Spaceflight before 1951

Spaceflight as a practical endeavor began during World War II with the development of operational liquid-fueled rockets. Beginning life as a weapon, the V-2 was pressed into peaceful service after the war at the United States' White Sands Missile Range as well as the Soviet Union's Kapustin Yar. This led to a flourishing of missile designs setting the stage for the exploration of space. The small American WAC Corporal rocket was evolved into the Aerobee, a much more powerful sounding rocket. Exploration of space began in earnest in 1947 with the flight of the first Aerobee, 46 of which had flown by the end of 1950. These and other rockets, both Soviet and American, returned the first direct data on air density, temperature, charged particles and magnetic fields in the Earth's upper atmosphere.

Spaceflight before 1951
Launch of a V-2 from Peenemünde
National firsts
Spaceflight Germany (1944)
 United States (1946)
 Soviet Union (1948)
Rockets
Maiden flights V-2
Bumper
Viking (first model)
Aerobee RTV-N-8
Aerobee RTV-N-10
Aerobee XASR-SC-1
Aerobee XASR-SC-2
Aerobee RTV-A-1
R-1
R-1A
R-2E
R-2
Retirements Bumper
Aerobee RTV-N-8
R-1A
R-2E

By 1948, the United States Navy had evolved the V-2 design into the Viking capable of more than 100 miles (160 km) in altitude. The first Viking to accomplish this feat, number four, did so 10 May 1950. The Soviet Union developed a virtual copy of the V-2 called the R-1, which first flew in 1948. Its longer-ranged successor, the R-2, entered military service in 1950. This event marked the entry of both superpowers into the post-V-2 rocketry era.

Origins and rocket development

The era of spaceflight began in 1942 with the development of the V-2 rocket (A-4) as a ballistic missile by Germany, the first vehicle capable of reaching the 100 kilometres (62 mi) boundary of space (as defined by the World Air Sports Federation).[1] On 20 June 1944, a V-2 (MW 18014) was launched vertically, reaching a height of 174.6 kilometres (108.5 mi).[2]

The post-war years saw rapid development in rocket technology by both superpowers, jumpstarted by the dozens of V-2s and hundreds of German specialists that ended up in the custody of the Soviet Union and the United States.[3]:216–7[4]:226[5]:43 The V-2, designed for carrying a warhead horizontally rather than vertical science missions, made an inefficient sounding rocket, while the wartime American WAC Corporal sounding rocket was too small to carry much scientific equipment.[4]:250 In 1946, the US Navy began development of its own heavy sounding rocket, the Viking, derived in part from the V-2.[6]:21–25[6]:236 The Aerobee was developed from the WAC Corporal to loft lighter payloads.[4]:250–1

The Soviet Union began military development of the R-1, a copy of the V-2 with modifications intended to improve reliability, in 1947.[5]:41,48 Flight testing of this first Soviet-made liquid-fueled missile began on 13 September 1948,[5]:129 and the rocket entered military service in 1950.[5]:135 Also from 1947, two advanced rockets with ranges of 600 kilometres (370 mi), the German émigré-designed G-1 (or R-10) and the Russian-designed R-2, competed for limited engineering and production staff, the latter winning out by the end of 1949[5]:65 and being put into service in 1951.[5]:274 The draft plan for the 3,000 kilometres (1,900 mi) range R-3 was approved on 7 December 1949,[5]:67 though it was never developed, later designs proving more useful and achievable.[5]:275–6

Space exploration

V-2, WAC Corporal, and R-1A
Aerobee launch at sea

The V-2s captured from Germany at the end of World War II were used for engineering and scientific missions by the United States and the Soviet Union. The first 25 captured V-2s were launched in the 15 months commencing 15 March 1946.[4]:398 By the end of 1950, more than 60 had been launched by the Americans, most of them equipped with research instruments.[7]:6 The first biological payloads launched to high altitude were sent on V-2s, starting with seeds and fruit flies in 1947, followed by mice and monkeys from 1948 onward.[8]

The V-2 was also used in early experiments with two-stage rockets: Project Bumper combined the V-2 first stage with the WAC Corporal as second stage. On 24 February 1949, Bumper 5 set an altitude record of 417 kilometres (259 mi).[4]:257–8 Around 10 WAC Corporals were also launched on their own in this period.[7]:6

The Soviet Union launched 11 captured V-2s in 1947.[5]:41 Three of the V-2s launched by the USSR in 1947 carried 500 kilograms (1,100 lb) experiment packages for measuring cosmic rays at high altitude; at least one returned usable data.[9]:56 Two Soviet R-1As (an experimental R-1 variant that tested nose cone separation at altitude) also carried scientific equipment during test launches in 1949, but neither returned usable data.[10]

Aerobee

First launched on 24 November 1947, the solid/liquid-fuel hybrid Aerobee quickly secured a reputation for reliability. With the development of these first generation purpose-built sounding rockets, the exploration of Earth's upper atmosphere and the nearest reaches of space began in earnest, a total of 46 Aerobee flights being launched through 1950.[11] Aerobee flights measured the velocity and density of cosmic rays above 70 miles (110 km) and made high altitude measurements of the Earth's magnetic field. Cameras mounted on Aerobee rockets returned the first high quality aerial photographs of sizeable regions of the Earth as well as large scale cloud formations.[4]:251

Viking
Launch of Viking 4

Vikings 1 and 2, launched in 1949 from White Sands Missile Range in New Mexico, both suffered from premature engine cutoff due to turbine leaks, significantly reducing their maximum altitude.[6]:98–102 The improved Viking 3, launched 9 February 1950 reached 50 mi (80 km) and could have gone higher. However, after 34 seconds of accurately guided flight, the rocket veered westward and had to be destroyed by range safety.[6]:108–114

On 10 May 1950, Viking 4 was launched from a site in the Pacific Ocean between Jarvis Island and Christmas Island. The fourth Viking became the first sounding rocket ever launched from a sea-going vessel, the USS Norton Sound. This flight was perfect, reaching 106.4 mi (171.2 km), more than double that reached by the earlier Vikings.[6]:108–114

Viking 5, launched 21 November 1950, carried a vast array of radiation detectors. The rocket also carried two movie cameras to take high altitude film of the Earth all the way to its peak height of 108 miles (174 km) as well as Pirani gauges to measure air densities in the upper atmosphere.[6]:148,236 Viking 6, launched 11 December, underperformed, reaching a maximum altitude of 40 miles (64 km).[6]:151–153,236

Launches

1942
1942 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
13 June — 12 December V-2 Peenemünde Wehrmacht
Wehrmacht Suborbital Missile testSame dayMixed
7 V-2 rockets launched on test flights, 3 successfully[12]

1943
1943 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
7 January — 30 December V-2 Peenemünde, Heidelager Wehrmacht
Wehrmacht Suborbital Missile testSame dayMixed
39 V-2 rockets launched on test flights; at least 9 failures[12]

1944
1944 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
20 June V-2 Greifswalder Oie Wehrmacht
MW 18014[2] Wehrmacht Suborbital Missile test20 JuneSuccessful
First artificial object to cross the Kármán line.
Vertical test, apogee: 174.6 kilometres (108.5 mi)
8 September V-2 Houffalize Wehrmacht
Wehrmacht Suborbital Missile attack8 SeptemberSuccessful
First combat usage of V-2 after more than a hundred test flights; ~3000 combat launches followed[12] (see List of V-2 test launches)

1945
1945 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
2 October
13:41		 V-2 Cuxhaven UK military
Suborbital 2 OctoberSuccessful
First launch of Operation Backfire; apogee: 69.4 kilometres (43.1 mi)[13]
4 October
13:15		 V-2 Cuxhaven UK military
Suborbital 4 OctoberPartial failure
Apogee: 17.4 kilometres (10.8 mi)[13]
15 October
14:06		 V-2 Cuxhaven UK military
Suborbital 15 OctoberSuccessful
Press and international observers present; Apogee: 64 kilometres (40 mi)[13]

1946
1946 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
16 April
21:47		 V-2 White Sands LC-33 General Electric / US Army
WSPG[14] Suborbital Cosmic Radiation (Applied Physics Laboratory)[15]16 AprilGuidance failure[14]
First launch of Project Hermes, apogee: 8 kilometres (5.0 mi)
10 May
21:15		 V-2 White Sands LC-33 GE / US Army
WSPG[14] Suborbital Cosmic Radiation (APL)[15]10 MaySuccessful
Project Hermes launch, apogee: 112 kilometres (70 mi), First US spaceflight
29 May
21:12		 V-2 White Sands LC-33 GE / US Army
GE[14] Suborbital Cosmic Radiation (APL)[15]29 MaySuccessful
Project Hermes launch, apogee: 112 kilometres (70 mi)
13 June
23:40		 V-2 White Sands LC-33 GE / US Army
GE[14] Suborbital Solar radiation, Ionosphere (NRL)[15]13 JuneSuccessful
Project Hermes launch, apogee: 117 kilometres (73 mi)
28 June
19:25		 V-2 White Sands LC-33 GE / US Army
Naval Research Laboratory[14] Suborbital Cosmic Radiation, Solar Radiation, Pressure, Temperature. Ionosphere[16]:336–337 (V-2 NO. 6)28 JuneSuccessful
Project Hermes launch, apogee: 108 kilometres (67 mi)
9 July
19:25		 V-2 White Sands LC-33 GE / US Army
GE[14] Suborbital Cosmic Radiation, Ionosphere (NRL), Biological (Harvard University)[16]:338–339 (V-2 NO. 7)9 JulySuccessful
Project Hermes launch, apogee: 134 kilometres (83 mi)
19 July
19:11		 V-2 White Sands LC-33 GE / US Army
GE[14] Suborbital Ionospheric (NRL)[15]19 JulyLaunch failure, explosion at 28.5 seconds[14]
Project Hermes launch, apogee: 5 kilometres (3.1 mi)
30 July
19:36		 V-2 White Sands LC-33 GE / US Army
Applied Physics Laboratory[14] Suborbital Cosmic Radiation, Ionosphere (NRL)[16]:342–343 (V-2 NO. 9)30 JulySuccessful
Project Hermes launch, apogee: 167 kilometres (104 mi)
15 August
18:00		 V-2 White Sands LC-33 GE / US Army
Princeton University[14] Suborbital Cosmic Radiation, Ionosphere[16]:344 (V-2 NO. 10)15 AugustGuidance Failure at 13.9 seconds[14]
Project Hermes launch, apogee: 3 kilometres (1.9 mi)
22 August
17:15		 V-2 White Sands LC-33 GE / US Army
University of Michigan[14] Suborbital Pressure, Density, Ionosphere Aeronomy, Sky Brightness[15]22 AugustGuidance Failure immediately after lift[14]
Project Hermes launch
10 October
18:02		 V-2 White Sands LC-33 GE / US Army
NRL[14] Suborbital Cosmic Ray, Ionosphere, Pressure-Temperature, Solar Spectroscopy, Ejection of Cosmic Ray Recording Camera[17] Selected seeds (Harvard), Cross jet attenuation transmitter & receiver[16]:346–347 (V-2 NO. 12)10 OctoberSuccessful
Project Hermes launch, apogee: 164 kilometres (102 mi)
24 October
19:15		 V-2 White Sands LC-33 GE / US Army
APL[14] Suborbital Cosmic & Solar radiation, winds, photography[15]24 OctoberSuccessful, Short burning time (59 sec)[18]
Project Hermes launch, apogee: 105 kilometres (65 mi), First photo of Earth from space
7 November
20:31		 V-2 White Sands LC-33 GE / US Army
Princeton University[14] Suborbital Cosmic Radiation[15]7 NovemberGuidance Failure at 2 seconds, missile turned sideways, flew horizontal and was destroyed[16]:350 (V-2 NO. 14)
Project Hermes launch, apogee: 0.39 kilometres (0.24 mi)
21 November
16:55		 V-2 White Sands LC-33 GE / US Army
Watson Laboratories, University of Michigan[18] Suborbital Pressure, Temperature, Ionosphere, Sky Brightness, Voltage breakdown[16]:351–352 (V-2 NO. 15)21 NovemberSuccessful
Project Hermes launch, apogee: 102 kilometres (63 mi)
5 December
20:08		 V-2 White Sands LC-33 GE / US Army
NRL[14] Suborbital Cosmic & Solar Radiation, Pressure, Temperature, Photography[15]5 DecemberSuccessful, Guidance Problems
Project Hermes launch, apogee: 167 kilometres (104 mi)
18 December
05:12		 V-2 White Sands LC-33 GE / US Army
GRENADES APL[14] Suborbital Cosmic Radiation, Meteor research, Biological (National Institute of Health)[15]18 DecemberSuccessful, extraordinary range due to guidance failure[16]:354 (V-2 NO. 16)
Project Hermes launch, apogee: 187 kilometres (116 mi); first night flight of V-2, released artificial meteors for photographic observation[19]

1947
1947 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
10 January
21:13		 V-2 White Sands LC-33 GE / US Army
NRL[14] Suborbital Cosmic Radiation,[15] "Daughter" Canister Release (Air Material Command)[16]:357–358 (V-2 NO. 18)10 JanuarySuccessful, Roll at 40 seconds[14]
Project Hermes launch, apogee: 116 kilometres (72 mi)
24 January
00:22		 V-2 White Sands LC-33 GE / US Army
GE[14] Suborbital Test Guidance System,[14] Hermes A-2 Telemetry System Test[16]:359–360 (V-2 NO. 19)24 JanuarySuccessful
Project Hermes launch, apogee: 49.88 kilometres (30.99 mi).
20 February
18:16		 V-2 White Sands LC-33 GE / US Army
Blossom I Air Materiel Command[14] Suborbital Pressure-temperature (University of Michigan), Ionosphere (Air Force Cambridge Research Center, UoM), Sky brightness, Voltage Breakdown measurements (AFCRC), Biological rye, cotton seeds and fruit flies, first animals in space,[20] Blossom parachute recovery of canister (Cambridge Field Station)[16]:361–362 (V-2 NO. 20)20 FebruarySuccessful, Guidance disturbance at 27 sec, Roll at 37.5 sec[14]
Project Hermes launch, apogee: 109 kilometres (68 mi).
7 March
18:23		 V-2 White Sands LC-33 GE / US Army
NRL[14] Suborbital Cosmic Radiation, Pressure-temperature, Solar Radiation, Ionosphere (NRL), Biological rye, cotton seeds and fruit flies (Harvard)[16]:363–365 (V-2 NO. 21)7 MarchSuccessful
Project Hermes launch, apogee: 161 kilometres (100 mi).
1 April
20:10		 V-2 White Sands LC-33 GE / US Army
APL[14] Suborbital Cosmic Radiation, Solar Radiation (APL & Yerkes Observatory), High altitude photography (Gun Sight Aiming Point camera)[16]:366–367 (V-2 NO. 22)1 AprilSuccessful
Project Hermes launch, apogee: 129 kilometres (80 mi)
9 April
00:10		 V-2 White Sands LC-33 GE / US Army
APL[14] Suborbital Cosmic Radiation, Solar Radiation, High altitude photography.[16]:368–369 (V-23 NO. 20)9 AprilSuccessful
Project Hermes launch, apogee: 103 kilometres (64 mi)
17 April
23:22		 V-2 White Sands LC-33 GE / US Army
GRENADES GE[14] Suborbital Pressure-Temperature: 9 Grenades (Signal Corps Engineering Laboratories)[16]:370–371 (V-2 NO. 24)17 AprilSuccessful, Roll at 57.5 seconds[14]
Project Hermes launch, apogee: 140 kilometres (87 mi)
15 May
23:08		 V-2 White Sands LC-33 GE / US Army
NRL[14] Suborbital Density-pressure-temperature grenades (SCEL), (Michigan University), Composition, Cosmic Radiation, Solar Radiation (NRL)[16]:374–375 (V-2 NO. 26)15 MaySuccessful, Steering trouble from lift[14]
Project Hermes launch, apogee: 122 kilometres (76 mi)
29 May V-2 White Sands LC-33 GE / US Army
Hermes II GE Suborbital Missile test of ramjet diffusers called "Organ"[21]29 MayLaunch Failure, missile went South instead of North, landed in Mexico[22]
Project Hermes launch, apogee: 50 kilometres (31 mi), maiden flight of Hermes II
10 July
19:18		 V-2 White Sands LC-33 GE / US Army
NRL[14] Suborbital Density-pressure-temperature, Cosmic Radiation, Ionosphere, Simulant agent experiment – Camp Detrick, Indiana, seed containers in control chamber (Harvard College Observatory)[16]:363–364 (V-2 NO. 29)10 JulyLaunch failure, Steering trouble from lift[14]
Project Hermes launch, apogee: 16 kilometres (9.9 mi)
29 July
12:55		 V-2 White Sands LC-33 GE / US Army
APL[14] Suborbital Cosmic Radiation, Solar Radiation, High altitude photography (APL)[16]:386–387 (V-2 NO. 30)29 JulySuccessful, Vane #4 ceased to operate at 27 sec[14]
Project Hermes launch, apogee: 159 kilometres (99 mi)
6 September V-2 USS Midway, Atlantic Ocean, southeast of Bermuda US Navy
US Navy Suborbital Missile test6 SeptemberLaunch failure
Operation Sandy, first shipboard missile launch, apogee: 1 kilometre (0.62 mi)
9 October
19:15		 V-2 White Sands LC-33 GE / US Army
GE[14] Suborbital Density-pressure-temperature, Skin temperature, Composition (University of Michigan), Solar radiation (NRL)[16]:(V-2 NO. 27)9 OctoberSuccessful, Steering disturbance at 48.4 sec. Roll at 52 sec.[14]
Project Hermes launch, apogee: 156 kilometres (97 mi)
18 October
07:47		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test28 OctoberPartial failure
Apogee: 86 kilometres (53 mi); destroyed during ballistic portion of flight[23]
20 October
07:47		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test20 OctoberPartial failure
Apogee: 85 kilometres (53 mi); tore loose from launch stand; flew 180 kilometres (110 mi) left of planned target[23]
23 October
14:05		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test23 OctoberLaunch failure
Apogee: 14 kilometres (8.7 mi); payload destroyed, rocket disintegrated[23]
28 October
14:05		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test28 OctoberSuccessful
Apogee: 87 kilometres (54 mi)[23]
31 October
13:41		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test31 OctoberLaunch failure
Apogee: 0 kilometres (0 mi); loss of control on longitudinal axis[23]
2 November
15:14		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test2 NovemberSuccessful
Apogee: 88 kilometres (55 mi)[23]
3 November
12:05		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test3 NovemberLaunch failure
Apogee: 0 kilometres (0 mi); rolled after launch and lost stabilization[23]
4 November
15:02		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test4 NovemberSuccessful
Apogee: 89 kilometres (55 mi)[23]
10 November
09:39		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test10 NovemberLaunch failure
Apogee: 11 kilometres (6.8 mi); lost guidance[23]
13 November
08:30		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test13 NovemberSuccessful
Apogee: 89 kilometres (55 mi)[23]
13 November
14:00		 V-2 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test13 NovemberPartial failure
Apogee: 89 kilometres (55 mi); broke up on re-entry[23]
20 November
23:47		 V-2 White Sands LC-33 GE / US Army
GE[14] Suborbital Technology development flight for GE[24]20 NovemberLaunch failure, Propulsion trouble at 36 sec.[14]
Apogee: 21 kilometres (13 mi)
24 November
17:20		 Aerobee RTV-N-8 White Sands LC-35 US Navy
Applied Physics Laboratory[16]:Table I,7.3 Suborbital Test flight24 NovemberLaunch failure, off course, flight terminated.[25]
Apogee: 56 kilometres (35 mi), maiden flight of the Aerobee RTV-N-8[11]
8 December
21:42		 V-2 White Sands LC-33 GE / US Army
Blossom II AMC[14] Suborbital Density-pressure-temperature (Michigan University), Skin temperature (Boston University), Solar soft X-rays,Vertical incidence ionosphere propagation, Oblique incidence ionosphere propagation, Aspect project (cameras to be lowered by parachute) (Wright Air Development Center), Sky brightness (AFCRC)[16]:379–382 (V-2 NO. 28)8 DecemberSuccessful
Project Hermes launch, apogee: 105 kilometres (65 mi)

1948
1948 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
22 January
20:12		 V-2 White Sands LC-33 GE / US Army
NRL Suborbital Chemical release / Aeronomy22 JanuarySuccessful
Project Hermes launch, apogee: 159 kilometres (99 mi)[12]
6 February
17:17		 V-2 White Sands LC-33 GE / US Army
GE Suborbital Technology development flight for GE6 FebruarySuccessful
Project Hermes launch, apogee: 113 kilometres (70 mi)[12]
5 March
22:51		 Aerobee RTV-N-8 White Sands LC-35 US Navy
APL Suborbital Chemical release5 MarchSuccessful
Apogee: 117.5 kilometres (73.0 mi)[11]
19 March
23:10		 V-2 White Sands LC-33 GE / US Army
Blossom IIA GE Suborbital Aeronomy19 MarchLaunch failure
Project Hermes launch, apogee: 5.5 kilometres (3.4 mi)[12]
2 April
13:47		 V-2 White Sands LC-33 GE / US Army
US Army Signal Corps Suborbital Aeronomy / Ionosphere / Solar UV2 AprilSuccessful
Project Hermes launch, apogee: 144 kilometres (89 mi)[12]
13 April
21:41		 Aerobee RTV-N-8 White Sands LC-35 US Navy
APL Suborbital Magnetic field research13 AprilSuccessful
Apogee: 114.3 kilometres (71.0 mi)[11]
19 April
19:54		 V-2 White Sands LC-33 GE / US Army
NRL Suborbital Solar UV / Ionosphere19 AprilGuidance Failure
Project Hermes launch, apogee: 56 kilometres (35 mi)[12]
13 May
13:43		 Bumper White Sands LC-33 GE / US Army
Bumper 1 GE Suborbital Solar / Ionosphere13 MaySuccessful
Maiden flight of Bumper, apogee: 127.6 kilometres (79.3 mi)[26]
27 May
14:15		 V-2 White Sands LC-33 GE / US Army
APL Suborbital Solar UV / Chemical release27 MaySuccessful
Project Hermes launch, apogee: 140 kilometres (87 mi)[12]
11 June
10:22		 V-2 White Sands LC-33 GE / US Army
Blossom III AMC Suborbital Biology / Ionosphere / Aeronomy11 JuneLaunch failure, premature valve closure
Project Hermes launch, apogee: 63 kilometres (39 mi)[12]
26 July
16:47		 Aerobee RTV-N-8 White Sands LC-35 US Navy
APL Suborbital Imaging26 JulySuccessful
Apogee: 112.7 kilometres (70.0 mi)[11]
26 July
18:03		 V-2 White Sands LC-33 GE / US Army
APL Suborbital Chemical release / Aeronomy26 JulySuccessful, Propulsion issues at 45.2s
Project Hermes launch, apogee: 97 kilometres (60 mi)[12]
5 August
12:07		 V-2 White Sands LC-33 GE / US Army
NRL Suborbital UV Astronomy / Solar X-ray5 AugustSuccessful
Project Hermes launch, apogee: 167 kilometres (104 mi)[12]
6 August
1:37		 Aerobee RTV-N-8 White Sands LC-35 US Navy
NRL Suborbital Aeronomy / Solar UV6 AugustSuccessful
Apogee: 96.6 kilometres (60.0 mi)[11]
19 August
14:45		 Bumper White Sands LC-33 GE / US Army
Bumper 2 GE Suborbital Solar UV19 AugustLaunch failure
Apogee: 13.1 kilometres (8.1 mi)[26]
3 September
01:00		 V-2 White Sands LC-33 GE / US Army
GRENADES USASC Suborbital Aeronomy3 SeptemberSuccessful
Project Hermes launch, apogee: 151 kilometres (94 mi)[12]
17 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test17 SeptemberLaunch failure[27]
Maiden flight of the R-1[27]
30 September
15:30		 Bumper White Sands LC-33 GE / US Army
Bumper 3 GE Suborbital Solar UV / X-Ray30 SeptemberLaunch failure, 2nd Stage Failure
Apogee: 150.6 kilometres (93.6 mi)[26]
10 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test10 OctoberSuccessful[27]
11 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test, sounding rocket11 OctoberSuccessful
First Soviet spaceflight with scientific experiments[27]
13 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test13 OctoberSuccessful[27]
21 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test21 OctoberSuccessful[27]
23 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test23 OctoberSuccessful[27]
1 November
14:24		 Bumper White Sands LC-33 GE / US Army[26]
Bumper 4 GE Suborbital Test flight1 NovemberLaunch failure, tail explosion at 28.5s
Apogee: 5 kilometres (3.1 mi)
1 November R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test1 NovemberSuccessful[27]
2 November
00:12		 Aerobee RTV-N-8 White Sands LC-35 US Navy
APL Suborbital Cosmic radiation, solar radiation and particles2 NovemberSuccessful
Apogee: 91 kilometres (57 mi)[11]
3 November R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test3 NovemberSuccessful[27]
4 November R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test4 NovemberSuccessful[27]
5 November R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test5 NovemberSuccessful
Last of nine launches in the first test series[27]
18 November
22:35		 V-2 White Sands LC-33 GE / US Army
GE Suborbital Ramjet research18 NovemberSuccessful
Project Hermes launch, apogee: 145 kilometres (90 mi)[12]
9 December
16:08		 V-2 White Sands LC-33 GE / US Army
USASC Suborbital Aeronomy / Solar X-Ray / Biology9 DecemberSuccessful
Project Hermes launch, apogee: 108 kilometres (67 mi)[12]
9 December
22:38		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Aeronomy9 DecemberSuccessful
Apogee: 91.6 kilometres (56.9 mi)[11]

1949
1949 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
14 January
20:26		 V-2 White Sands LC-33 US Army
Hermes II US Army Suborbital Missile test14 JanuaryLaunch failure
Project Hermes launch, apogee: 1 kilometre (0.62 mi)[28]
28 January
17:20		 V-2 White Sands LC-33 GE / US Army
NRL Suborbital Solar x-ray / Ionospheric / Aeronomy / Biological28 JanuaryLaunch failure
Blossom launch, apogee: 60 kilometres (37 mi)[28]
29 January
06:17		 Aerobee RTV-N-8 White Sands LC-35 US Navy
NRL Suborbital Radiation / Ionospheric29 JanuarySuccessful
Apogee: 96.6 kilometres (60.0 mi)[11]
1 February
18:38		 Aerobee RTV-N-8 White Sands LC-35 US Navy
NRL Suborbital Solar UV and X-Ray1 FebruaryLaunch failure
Apogee: 0 kilometres (0 mi)[11]
17 February
17:00		 V-2 White Sands LC-33 GE / US Army
APL Suborbital Chemical release / Solar UV / Biological17 FebruarySuccessful
Apogee: 100.8 kilometres (62.6 mi)[28]
24 February
22:14		 Bumper White Sands LC-33 GE / US Army
Bumper 5 GE Suborbital Aeronomy24 FebruarySuccessful
Apogee: 393 kilometres (244 mi). The new altitude record.[26]
2 March
00:15		 Aerobee RTV-N-8 White Sands LC-35 US Navy
APL Suborbital Test for shipboard launch; dummy payload2 MarchLaunch failure
Apogee: 0 kilometres (0 mi)[11]
17 March
23:20		 Aerobee RTV-N-8 USS Norton Sound, Pacific Ocean near South America US Navy
APL Suborbital Ionospheric17 MarchSuccessful
Apogee: 104.6 kilometres (65.0 mi)[11]
22 March
06:43		 V-2 White Sands LC-33 GE / US Army
Blossom IVA AMC Suborbital Ionospheric22 MarchSuccessful
Blossom IVA; apogee: 129 kilometres (80 mi)[28]
22 March
17:20		 Aerobee RTV-N-8 USS Norton Sound, Pacific Ocean near South America US Navy
APL Suborbital Ionospheric22 MarchSuccessful
Apogee: 104.6 kilometres (65.0 mi)[11]
24 March
15:14		 Aerobee RTV-N-8 USS Norton Sound, Pacific Ocean near South America US Navy
APL Suborbital Ionospheric24 MarchLaunch failure
Apogee: 6 kilometres (3.7 mi), pressure valve malfunction, booster separated on ignition[11]
11 April
22:05		 V-2 White Sands LC-33 GE / US Army
USASC Suborbital Aeronomy / Solar X-Ray / Biological11 AprilSuccessful
Apogee: 85 kilometres (53 mi)[28]
22 April
00:17		 Bumper White Sands LC-33 GE / US Army
Bumper 6 GE Suborbital Solar / Aeronomy22 AprilLaunch failure
Apogee: 50 kilometres (31 mi)[26]
3 May
16:14		 Viking (first model) White Sands LC-33 – Army Launch Area 1 US Navy
Viking 1 NRL Suborbital Aeronomy / Imaging3 MayPartial launch failure
Apogee: 83 kilometres (52 mi)[6]:236[29]
5 May
15:15		 V-2 White Sands LC-33 GE / US Army
GE Suborbital Technology development flight for GE / Solar5 MayLaunch failure
Apogee: 8.9 kilometres (5.5 mi)[28]
7 May
03:12		 R-1A Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test7 MaySuccessful
Apogee: 109 kilometres (68 mi), maiden flight of R-1A,[10] tested separable warhead
10 May
15:57		 R-1A Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test10 MaySuccessful
Tested separable warhead[10]
15 May
02:48		 R-1A Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test15 MaySuccessful
Tested separable warhead[10]
16 May
21:55		 R-1A Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test16 MaySuccessful
Tested separable warhead[10]
24 May
01:40		 R-1A Kapustin Yar NII-88 Section 3
FIAR-1 NII-88 Section 3 Suborbital Missile test / Aeronomy24 MayPartial Failure
Vertical flight, tested separable warhead, carried aeronomy experiments that were not recovered[10]
28 May
01:50		 R-1A Kapustin Yar NII-88 Section 3
FIAR-1 NII-88 Section 3 Suborbital Missile test / Aeronomy28 MayPartial Failure
Final R-1A flight; vertical flight, tested separable warhead, carried aeronomy experiments damaged on landing and returned no usable data[10]
2 June
13:10		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Aeronomy2 JuneSuccessful
Apogee: 78.4 kilometres (48.7 mi)[11]
14 June
22:35		 V-2 White Sands LC-33 GE / US Army
Blossom IVB AMC Suborbital Biological, Atmospheric14 JuneSuccessful
Apogee: 133.9 kilometres (83.2 mi), carried Albert II, first monkey in space[20][30][28]
15 June
02:03		 Aerobee RTV-N-8 White Sands LC-35 US Navy
NRL Suborbital Ozone research15 JuneSuccessful
Apogee: 109.5 kilometres (68.0 mi)[11]
17 June
02:03		 Aerobee RTV-N-8 White Sands LC-35 US Navy
APL Suborbital Classified mission17 JuneSuccessful
Apogee: 88.5 kilometres (55.0 mi)[11]
23 June
23:21		 Aerobee RTV-N-8 White Sands LC-35 US Navy
APL Suborbital Solar / Aeronomy23 JuneSuccessful
Apogee: 88.5 kilometres (55.0 mi)[11]
21 July
16:01		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Aeronomy21 JulySuccessful
Apogee: 76.1 kilometres (47.3 mi)[11]
6 September
16:57		 Viking (first model) White Sands LC-33 – Army Launch Area 1 US Navy
Viking 2 NRL Suborbital Aeronomy / Imaging6 SeptemberLaunch failure
Apogee: 51.5 kilometres (32.0 mi)[6]:236[29]
10 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test10 SeptemberSuccessful[27]
First flight of second series of tests
11 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test11 SeptemberSuccessful[27]
13 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test13 SeptemberSuccessful[27]
14 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test14 SeptemberSuccessful[27]
16 September
23:19		 V-2 White Sands LC-33 GE / US Army
Blossom IVC AMC Suborbital Biological16 SeptemberLaunch failure
Apogee: 5 kilometres (3.1 mi), carried Albert III[28]
17 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test17 SeptemberSuccessful[27]
19 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test19 SeptemberSuccessful[27]
20 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test20 SeptemberLaunch failure[27]
20 September
17:03		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Aeronomy20 SeptemberSuccessful
Apogee: 58.6 kilometres (36.4 mi)[11]
23 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test23 SeptemberLaunch failure[27]
25 September
11:16		 R-2E Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test25 SeptemberSuccessful
Maiden flight of R-2E, a modified R-1 missile to test R-2 concepts: integral fuel tank and separable warhead[31]
28 September R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test28 SeptemberSuccessful[27]
29 September
16:58		 V-2 White Sands LC-33 GE / US Army
NRL Suborbital Ionosphere / Meteorites29 SeptemberSuccessful
Project Hermes launch, apogee: 151.1 kilometres (93.9 mi)[28]
30 September
11:49		 R-2E Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test30 SeptemberSuccessful[31]
2 October
11:00		 R-2E Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test2 OctoberPartial failure
Fire in tail compartment[31]
3 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test3 OctoberSuccessful[27]
6 October V-2 White Sands LC-33 US Army
Hermes II US Army Suborbital Missile test6 OctoberLaunch failure
Project Hermes launch, apogee: 4 kilometres (2.5 mi)[28]
8 October
06:05		 R-2E Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test8 OctoberSuccessful[31]
8 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test8 OctoberSuccessful[27]
10 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test10 OctoberSuccessful[27]
11 October
12:45		 R-2E Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test11 OctoberPartial failure
Fire in tail compartment, last of five R-2E launches[31]
12 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test12 OctoberSuccessful[27]
13 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test13 OctoberSuccessful[27]
13 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test13 OctoberSuccessful[27]
15 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test15 OctoberSuccessful[27]
18 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test18 OctoberSuccessful[27]
19 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test19 OctoberSuccessful[27]
22 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test22 OctoberSuccessful[27]
23 October R-1 Kapustin Yar NII-88 Section 3
NII-88 Section 3 Suborbital Missile test23 OctoberSuccessful[27]
Last of second series of twenty firings
18 November
16:03		 V-2 White Sands LC-33 GE / US Army
GRENADES USASC Suborbital Aeronomy / Chemical release18 NovemberSuccessful
Apogee: 124.2 kilometres (77.2 mi)[28]
2 December
22:20		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Solar, imaging, aeronomy2 DecemberSuccessful
Apogee: 96 kilometres (60 mi), maiden flight of the RTV-A-1[11]
6 December
18:32		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Air sampling aeronomy mission6 DecemberSuccessful
Apogee: 64.9 kilometres (40.3 mi)[11]
7 December
00:16		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Air sampling aeronomy mission7 DecemberSuccessful
Apogee: 60 kilometres (37 mi)[11]
8 December
19:15		 V-2 White Sands LC-33 GE / US Army
Blossom IVD AMC Suborbital Biological8 DecemberSuccessful
Apogee: 127 kilometres (79 mi), carried Albert IV[28]
15 December
17:10		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Solar, imaging, aeronomy15 DecemberLaunch failure
Apogee: 0.3 kilometres (0.19 mi)[11]

1950
1950 launches
Date and time (UTC) Rocket Flight number Launch site LSP
Payload Operator Orbit Function Decay (UTC) Outcome
Remarks
15 January
23:45		 Aerobee RTV-N-10 USS Norton Sound, Bering Sea US Navy
Applied Physics Laboratory Suborbital Particle physics15 JanuarySuccessful
Ship-launched; Apogee: 72.4 kilometres (45.0 mi), maiden flight of the RTV-N-10[11]
18 January
23:17		 Aerobee RTV-N-10 USS Norton Sound, Bering Sea US Navy
APL Suborbital Particle physics18 JanuarySuccessful
Ship-launched; Apogee: 80.5 kilometres (50.0 mi)[11]
9 February
21:44		 Viking (first model) White Sands LC-33 – Army Launch Area 1 US Navy
Viking 3 NRL Suborbital Solar / Imaging9 FebruaryLaunch failure
Veered off-course, failed to reach space, apogee: 80.5 kilometres (50.0 mi)[6]:236[29]
14 February
23:14		 Aerobee RTV-N-8 White Sands LC-35 US Navy
NRL Suborbital Cosmic gamma Ionosphere mission14 FebruarySuccessful
Apogee: 87.6 kilometres (54.4 mi), final flight of the RTV-N-8[11]
17 February
18:00		 V-2 White Sands LC-33 GE / US Army
NRL Suborbital Solar x-ray / Chemical release / Aeronomy17 FebruarySuccessful
Apogee: 148 kilometres (92 mi)[28]
22 February
00:54		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Aeronomy22 FebruarySuccessful
Apogee: 49.1 kilometres (30.5 mi)[11]
4 March
00:36		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Aeronomy4 MarchSuccessful
Apogee: 72.4 kilometres (45.0 mi)[11]
14 March
20:43		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Solar radiation14 MarchLaunch failure
Apogee: 3.2 kilometres (2.0 mi)[11]
26 April
01:11		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy26 AprilSuccessful
Apogee: 99.5 kilometres (61.8 mi), maiden flight of the XASR-SC-2[11]
12 May
03:08		 Viking (first model) USS Norton Sound, Pacific Ocean, near Jarvis Island US Navy
Viking 4 US Navy Suborbital Ionospheric / Aeronomy12 MaySuccessful
Apogee: 171 kilometres (106 mi)[6]:236[29]
12 May
12:30		 Aerobee RTV-N-10 White Sands LC-35 US Navy
APL Suborbital Particle physics12 MaySuccessful
Ship-launched; Apogee: 88.1 kilometres (54.7 mi)[11]
26 May
19:43		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Solar radiation26 MaySuccessful
Apogee: 67.6 kilometres (42.0 mi)[11]
2 June
17:07		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Sky brightness research2 JuneSuccessful
Apogee: 24.8 kilometres (15.4 mi)[11]
20 June
15:38		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Aeronomy20 JuneSuccessful
Apogee: 92.6 kilometres (57.5 mi)[11]
14 July
08:39		 Aerobee XASR-SC-1 White Sands LC-35 US Army
USASC Suborbital Aeronomy14 JulySuccessful
Apogee: 69.2 kilometres (43.0 mi)[11]
24 July
14:29		 Bumper Cape Canaveral LC-3 GE / US Army
Bumper 8 GE Suborbital Low angle speed test24 JulyLaunch failure
First missile launch from Cape Canaveral; apogee: 20 kilometres (12 mi)[26]
29 July
11:25		 Bumper Cape Canaveral LC-3 GE / US Army
Bumper 7 GE Suborbital Low angle speed test29 JulySuccessful
Apogee: 35.2 kilometres (21.9 mi)[26]
3 August
23:52		 Aerobee RTV-N-10 White Sands LC-35 US Navy
NRL Suborbital Solar radiation3 AugustLaunch failure
Apogee: 6 kilometres (3.7 mi)[11]
17 August
15:45		 Aerobee RTV-N-10 White Sands LC-35 US Navy
APL Suborbital Spectrometry17 AugustSuccessful
Apogee: 101.4 kilometres (63.0 mi)[11]
31 August
17:09		 V-2 White Sands LC-33 GE / US Army
Blossom IVG AMC Suborbital Biological31 AugustSuccessful
Apogee: 137 kilometres (85 mi), carried a mouse[28]
1 October R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 OctoberPartial failure
Maiden flight of the R-2 prototype missile; missed target[32]
1 October R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 OctoberPartial failure
Missed target[32]
12 October
19:36		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Photography12 OctoberSuccessful
Apogee: 91.3 kilometres (56.7 mi)[11]
17 October
04:00		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy17 OctoberSuccessful
Apogee: 80.5 kilometres (50.0 mi)[11]
18 October
04:30		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy18 OctoberSuccessful
Apogee: 85 kilometres (53 mi)[11]
21 October R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test21 OctoberPartial Failure
Missed target[32]
26 October
23:02		 V-2 White Sands LC-33 GE / US Army
Ballistic Research Laboratory Suborbital Technology development for NRL26 OctoberLaunch failure
Apogee: 8.1 kilometres (5.0 mi)[28]
27 October
13:30		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy27 OctoberSuccessful
Apogee: 80.2 kilometres (49.8 mi)[11]
1 November R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 NovemberPartial failure
Missed target[32]
1 November R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 NovemberPartial failure
Missed target[32]
1 November R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 NovemberPartial failure
Missed target[32]
1 November R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 NovemberPartial failure
Missed target[32]
1 November R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 NovemberPartial failure
Missed target[32]
2 November
16:29		 Aerobee RTV-A-1 Holloman LC-A US Air Force
US Air Force Suborbital Air glow research2 NovemberSuccessful
Apogee: 91.8 kilometres (57.0 mi)[11]
9 November V-2 White Sands LC-33 US Army
Hermes II US Army Suborbital Missile test9 NovemberPartial Failure
Project Hermes launch, apogee: 150 kilometres (93 mi), final flight of the Hermes II[33]
21 November
17:18		 Viking (first model) White Sands LC-33 – Army Launch Area 1 US Navy
Viking 5 NRL Suborbital Solar / Ionospheric21 NovemberSuccessful
Apogee: 174 kilometres (108 mi)[6]:236[29]
1 December R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 DecemberPartial failure
Missed target[32]
1 December R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 DecemberPartial failure
Missed target[32]
1 December R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test1 DecemberPartial failure
Missed target[32]
11 December
17:04		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy11 DecemberLaunch failure
Apogee: 83.9 kilometres (52.1 mi)[11]
12 December
04:06		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy12 DecemberSuccessful
Apogee: 84 kilometres (52 mi)[11]
12 December
07:04		 Viking (first model) White Sands LC-33 – Army Launch Area 1 US Navy
Viking 6 NRL Suborbital Solar / Ionospheric12 DecemberLaunch failure
Apogee: 64 kilometres (40 mi)[6]:236[29]
12 December
09:10		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy12 DecemberSuccessful
Apogee: 77 kilometres (48 mi)[11]
12 December
18:26		 Aerobee RTV-A-1 Holloman LC-A ARDC
ARDC Suborbital Aeronomy12 DecemberSuccessful
Apogee: 108.2 kilometres (67.2 mi)[11]
19 December
18:52		 Aerobee XASR-SC-2 White Sands LC-35 US Army
USASC Suborbital Aeronomy19 DecemberSuccessful
Apogee: 81.9 kilometres (50.9 mi)[11]
20 December R-2 Kapustin Yar OKB-1
OKB-1 Suborbital Missile test20 DecemberPartial failure
Final flight of 12 mission prototype series; missed target[32]

Suborbital launch summary (1945–1950)

By country
Launches by country
Country Launches Successes Failures Partial
failures
 United Kingdom 3201
 United States 12084342
 Soviet Union 6438719

By rocket
16
32
48
64
80
Launches by rocket
Rocket Country Launches Successes Failures Partial
failures		 Remarks
V-2  United Kingdom3201Maiden flight, retired
V-2 / Hermes II  United States5940181Maiden flight, first US spaceflight
Bumper  United States8350Maiden flight, retired
Viking (first model)  United States6231Maiden flight
Aerobee RTV-N-8  United States161240Maiden flight, retired
Aerobee RTV-N-10  United States5410Maiden flight
Aerobee XASR-SC-1  United States9900Maiden flight
Aerobee XASR-SC-2  United States8710Maiden flight
Aerobee RTV-A-1  United States9720Maiden flight
V-2  Soviet Union11443Maiden flight, retired
R-1  Soviet Union302730Maiden flight, first Soviet spaceflight
R-1A  Soviet Union6402Maiden flight, retired
R-2E  Soviet Union5302Maiden flight, retired
R-2  Soviet Union120012Maiden flight

See also

References
Generic references:
 Spaceflight portal
  • Bergin, Chris. "NASASpaceFlight.com".
  • Clark, Stephen. "Spaceflight Now".
  • Kelso, T.S. "Satellite Catalog (SATCAT)". CelesTrak.
  • Krebs, Gunter. "Chronology of Space Launches".
  • Kyle, Ed. "Space Launch Report".
  • McDowell, Jonathan. "Jonathan's Space Report".
  • Pietrobon, Steven. "Steven Pietrobon's Space Archive".
  • Wade, Mark. "Encyclopedia Astronautica".
  • Webb, Brian. "Southwest Space Archive".
  • Zak, Anatoly. "Russian Space Web".
  • "ISS Calendar". Spaceflight 101.
  • "NSSDCA Master Catalog". NASA Space Science Data Coordinated Archive. NASA Goddard Space Flight Center.
  • "Space Calendar". NASA Jet Propulsion Laboratory.
  • "Space Information Center". JAXA.
  • "Хроника освоения космоса" [Chronicle of space exploration]. CosmoWorld (in Russian).

Footnotes
  1. Paul Voosen (24 July 2018). "Outer space may have just gotten a bit closer". Science. doi:10.1126/science.aau8822. Archived from the original on 11 November 2020. Retrieved 1 April 2019.
  2. Louis de Gouyon Matignon. "Peenemünde and the German V-2 rockets". Space Legal Issues. Archived from the original on 27 November 2020. Retrieved 13 December 2020.
  3. Dieter K. Kuzel (1962). Peenemünde to Canaveral. United States of America: Prentice Hall.
  4. Willy Ley (June 1951). Rockets, Missiles, and Space Travel. Dominion of Canada: Viking Press. OCLC 716327624.
  5. Boris Chertok (June 2006). Rockets and People, Volume II: Creating a Rocket Industry. Washington D.C.: NASA. OCLC 946818748.
  6. Milton W. Rosen (1955). The Viking Rocket Story. New York: Harper & Brothers. OCLC 317524549.
  7. George Ludwig (2011). Opening Space Research. Washington D.C.: geopress. OCLC 845256256.
  8. Beischer, DE; Fregly, AR (1962). "Animals and man in space. A chronology and annotated bibliography through the year 1960" (PDF). US Naval School of Aviation Medicine. ONR TR ACR-64 (AD0272581). Archived from the original (PDF) on 24 March 2016. Retrieved 14 June 2011.
  9. Asif A. Siddiqi. Challenge to Apollo: The Soviet Union and the Space Race, 1945–1974 (pdf). Washington D.C.: NASA. OCLC 1001823253. Archived (PDF) from the original on 16 September 2008. Retrieved 18 December 2020.
  10. Mark Wade. "R-1A". Encyclopedia Astronautica. Archived from the original on 21 January 2020. Retrieved 6 December 2020.
  11. Mark Wade. "Aerobee". Encyclopedia Astronautica. Archived from the original on 7 August 2020. Retrieved 8 December 2020.
  12. Mark Wade. "V-2". Encyclopedia Astronautica. Archived from the original on 6 December 2020. Retrieved 7 December 2020.
  13. Report on operation 'Backfire' Recording and analysis of the trajectory. Vol. 5. Ministry of Supply. January 1946. pp. 9–11.
  14. L. D. White (September 1952). Final Report, Project Hermes V-2 Missile Program. Schnectady, New York: Guided Missile Department, Aeronautic and Ordnance Systems Division, Defense Products Group, General Electric. p. Table I.
  15. Gregory P. Kennedy (2009). The Rockets and Missiles of White Sands Proving Ground. Atglen, PA.: Schiffer Publishing. p. 159. ISBN 978-0-7643-3251-7.
  16. Charles P. Smith, Jr. (February 1958). Naval Research Laboratory Report No. 4276 Upper Atmospheric Research Report Number XXI, Summary of Upper Atmosphere Rocket Research Firings. Washington D.C.: Naval Research Laboratory. Archived from the original (pdf) on 11 March 2016. Retrieved 9 March 2016.
  17. H. E. Newell, Jr.; J. W. Siry (30 December 1946). Naval Research Laboratory Report No. R-3030: Upper Atmospheric Research Report Number II (PDF). Washington D.C.: Naval Research Laboratory. pp. 11, 91. Archived from the original (pdf) on 6 September 2017.
  18. H. E. Newell, Jr.; J. W. Siry (30 December 1946). Naval Research Laboratory Report No. R-3030: Upper Atmospheric Research Report Number II (PDF). Washington D.C.: Naval Research Laboratory. p. Table I. Archived from the original (pdf) on 6 September 2017.
  19. F. Zwicky (February 1947). "The First Night–Firing of a V-2 Rocket in the United States" (pdf). Publications of the Astronomical Society of the Pacific. 59 (346): 32. Archived from the original on 20 June 2021. Retrieved 2 March 2021.
  20. Gregory P. Kennedy. "Chronology of Human Space Exploration: Part 1: 1900 – 1950". I-Spy Space. Archived from the original on 9 February 2012. Retrieved 20 February 2008.
  21. Michael J. Neufeld (2007). Von Braun, Dreamer of Space, Engineer of War. New York: Vintage Books. p. 239. ISBN 978-0-307-38937-4.
  22. Gregory P. Kennedy (2009). The Rockets and Missiles of White Sands Proving Ground. Atglen, PA.: Schiffer Publishing. p. 57. ISBN 978-0-7643-3251-7.
  23. Mark Wade. "Kapustin Yar V-2". Encyclopedia Astronautica. Archived from the original on 22 February 2020. Retrieved 7 December 2020.
  24. Mark Wade. "1947". Encyclopedia Astronautica. Archived from the original on 8 November 2013. Retrieved 3 March 2016.
  25. James A. Van Allen & John W. Townsend, Jr. (1959). "Chapter 4:The Aerobee Rocket". In H. E. Newell (ed.). Sounding Rockets. McGraw-Hill Book Company. pp. 61–62.
  26. Mark Wade. "BUMPER-WAC". Encyclopedia Astronautica. Archived from the original on 21 January 2020. Retrieved 13 December 2020.
  27. Mark Wade. "R-1". Encyclopedia Astronautica. Archived from the original on 7 June 2020. Retrieved 6 December 2020.
  28. Mark Wade. "White Sands LC33". Encyclopedia Astronautica. Archived from the original on 5 May 2021. Retrieved 7 December 2020.
  29. Mark Wade. "Viking Sounding Rocket". Encyclopedia Astronautica. Archived from the original on 8 July 2020. Retrieved 7 January 2021.
  30. Mark Wade. "V-2 Chronology". Encyclopedia Astronautica. Archived from the original on 20 September 2012. Retrieved 14 September 2012.
  31. Mark Wade. "R-2E". Encyclopedia Astronautica. Archived from the original on 1 November 2020. Retrieved 7 December 2020.
  32. Mark Wade. "R-2". Encyclopedia Astronautica. Archived from the original on 1 November 2020. Retrieved 7 December 2020.
  33. Michael J. Neufeld (2007). Von Braun, Dreamer of Space, Engineer of War. New York: Vintage Books. p. 249. ISBN 978-0-307-38937-4.


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