A replica of Sputnik 1, the world's first artificial satellite, launched in 1957

Neil Armstrong, one of the first two men to land on the Moon, and the first to walk on it, in 1969

A chart of selected space milestones as accomplished by the USSR and the USA in the space race.

The Space Race was a mid-to-late 20th century competition between the Soviet Union (USSR) and the United States (US) for supremacy in space exploration. Between 1957 and 1975, the Cold War rivalry between the two nations focused on attaining firsts in space exploration, which were seen as necessary for national security and symbolic of technological and ideological superiority. The Space Race involved pioneering efforts to launch artificial satellites, sub-orbital and orbital human spaceflight around the Earth, and piloted voyages to the Moon. It effectively began with the Soviet launch of the Sputnik 1 artificial satellite on 4 October 1957, and concluded with the co-operative Apollo-Soyuz Test Project human spaceflight mission in July 1975. The Apollo-Soyuz Test Project came to symbolize détente, a partial easing of strained relations between the USSR and the US.

The Space Race had its origins in the missile-based arms race that occurred just after the end of the World War II, when both the Soviet Union and the United States captured advanced German rocket technology and personnel.

The Space Race sparked unprecedented increases in spending on education and pure research, which accelerated scientific advancements and led to beneficial spin-off technologies. An unforeseen effect was that the Space Race contributed to the birth of the environmental movement; the first color pictures of Earth taken from deep space were used as icons by the movement to show the planet as a fragile "blue marble" surrounded by the blackness of space.

Some famous probes and missions include Sputnik 1, Explorer 1, Vostok 1, Mariner 2, Ranger 7, Luna 9, Alouette 1, Apollo 8, and Apollo 11.

Origins[link]

World War II[link]

The Space Race can trace its origins to Nazi Germany, beginning in the 1930s and continuing during World War II when Germany researched and built operational ballistic missiles. Starting in the early 1930s, German aerospace engineers experimented with liquid-fueled rockets, with the goal that one day they would be capable of reaching high altitudes and traversing long distances.^[1] The head of the German Army's Ballistics and Munitions Branch, Lieutenant Colonel Karl Emil Becker, gathered a small team of engineers that included Walter Dornberger and Leo Zanssen, to figure out how to use rockets as long-range artillery in order to get around the Treaty of Versailles' ban on research and development of long-range cannons.^[2] Wernher von Braun, a young engineering prodigy, was recruited by Becker and Dornberger to join their secret army program at Kummersdorf-West in 1932.^[3] Von Braun had romantic dreams about conquering outer space with rockets, and did not initially see the military value in missile technology.^[4]

During the Second World War, General Dornberger was the military head of the army's rocket program, Zanssen became the commandant of the Peenemünde army rocket centre, and von Braun was the technical director of the ballistic missile program.^[5] They would lead the team that built the Aggregate-4 (A-4) rocket, which became the first vehicle to reach outer space during its test flight program in 1942 and 1943.^[6] By 1943, Germany began mass producing the A-4 as the Vergeltungswaffe 2 (“Vengeance Weapon” 2, or more commonly, V2), a ballistic missile with a 320 kilometres (200 mi) range carrying a 1,130 kilograms (2,500 lb) warhead at 4,000 kilometres per hour (2,500 mph).^[7] Its supersonic speed meant there was no defense against it, and radar detection provided little warning.^[8] Germany used the weapon to bombard southern England and parts of Allied-liberated western Europe from 1944 until 1945.^[9] After the war, the V-2 became the basis of early American and Soviet rocket designs.^[10][11]

At war’s end, American, British, and Soviet scientific intelligence teams competed to capture Germany's rocket engineers along with the German rockets themselves and the designs on which they were based.^[12] Each of the Allies captured a share of the available members of the German rocket team, but the United States benefited the most with Operation Paperclip, recruiting von Braun and most of his engineering team, who later helped develop the American missile and space exploration programs. The United States also acquired a large number of complete V2 rockets.^[10]

Rocket teams assembled[link]

The German rocket center at Peenemünde was located in the eastern part of Germany, which became the Soviet zone of occupation. On Stalin's orders, the Soviet Union sent its best rocket engineers to this region to see what they could salvage for future weapons systems.^[13] The Soviet rocket engineers were led by Sergei Korolev.^[13] He had been involved in space clubs and early Soviet rocket design in the 1930s, but was arrested in 1938 during Joseph Stalin's Great Purge and imprisoned for six years in Siberia.^[14] After the war, he became the USSR's chief rocket and spacecraft engineer, essentially the Soviets' counterpart to Von Braun.^[15] His identity was kept a state secret throughout the Cold War, and he was identified publicly only as "the Chief Designer."^[15] In the West, his name was only officially revealed when he died in 1966.^[15]

After almost a year in the area around Peenemünde, Soviet officials moved most of the captured German rocket specialists to Gorodomlya Island on Lake Seliger, about 240 kilometres (150 mi) northwest of Moscow.^[16] They were not allowed to participate in Soviet missile design, but were used as problem-solving consultants to the Soviet engineers.^[17] They helped in the following areas: the creation of a Soviet version of the A-4; work on "organizational schemes"; research in improving the A-4 main engine; development of a 100-ton engine; assistance in the "layout" of plant production rooms; and preparation of rocket assembly using German components.^[16] With their help, particularly Helmut Groettrup's group, Korolev reverse-engineered the A-4 and built his own version of the rocket, the R-1, in 1948.^[18] Later, he developed his own distinct designs, though many of these designs were influenced by the Groettrup Group's G4-R10 design from 1949.^[18] The Germans were eventually repatriated in 1951–53.^[18]

In America, Von Braun and his team were sent to the United States Army's White Sands Proving Ground, located in New Mexico, in 1945.^[19] They set about assembling the captured V2s and began a program of launching them and instructing American engineers in their operation.^[20] These tests led to the first rocket to take photos from outer space, and the first two-stage rocket, the WAC Corporal-V2 combination, in 1949.^[20] The German rocket team was moved from Fort Bliss to the Army's new Redstone Arsenal, located in Huntsville, Alabama, in 1950.^[21] From here, Von Braun and his team would develop the Army's first operational medium-range ballistic missile, the Redstone rocket, that would, in slightly modified versions, launch both America's first satellite, and the first piloted Mercury space missions.^[21] It became the basis for both the Jupiter and Saturn family of rockets.^[21]

Cold War arms race[link]

The Cold War (1947–1991) developed between two former allies, the Soviet Union and the United States, soon after the end of the Second World War. It involved a continuing state of political conflict, military tension, proxy wars, and economic competition, primarily between the Soviet Union and its satellite states, and the powers of the Western world, particularly the United States.^[22] Although the primary participants' military forces never clashed directly, they expressed this conflict through military coalitions, strategic conventional force deployments, extensive aid to states deemed vulnerable, proxy wars, espionage, propaganda, a nuclear arms race, and economic and technological competitions, such as the Space Race.^[22]

In simple terms, the Cold War can be viewed as an expression of the ideological struggle between communism and democracy.^[23] The United States faced a new uncertainty beginning in September 1949, when it lost its monopoly on the atomic bomb.^[23] American intelligence agencies discovered that the Soviet Union had exploded its first atomic bomb, with the consequence that the United States potentially could face a future nuclear war that, for the first time, might devastate its cities.^[23] Given this new danger, the United States participated in an arms race with the Soviet Union that included development of the hydrogen bomb, as well as intercontinental strategic bombers and intercontinental ballistic missiles (ICBMs) capable of delivering nuclear weapons.^[23] A new fear of communism and its sympathizers swept the United States during the 1950s, which devolved into paranoid McCarthyism.^[23] With communism spreading in China, Korea, and Eastern Europe, Americans came to feel so threatened that popular and political culture condoned extensive "witch-hunts" to expose communist spies.^[23] Part of the American reaction to the Soviet atomic and hydrogen bomb tests included maintaining a large Air Force, under the control of the Strategic Air Command (SAC). SAC employed intercontinental strategic bombers, as well as medium-bombers based close to Soviet airspace (in western Europe and in Turkey) that were capable of delivering nuclear payloads.^[24]

For its part, the Soviet Union harbored fears of invasion. Having suffered at least 27 million casualties during World War II after being invaded by Nazi Germany in 1941,^[25] the Soviet Union was wary of its former ally, the United States, which until late 1949 was the sole possessor of atomic weapons. The United States had used these weapons operationally during World War II, and it could use them again against the Soviet Union, laying waste its cities and military centers.^[25] Since the Americans had a much larger air force than the Soviet Union, and the United States maintained advance air bases near Soviet territory, in 1947 Stalin ordered the development of intercontinental ballistic missiles (ICBMs) in order to counter the perceived American threat.^[17]

In 1953, Korolev was given the go-ahead to develop the R-7 Semyorka rocket, which represented a major advance from the German design. Although some of its components (notably boosters) still resembled the German G-4, the new rocket incorporated staged design, a completely new control system, and a new fuel. It was successfully tested on 21 August 1957 and became the world's first fully operational ICBM the following month.^[26] It would later be used to launch the first satellite into space, and derivatives would launch all piloted Soviet spacecraft.^[27]

The United States had multiple rocket programs divided among the different branches of the American armed services, which meant that each force developed its own ICBM program. The Air Force initiated ICBM research in 1945 with the MX-774.^[28] However, its funding was cancelled and only three partially successful launches were conducted in 1947.^[28] In 1951, the Air Force began a new ICBM program called MX-1953, and by 1955 this program was receiving top-priority funding.^[28] The MX-1593 program evolved to become the Atlas-A, with its maiden launch occurring on 11 June 1957, becoming the first successful American ICBM.^[28] Its upgraded version, the Atlas-D rocket, would later serve as an operational nuclear ICBM and be used as the orbital launch vehicle for Project Mercury and the remote-controlled Agena Target Vehicle used in Project Gemini.^[28]

With the Cold War as an engine for change in the ideological competition between the United States and the Soviet Union, a coherent space policy began to take shape in the United States during the late 1950s.^[29] Korolev would take much inspiration from the competition as well, achieving many firsts to counter the possibility that the United States might prevail.^[30]

Early Space Race: 1950s[link]

Beginnings[link]

In 1955, with both the United States and the Soviet Union building ballistic missiles that could be utilized to launch objects into space, the "starting line" was drawn for the Space Race.^[31] In separate announcements, just four days apart, both nations publicly announced that they would launch artificial Earth satellites by 1957 or 1958.^[31] On 29 July 1955, James C. Hagerty, president Dwight D. Eisenhower's press secretary, announced that the United States intended to launch "small Earth circling satellites" between 1 July 1957 and 31 December 1958 as part of their contribution to the International Geophysical Year (IGY).^[31] Four days later, at the Sixth Congress of International Astronautical Federation in Copenhagen, scientist Leonid I. Sedov spoke to international reporters at the Soviet embassy, and announced his country's intention to launch a satellite as well, in the "near future".^[31] On 30 August 1955, Korolev managed to get the Soviet Academy of Sciences to create a commission whose purpose was to beat the Americans into Earth orbit: this was the defacto start date for the Space Race.^[31]

Initially, President Eisenhower was worried that a satellite passing above a nation at over 100 kilometres (62 mi), might be construed as violating that nation's sovereign airspace.^[32] He was concerned that the Soviet Union would accuse the Americans of an illegal overflight, thereby scoring a propaganda victory at his expense.^[33] Eisenhower and his advisors believed that a nation's airspace sovereignty did not extend into outer space, acknowledged as the Kármán line, and he used the 1957–58 International Geophysical Year launches to establish this principle in international law.^[32] Eisenhower also feared that he might cause an international incident and be called a "Warmonger" if he were to use military missiles as launchers. Therefore he selected the untried Naval Research Laboratory's Vanguard rocket, which was a research-only booster.^[34] This meant that von Braun's team was not allowed to put a satellite into orbit with their Jupiter-C rocket, because of its intended use as a future military vehicle.^[34] On 20 September 1956, von Braun and his team did launch a Jupiter-C that was capable of putting a satellite into orbit, however the launch was used only as a suborbital test of nose cone reentry technology.^[34] Had von Braun's team been allowed to orbit a satellite in 1956, the Space Race might have been over before it gained sufficient momentum to yield real benefits.^{[citation needed]}

First artificial satellites[link]

The signals of Sputnik 1 continued for 22 days.

Korolev received word about von Braun's 1956 Jupiter-C test, but thinking it was a satellite mission that failed, he expedited plans to get his own satellite in orbit. Since his R-7 was substantially more powerful than any of the American boosters, he made sure to take full advantage of this capability by designing Object D as his primary satellite.^[35] It was given the designation 'D', to distinguish it from other R-7 payload designations 'A', 'B', 'G', and 'V' which were nuclear weapon payloads.^[36] Object D would dwarf the proposed American satellites, by having a weight of 1,400 kilograms (3,100 lb), of which 300 kilograms (660 lb) would be composed of scientific instruments that would photograph the Earth, take readings on radiation levels, and check on the planet's magnetic field.^[36] However, things were not going along well with the design and manufacturing of the satellite, so in February 1957, Korolev sought and received permission from the USSR Council of Ministers to create a prosteishy sputnik (PS-1), or simple satellite.^[35] The Council also decreed that Object D be postponed until April 1958.^[37] The new sputnik was a shiny spherical ball that would be a much lighter craft, weighing 83.8 kilograms (185 lb) and having a 58-centimetre (23 in) diameter. ^[38] The satellite would not contain the complex instrumentation that Object D had, but it did have two radio transmitters operating on different short wave radio frequencies, the ability to detect if a meteoroid were to penetrate its pressure hull, and the ability to detect the density of the Earth's thermosphere.^[39]

Korolev was buoyed by the first successful launches of his R-7 rocket in August and September, paving the way for him to launch his sputnik.^[40] Word came that the Americans were planning to announce a major breakthrough at an International Geophysical Year conference at the National Academy of Sciences in Washington D.C., with a paper entitled "Satellite Over the Planet", on 6 October 1957.^[41] Korolev's fear was that von Braun might launch a Jupiter-C with a satellite payload, on, or around, the fourth or fifth of October, in conjunction with the paper.^[41] The fear of being beaten made him hasten the launch, moving it to the fourth of October.^[41] The launch vehicle for PS-1, was a modified R-7 – vehicle 8K71PS number M1-PS– without much of the test equipment and radio gear that was present in the previous launches.^[40] It arrived at the Soviet missile base Tyura-Tam in September and was prepared for its mission at launch site number one.^[40] On Friday, 4 October 1957, at exactly 10:28:34 pm Moscow time, the R-7, with the now named Sputnik 1 satellite, lifted off the launch pad, and placed this artificial "moon" into an orbit a few minutes later.^[42] But the celebrations were muted at the launch control centre until the down-range far east tracking station at Kamchatka received the first distinctive beep...beep...beep sounds from Sputnik 1's radio transmitters, indicating that it was on its way to completing its first orbit.^[42] About 95 minutes after launch, the satellite flew over its launch site, and its radio signals were picked up by the engineers and military personnel at Tyura-Tam: that's when Korolev and his team celebrated the first successful artificial satellite placed into Earth-orbit.^[43]

Launch rocket family of Sputnik, Laika, Gagarin, and more — R7/Soyuz

The Soviet success caused public controversy in the United States, and Eisenhower ordered the civilian rocket and satellite project, Vanguard, to move up its timetable and launch its satellite much sooner than originally planned.^[44] The 6 December 1957 Project Vanguard launch failure occurred at Cape Canaveral in front of a live broadcast television audience in the United States.^[44] Only in the wake of this very public failure did von Braun's Redstone team get the go-ahead to launch their Jupiter-C rocket as soon as they could. Nearly four months after the launch of Sputnik 1, von Braun and the United States successfully launched its first satellite, on a modified Redstone booster, under the "civilian" name Juno 1 to differentiate it from the army's Redstone missile. The Juno 1 carried the Explorer 1 satellite,^[44] and the Explorer 1's flight data confirmed the existence of an Earth-encompassing radiation belt, previously theorized by James Van Allen. Confirmation of the Van Allen radiation belt was considered one of the outstanding discoveries of the International Geophysical Year.^[44]

Space Race in the 1960s[link]

First humans in space[link]

The first human to travel into orbit, Yuri Gagarin, launched in 1961.

On 12 April 1961, the Soviet Union won the race with the United States to get a human into space, when Yuri Gagarin was launched into orbit around the Earth on Vostok 1.^[45] They dubbed Gagarin the first cosmonaut, roughly translated from Russian and Greek as "sailor of the universe". Although he had the ability to take over manual control of his spacecraft in an emergency, it was flown in an automatic mode as a precaution; medical science at that time did not know what would happen to a human in the weightlessness of space.^[45] Vostok 1 orbited the Earth for 108 minutes and made its reentry over the Soviet Union, with Gagarin ejecting from the spacecraft at 7,000 metres (23,000 ft), and landing by parachute.^[45] Under Fédération Aéronautique Internationale (International Federation of Aeronautics) FAI qualifying rules for aeronautical records, pilots must both take off and land with their craft, so the Soviets kept the landing procedures secret until 1978, when they finally admitted that Gagarin did not land with his spacecraft.^[45] When the flight was publicly announced, it was celebrated around the world as a great triumph, not just for the Soviet Union, but for the world itself, though it once again shocked and embarrassed the United States.^[46]

The United States called their space travelers astronauts ("star sailors" from the Greek), and it was 3 weeks later, on 5 May 1961, when Alan Shepard became the first one in space, launched on a suborbital mission Mercury-Redstone 3, in a spacecraft named Freedom 7.^[47] Though he did not achieve orbit, unlike Gagarin he was the first person to exercise manual control over his spacecraft's attitude and retro-rocket firing.^[48] The first Soviet cosmonaut to exercise manual control was Gherman Titov in Vostok 2 on 6 August 1961.^[49]

Almost a year after the Soviets put a human into orbit, astronaut John Glenn became the first American to orbit the Earth, on 20 February 1962.^[50] His Mercury-Atlas 6 mission completed three orbits in the Friendship 7 spacecraft, and splashed-down safely in the Atlantic Ocean, after a tense reentry, due to what falsely appeared from the telemetry data to be a loose heat-shield.^[50]

Kennedy launches the Moon race[link]

On 20 April 1961, about one week after Gagarin's flight, American President John F. Kennedy sent a memo to Vice President Lyndon B. Johnson, asking him to look into the state of America's space program, and into programs that could offer NASA the opportunity to catch up.^[52] Johnson responded about one week later, concluding that the United States needed to do much more to reach a position of leadership. Johnson recommended that a piloted moon landing was far enough in the future that it was likely that the United States could achieve it first.^[53]

On 25 May, Kennedy announced his support for the Apollo program and redefined the ultimate goal of the Space Race in an address to a special joint session of Congress:"I believe that this nation should commit itself to achieving the goal, before this decade is out, of landing a man on the moon and returning him safely to the earth."^[54] His justification for the Moon Race, was that it was both vital to national security and it would focus the nation's energies in other scientific and social fields.^[51] He expressed his reasoning in the famous "We choose the Moon" speech, on 12 September 1962, before a large crowd at Rice University Stadium, in Houston, Texas, near the site of the future Johnson Space Center.^[51]

Proposed Joint U.S.-U.S.S.R. Moon Program[link]

On 20 September 1963, in a speech before the United Nations General Assembly, President Kennedy proposed that the United States and the Soviet Union join forces in their efforts to reach the moon. Soviet Premier Nikita Khrushchev initially rejected Kennedy's proposal, however during the next few weeks he concluded that both nations might realize cost benefits and technological gains from a joint venture. Khrushchev was poised to accept Kennedy's proposal at the time of Kennedy's assassination in November 1963.^[55]

Khrushchev and Kennedy had developed a measure of rapport during their years as leaders of the world's two superpowers, especially during the 1962 Cuban Missile Crisis. That trust was lacking with Vice President Johnson; when Johnson assumed the Presidency after Kennedy's assassination, Khrushchev dropped the idea of a joint U.S.-U.S.S.R. moon program.^[55]

Vostoks and Voskhods[link]

Vostok rocket displayed at Ostankino

The Soviet Union achieved another first, with the first dual-piloted flights, Vostok 3 and Vostok 4 on 11–15 August 1962.^[56] The two spacecraft came within approximately 6.5 kilometres (4.0 mi) of one another, close enough for radio communication.^[57] The launching of two spacecraft from the same pad during a very short period of time represented a significant technical accomplishment, however there was no capability for the spacecraft to maneuver closer to each other, and over the course of the mission they continued to drift as far as 2,850 kilometres (1,770 mi) apart.^[58]