrust, and combined, 1,161,250 pounds of thrust.
A Saturn V S-IVB third stage with its Rocketdyne J-2 engine. (NASA)
The Saturn V third stage was designated Saturn S-IVB. It was built by McDonnell Douglas Astronautics Company at Huntington Beach, California. The S-IVB was 58 feet, 7 inches (17.86 meters) tall with a diameter of 21 feet, 8 inches (6.604 meters). It had a dry weight of 23,000 pounds (10,000 kilograms) and fully fueled weighed 262,000 pounds. The third stage had one J-2 engine and also used liquid hydrogen and liquid oxygen for propellant. The S-IVB wou place the Command and Service Module into Low Earth Orbit, then, when all was ready, the J-2 would be restarted for the Trans Lunar Injection.
Eighteen Saturn V rockets were built. They were the most powerful machines ever built by man.
Apollo 16 AS-511 clears the tower at Launch Complex 39A, Kennedy Space Center, Cape Canaveral, Florida, 17:54:00 UTC, 16 April 1972. (NASA)Apollo 16 accelerates toward Earth orbit, 16 April 1972.(LIFE Magazine)
¹ At First Motion (T + 000.00.00.3) the Vehicle Weight of Apollo 16/Saturn V AS-511 was calculated at 6,439,605 pounds (2,920,956 kilograms).
Lieutenant Commander George Clinton Watkins, United States Navy, set a World Altitude Record with a Grumman F11F-1F Super Tiger, 18 April 1958. (U.S. Navy)
16 April 1958: At Edwards Air Force Base, California, test pilot Lieutenant Commander George Clinton Watkins, United States Navy, set a Fédération Aéronautique Internationale (FAI) World Altitude Record of 23,449 meters (76,932 feet) ¹ with a Grumman F11F-1F Tiger, Bureau of Aeronautics serial number (Bu. No.) 138647.
Lieutenant Commander Watkins wore a David Clark Co. C-1 capstan-type partial-pressure suit with an International Latex Corporation (ILC Dover) K-1 helmet and face plate for protection at high altitudes.
The Valley Times reported:
Edwards Flier Sets Altitude Mark For Jets
By WALT KEESHAN JR. Valley Times Aviation Editor
EL CENTRO — The world’s altitude record for jet planes has been taken to the Antelope Valley by a Navy pilot dressed in a Mars-like suit who flew to the edge of space at 76,828.8 feet above Mojave.
This historic event, announced yesterday at the third annual Naval Air Weapons meet, staged in the Imperial Valley, brought the Distinguished Flying Cross to LCDR George C. Watkins, 37, who gave America the first altitude record it has held in 28 years. The flight was Wednesday.
Flying a F-11-1F Super Tiger, Watkins, of Pasadena, proved that jet airplanes can operate for a brief period of time 14 miles above earth—a period long enough to launch missiles into space.
45-Minute Flight
The actual flight which took Watkins up into the Ozonosphere lasted 45 minutes and covered a distance of 500 miles stretching from Needles to Mojave. He stayed at the record altitude for four seconds.
Watkins flew in a patch like a ballistic missile strapped in his swept-wing fighter, Outside the snug cockpit the temperature was 69 degrees below zero.
The swept-wing fighter shot from the Edwards Air Force Base runway loaded with 6,270 pounds of fuel and raced for Needles, 210 miles to the east.
Making a U-turn 30 miles beyond Needles, Watkins poured on teh speed and dashed toward Edwards with his throttle wide open at 1,260 miles per hour (Mach 1.9) at 40,000 feet.
Cruise Climb
Watkins slowly began to cruise climb, rising 1,500 feet a minute until he had only 400 pounds of fuel left. Rising skyward the afterburner cut off at 65,000 feet and he was on his way.
The altimeter began to spin crazily and all the energy he had built up pushed him up at a rate of 50,000 feet a minute in what pilots call a zoom-glide.
As he eased over the top at 76,828.8 feet, the Super Tiger was only going 100 miles an hour and Watkins was experiencing zero-gravity for more than a minute—an uncomfortable 60 seconds when he became weightless and objects began floating in the cockpit.
Outside the sky was very deep blue. He was the first jet pilot to see this new color. “I hardly had time to look,” Watkins said.
Lands Without Fuel
During the record run he had to hit a five mile square area in the sky so that radar cameras on the ground could officially record his record. He landed without enough fuel to taxi back to the hangar.
The record run was part of “Operation Apollo” now being staged at Edwards. He will try for 84,000 feet probably the first part of next week when the temperature gets down to a minus 79 degrees outside. The colder it is the faster he can go.
The Air Force and the Navy are both interested in this altitude mark because solid missiles could be launched from these sky platforms and fired at tremendously increased distances—maybe put in orbit.
The record Watkins broke was 70,308 feet set by the British last year in a combination jet and rocket powered airplane.
—Valley Times, Vol. 21, No. 93, Friday 18 April 1958, Page 1, Column 3, and Page 2, Column 3
Watkins’ flight was observed by the National Aeronautic Association and certified by the Fédération Aéronautique Internationale (FAI). For his record-setting flight, Lieutenant Commander Watkins was presented the Distinguished Flying Cross by Vice Admiral William F. Davis, Jr., Deputy Chief of Operations for Air.
Grumman F11F-1F Tiger, Bu. No. 138647, in flight near Edwards AFB, California. (U.S. Navy)
The F11F-1F Tiger was a higher performance variant of the U.S. Navy F11F single-seat, single-engine swept wing aircraft carrier-based supersonic fighter. The last two regular production F11F-1 Tigers, Bu. Nos. 138646 and 138647 were completed as F11F-2s, with the standard Westinghouse J65-WE-18 turbojet engine replaced by a more powerful General Electric YJ79-GE-3, which produced 9,300 pounds of thrust (41.37 kilonewtons), or 14,350 pounds (63.83 kilonewtons) with afterburner. The air intakes on each side of the fuselage were longer and had a larger area to provide greater airflow for the new engine. After testing, the fuselage was lengthened 1 foot, 1½ inches (0.343 meters) and an upgraded J79 engine installed. The first “Super Tiger” was damaged beyond repair in a takeoff accident and was “expended” as a training aid for fire fighters.
The U.S. Navy determined that the F11F-2 was too heavy for operation aboard carriers and did not place any orders. The designation was changed from F11F-2 to F11F-1F, and later, to F-11B, although the remaining aircraft was no longer flying by that time.
The F11F-1F Tiger is 48 feet, 0.5 inches (14.643 meters) long with a wingspan of 31 feet, 7.5 inches (9.639 meters) and overall height of 13 feet, 10 inches (4.216 meters). The Super Tiger has an empty weight of 16,457 pounds (7,465 kilograms) and maximum takeoff weight of 26,086 pounds (11,832 kilograms).
The General Electric J79 is a single-spool axial-flow afterburning turbojet, which used a 17-stage compressor and 3-stage turbine. The engine is 17 feet, 3.5 inches (5.271 meters) long, 3 feet, 2.3 inches (0.973 meters) in diameter, and weighs 3,325 pounds (1,508 kilograms).
With the YJ79 engine, the F11F-1F has a maximum speed of 836 miles per hour (1,345 kilometers per hour) at Sea Level, 1,325 miles per hour (2,132 kilometers per hour) at 35,000 feet (10,668 meters) and 1,400 miles per hour (2,253 kilometers per hour) at 40,000 feet (12,192 meters). Cruise speed is 580 miles per hour (933 kilometers per hour). It had an initial rate of climb of 8,950 feet per minute (45.5 meters per second) and service ceiling of 50,300 feet (15,331 meters). Range with internal fuel was 1,136 miles (1,828 kilometers).
The Tiger’s armament consisted of four 20 mm Colt Mk 12 autocannon with 125 rounds of ammunition per gun, and four AIM-9 Sidewinder heat-seeking missiles.
The single remaining F11F-1F, Bu. No. 138647, is on static display at the Naval Air Weapons center, China Lake, California.
George Clinton Watkins was born at Alhambra, California, 10 March 1921, the third of seven children of Edward Francis Watkins, a purchasing agent for the Edison Company, and Louise Whipple Ward Watkins. (Mrs. Watkins was a candidate for election to the United States Senate in 1938.) George’s brother, James, would later serve as Chief of Naval Operations.
George was educated at the Army and Navy Academy, Carlsbad, California, and at The Citadel, the Military College of South Carolina, before being appointed to the United States Naval Academy, Annapolis, Maryland. He entered the Academy 3 July 1940. He graduated and was commissioned as an Ensign, United States Navy, 9 June 1943. He was then assigned as a gunnery officer aboard the battleship, USS Pennsylvania (BB-38). Ensign Watkins was promoted to the rank of lieutenant (junior grade), 1 September 1944.
Near the end of the war, Lieutenant (j.g.) Watkins entered pilot training. He graduated and was awarded the gold wings of a Naval Aviator in 1945. He was promoted to the rank of lieutenant, 1 April 1946. His first operational assignment was as pilot of a Grumman TBF Avenger torpedo bomber with VT-41. In 1950 Watkins attended the Navy’s test pilot school at NAS Patuxent River on the Chesapeake Bay, Maryland. Among his classmates were future astronauts John H. Glenn and Alan B. Shepard. Lieutenant Watkins served as a fighter pilot during the Korean War, flying the Grumman F9F-6 with VF-24, aboard USS Yorktown (CVA-10)then returned to duty as a test pilot. On 1 January 1954, he was promoted to lieutenant commander.
George Watkins was the first U.S. Navy pilot to fly higher than 60,000 feet (18,288 meters), and 70,000 feet (21,336 meters). In 1956, he set a speed record of 1,210 miles per hour (1,947.3 kilometers per hour). Lieutenant Commander Watkins was promoted to the rank of commander, 1 March 1958. He was assigned as Commander Air Group 13 in August 1961. On 9 May 1962, Commander Watkins became the first U.S. Navy pilot to have made 1,000 aircraft carrier landings.
Commander Watkins was promoted to the rank of captain, 1 July 1964. Captain Watkins served in planning assignments at the Pentagon, and was an aide to Presidents Kennedy, Johnson and Nixon.
USS Mars (AFS-1). (United States Navy)Captain George Clinton Watkins, United States Navy (1921–2005)
From 14 December 1965 to 12 December 1966, Captain Watkins commanded USS Mars (AFS-1), a combat stores ship. (Experience commanding a deep draft ship was a requirement before serving as captain of an aircraft carrier).
He later served as a technical adviser for the 1970 20th Century Fox/Toei Company movie, “Tora! Tora! Tora!,” about the Japanese attack against Pearl Harbor which brought the United States of America into World War II.
By the time Captain Watkins retired from the Navy in 1973, he had flown more than 200 aircraft types, made 1,418 landings on 37 aircraft carriers, and logged more than 16,000 flight hours. He continued flying after he retired, operating sailplane schools at Santa Monica and Lompoc, California. He had flown more than 21,000 hours during 26,000 flights.
Captain Watkins married Miss Monica Agnes Dobbyn, 20 years his junior, at Virginia Beach, Virginia, 9 June 1979. Mrs. Watkins is the author of Cats Have Angels Too, Angelaura & Company, 1998.
Captain Watkins died 18 September 2005 at the age of 84 years. His ashes were spread at sea from the deck of a United States Navy aircraft carrier.
