1951 in spaceflight

The US Army, US Air Force, and the Applied Physics Laboratory continued their use of Aerobee on a variety of physics, aeronomy, photography, weather, and biomedical sounding rocket flights; a total of 11 were launched during the year.[2] Two of these comprised the earliest space biomedical missions. Launched by the Air Force, and carrying mice and monkeys, they (along with a third flight in 1952) determined that brief (approx. 15 minutes) exposure to acceleration, reduced gravity, and high altitude cosmic radiation did not have significant negative effects.[3]

The first generation of US Navy-built Viking sounding rockets reached its acme of performance with the flight of Viking 7, the sole Viking launch of 1951. Launched 7 August from White Sands Missile Range in New Mexico, the rocket set a new world altitude record of 136 miles (219 km).[4]^{: 167–171, 236}

The R-1, the Soviet Union's first domestically built long-range ballistic missile, was accepted into service in November 1950. In January 1951, cold-weather testing of the R-1 for quality assurance purposes was conducted.[5]^{: 149, 152} On 1 June, production of the R-1 was centralized and transferred to a former automobile factory in Dnepropetrovsk, and that month,[6] a test series of R-1s was successfully launched to the edge of space, all landing within 5.5 kilometers (3.4 mi) of their targets. Though the R-1, a virtual copy of the now-obsolete V-2,[5]^: 119 was not a particularly formidable weapon and posed virtually no threat to the West, it was invaluable in training engineers and missile crews, as well as creating a nascent rocket industry in the Soviet Union.[5]^: 152–3

On 29 January 1951, dogs were carried on one of the winter test flights of the R-1.[2] This was followed in the summer by six R-1s specifically designed and equipped for biomedical flights to determine if their payload dogs could survive the rigors of space travel and be recovered. Three of the missions were successful.[7]

The R-2 missile, the first operational Soviet design to have a separable nose cone, underwent a second test series of thirteen flights in July 1951, experiencing one failure. Accepted for operational service on 27 November 1951,[8] the design had a range of 600 kilometers (370 mi), twice that of the R-1, while maintaining a similar payload of around 1,000 kilograms (2,200 lb).[5]^: 48–9

By 1950, the war-head carrying ballistic missile, which in the United States had been eclipsed since World War II by guided missile development, received national priority. In January 1951, the US Air Force's Air Research and Development Command awarded to Consolidated Vultee the contract for Atlas, the nation's first Intercontinental ballistic missile.[9]^: 59–61 The Atlas went on to become one of the key boosters in America's crewed and robotic space programs,[10]^: 32–39 first orbiting a payload (SCORE) in 1958.[9]^{: 153, 161–2}

On 15 April 1950, Wernher von Braun and his team of German rocket engineers were transferred from Fort Bliss to Redstone Arsenal in Alabama. In 1951, the Redstone team was tasked with the research and development of guided missiles and the development and testing of free rockets, solid propellants, Jet-Assisted Take-off rockets, and related items, thus making the Army a leading player in America's missile development.[11] Their work led to the production of the Redstone missile, first launched in 1953,[12] versions of which ultimately launched Explorer 1, America's first artificial satellite, in 1958, and Mercury-Redstone 3, America's first human space mission, in 1961.[13]

In the summer of 1950, the United States Naval Research Laboratory (NRL) team led by Milton Rosen began work on an improved Viking rocket able to reach higher altitudes. The team would achieve increased performance through larger fuel tanks and reduced weight elsewhere on the rocket. Originally planned for launch in 1951, the development of the second generation Viking took two years, and the first of the new rockets would not launch until 6 June 1952.[4]^{: 172–3, 236}

In January 1951, Dr. James Van Allen, instrumental in the development of the Aerobee rocket, joined the physics department at the State University of Iowa (SUI). Along with University of Chicago graduate Melvin B. Gottlieb and Van Allen's first SUI graduate student, Leslie H. Meredith, they began a high altitude cosmic ray research program using equipment mounted on balloons. Launched from 16 June 1951, though 26 January 1952,[14]^: 7–10 this experience set the foundation for balloon-launched sounding rockets, which would first breach the boundary of space in 1954.[14]^: 38

From 1947, the German émigré-designed G-1 (or R-10) missile had competed with the Soviet-designed R-2 for limited engineering and production staff, the latter winning out by the end of 1949. With the project stalled for lack of resources and government interest, the Soviets terminated all work by the German specialists in October 1950. In December 1951, the first of the specialists were repatriated to East Germany (a process that the Soviets completed in November 1953).[5]^: 69–70

The draft plan for the ambitious 3,000-kilometer (1,900 mi) range R-3 had been approved on 7 December 1949,[5]^: 67 but was canceled on 20 October 1951, other designs proving more useful and achievable.[5]^: 275–6 One of them was the R-5 missile, able to carry the same payload as the R-1 and R-2 but over a distance of 1,200 kilometers (750 mi)[5]^: 242 (the other being the R-11, a tactical missile half the size of the R-1 but with the same payload).[15] The R-5's conceptual design was completed by 30 October 1951.[16]^: 97