US-A

Last updated January 04, 2025 • 3 min readFrom Wikipedia, The Free Encyclopedia

Upravlyaemy Sputnik Aktivnyy (Russian : Управляемый Спутник Активный for Controlled Active Satellite), or US-A, also known in the Western world as Radar Ocean Reconnaissance Satellite or RORSAT (GRAU index 17F16K), was a series of 33 Soviet reconnaissance satellites. Launched between 1967 and 1988 to monitor NATO and merchant vessels using radar, the satellites were powered by nuclear reactors.

Because a return signal from an ordinary target illuminated by a radar transmitter diminishes as the inverse of the fourth power of the distance, for the surveillance radar to work effectively, US-A satellites had to be placed in low Earth orbit. Had they used large solar panels for power, the orbit would have rapidly decayed due to drag through the upper atmosphere. Further, the satellite would have been useless in the shadow of Earth. Hence the majority of the satellites carried type BES-5 nuclear reactors fuelled by uranium-235. Normally the nuclear reactor cores were ejected into high orbit (a so-called "disposal orbit") at the end of the mission, but there were several failure incidents, some of which resulted in radioactive material re-entering the Earth's atmosphere.

The US-A programme was responsible for orbiting a total of 33 nuclear reactors, 31 of them BES-5 types with a capacity of providing about two kilowatts of power for the radar unit. In addition, in 1987 the Soviets launched two larger TOPAZ nuclear reactors (six kilowatts) in Kosmos satellites (Kosmos 1818 and Kosmos 1867) which were each capable of operating for six months.^[1] The higher-orbiting TOPAZ-containing satellites were the major source of orbital contamination for satellites that sensed gamma-rays for astronomical and security purposes, as radioisotope thermoelectric generators (RTGs) do not generate significant gamma radiation as compared with unshielded satellite fission reactors, and all of the BES-5-containing spacecraft orbited too low to cause positron pollution in the magnetosphere.^[2]

The last US-A satellite was launched 14 March 1988.

Incidents

Launch failure, 25 April 1973. Launch failed and the reactor fell into the Pacific Ocean north of Japan. Radiation was detected by US air sampling airplanes.
Kosmos 367 (04564 / 1970-079A), 3 October 1970, failed 110 hours after launch, moved to higher orbit.^[3]^: 10
Kosmos 954. The satellite failed to boost into a nuclear-safe storage orbit as planned. Nuclear materials re-entered the Earth's atmosphere on 24 January 1978 and left a trail of radioactive pollution over an estimated 124,000 square kilometres of Canada's Northwest Territories.
Kosmos 1402. Failed to boost into storage orbit in late 1982. The reactor core was separated from the remainder of the spacecraft and was the last piece of the satellite to return to Earth, landing in the South Atlantic Ocean on 7 February 1983.
Kosmos 1900. The primary system failed to eject the reactor core into storage orbit, but the backup managed to push it into an orbit 80 km (50 mi) below its intended altitude.^[4]^[3]^: 56, 58

Other concerns

Although most nuclear cores were successfully ejected into higher orbits, their orbits will still eventually decay.

US-A satellites were a major source of space debris in low Earth orbit. The debris is created two ways:

During 16 reactor core ejections, approximately 128 kg of NaK-78 (a fusible alloy eutectic of 22% and 78% w/w sodium and potassium, respectively) escaped from the primary coolant systems of the BES-5 reactors. The smaller droplets have already decayed/reentered, but larger droplets (up to 5.5 cm in diameter) are still in orbit. Since the metal coolant was exposed to neutron radiation, it contains some radioactive argon-39, with a half-life of 269 years. There is no risk of surface contamination, as the droplets will burn up completely in the upper atmosphere on re-entry and the argon, a chemically inert gas, will dissipate. The major risk is impact with operational satellites.^[5]

An additional mechanism is through the impact of space debris hitting intact contained coolant loops. A number of these old satellites are punctured by orbiting space debris—calculated to be 8 percent over any 50-year period—and release their remaining NaK coolant into space. The coolant self-forms into frozen droplets of solid sodium-potassium of up to around several centimeters in size,^[6] and these solid objects then become a significant source of space debris themselves.^[7]

List of US-A satellites

There were 38 Rorsat satellite launches from Baikonur, all with reported mass of 3,800 kg.^[8]

Rorsat satellite launches
Launch Date	Satellite Name	Launch Vehicle	Perigee (km)	Apogee (km)	Inclination (deg)	Period (min)
1968 March 22	Cosmos 209	Tsyklon	876	927	65.30	103.00
1969 January 25	US-A Mass Model	Tsyklon	-	100	-	-
1970 October 3	Cosmos 367	Tsyklon 2	915	1,022	65.30	104.50
1971 April 1	Cosmos 402	Tsyklon 2	965	1,011	65.00	104.90
1971 December 25	Cosmos 469	Tsyklon 2	948	1,006	64.50	104.60
1972 August 21	Cosmos 516	Tsyklon 2	906	1,038	64.80	104.50
1973 April 25	failure	Tsyklon 2	-	-	-	-
1973 December 27	Cosmos 626	Tsyklon 2	907	982	65.40	103.90
1974 May 15	Cosmos 651	Tsyklon 2	890	946	65.00	103.40
1974 May 17	Cosmos 654	Tsyklon 2	924	1,006	64.90	104.40
1975 April 2	Cosmos 723	Tsyklon 2	899	961	64.70	103.60
1975 April 7	Cosmos 724	Tsyklon 2	852	943	65.60	102.90
1975 December 12	Cosmos 785	Tsyklon 2	907	1,004	65.10	104.20
1976 October 17	Cosmos 860	Tsyklon 2	923	995	64.70	104.30
1976 October 21	Cosmos 861	Tsyklon 2	928	987	64.90	104.20
1977 September 16	Cosmos 952	Tsyklon 2	911	990	64.90	104.10
1977 September 18	Cosmos 954	Tsyklon 2	251	265	65.00	89.70
1980 April 29	Cosmos 1176	Tsyklon 2	873	962	64.80	103.40
1981 April 21	Cosmos 1266	Tsyklon 2	911	941	64.80	103.60
1981 August 24	Cosmos 1299	Tsyklon 2	926	962	65.10	103.90
1981 March 5	Cosmos 1249	Tsyklon 2	904	976	65.00	103.90
1982 August 30	Cosmos 1402	Tsyklon 2	250	266	65.00	89.60
1982 June 1	Cosmos 1372	Tsyklon 2	919	966	64.90	103.90
1982 May 14	Cosmos 1365	Tsyklon 2	881	979	65.10	103.60
1982 October 2	Cosmos 1412	Tsyklon 2	886	998	64.80	103.90
1984 June 29	Cosmos 1579	Tsyklon 2	914	970	65.10	103.90
1984 October 31	Cosmos 1607	Tsyklon 2	908	994	65.00	104.10
1985 August 1	Cosmos 1670	Tsyklon 2	893	1,007	64.90	104.10
1985 August 23	Cosmos 1677	Tsyklon 2	880	1,001	64.70	103.90
1986 August 20	Cosmos 1771	Tsyklon 2	909	1,000	65.00	104.20
1986 March 21	Cosmos 1736	Tsyklon 2	936	995	65.00	104.40
1987 December 12	Cosmos 1900	Tsyklon 2	696	735	66.10	99.10
1987 June 18	Cosmos 1860	Tsyklon 2	900	992	65.00	104.00
1988 March 14	Cosmos 1932	Tsyklon 2	920	1,008	65.10	104.40

Related Research Articles

A magnetoplasmadynamic (MPD) thruster (MPDT) is a form of electrically powered spacecraft propulsion which uses the Lorentz force to generate thrust. It is sometimes referred to as Lorentz Force Accelerator (LFA) or MPD arcjet.

A nuclear meltdown is a severe nuclear reactor accident that results in core damage from overheating. The term nuclear meltdown is not officially defined by the International Atomic Energy Agency or by the United States Nuclear Regulatory Commission. It has been defined to mean the accidental melting of the core of a nuclear reactor, however, and is in common usage a reference to the core's either complete or partial collapse.

<span class="mw-page-title-main">Anti-satellite weapon</span> Kinetic energy device designed to destroy satellites in orbit

Anti-satellite weapons (ASAT) are space weapons designed to incapacitate or destroy satellites for strategic or tactical purposes. Although no ASAT system has yet been utilized in warfare, a few countries have successfully shot down their own satellites to demonstrate their ASAT capabilities in a show of force. ASATs have also been used to remove decommissioned satellites.

A radioisotope thermoelectric generator, sometimes referred to as a radioisotope power system (RPS), is a type of nuclear battery that uses an array of thermocouples to convert the heat released by the decay of a suitable radioactive material into electricity by the Seebeck effect. This type of generator has no moving parts and is ideal for deployment in remote and harsh environments for extended periods with no risk of parts wearing out or malfunctioning.

Space debris are defunct human-made objects in space – principally in Earth orbit – which no longer serve a useful function. These include derelict spacecraft, mission-related debris, and particularly numerous in-Earth orbit, fragmentation debris from the breakup of derelict rocket bodies and spacecraft. In addition to derelict human-made objects left in orbit, space debris includes fragments from disintegration, erosion, or collisions; solidified liquids expelled from spacecraft; unburned particles from solid rocket motors; and even paint flecks. Space debris represents a risk to spacecraft.

Sodium–potassium alloy, colloquially called NaK, is an alloy of the alkali metals sodium and potassium that is normally liquid at room temperature. Various commercial grades are available. NaK is highly reactive with water and may catch fire when exposed to air, so must be handled with special precautions.

Kosmos is a designation given to many satellites operated by the Soviet Union and subsequently Russia. Kosmos 1, the first spacecraft to be given a Kosmos designation, was launched on 16 March 1962.

Kosmos 954 was a reconnaissance satellite launched by the Soviet Union in 1977. A malfunction prevented safe separation of its onboard nuclear reactor; when the satellite reentered the Earth's atmosphere the following year, it scattered radioactive debris over northern Canada, some of the debris landing in the Great Slave Lake next to Fort Resolution, NWT.

SNAP-10A was a US experimental nuclear powered satellite launched into space in 1965 as part of the SNAPSHOT program. The test marked both the world's first operation of a nuclear reactor in orbit, and the first operation of an ion thruster system in orbit. It is the only fission reactor power system launched into space by the United States. The reactor stopped working after just 43 days due to a non-nuclear electrical component failure. The Systems Nuclear Auxiliary Power Program reactor was specifically developed for satellite use in the 1950s and early 1960s under the supervision of the U.S. Atomic Energy Commission.

The Systems Nuclear Auxiliary POWER (SNAP) program was a program of experimental radioisotope thermoelectric generators (RTGs) and space nuclear reactors flown during the 1960s by NASA.

The TOPAZ nuclear reactor is a lightweight nuclear reactor developed for long term space use by the Soviet Union. Cooled by liquid metal, it uses a high-temperature moderator containing hydrogen and highly enriched fuel and produces electricity using a thermionic converter.

USA-193, also known as NRO Launch 21, was a United States military reconnaissance satellite launched on 14 December 2006. It was the first launch conducted by the United Launch Alliance (ULA). Owned by the National Reconnaissance Office (NRO), the craft's precise function and purpose were classified. On 21 February 2008, it was destroyed as a result of Operation Burnt Frost.

The Romashka reactor was a Soviet experimental nuclear reactor. It began operation in 1964, and was developed by the Kurchatov Institute of Atomic Energy. The reactor used direct thermoelectric conversion to create electricity, rather than heating water to drive a turbine. It is thus similar to a radioisotope thermoelectric generator, but higher power.

Kosmos 1818 was a nuclear powered Soviet surveillance satellite in the RORSAT program, which monitored NATO vessels using radar. Kosmos 1818 was the first satellite to use the TOPAZ-1 fission reactor. In July 2008, the satellite was damaged, and leaked a trail of sodium coolant.

Kosmos 1867 was a nuclear powered radar ocean reconnaissance satellite (RORSAT) that was launched by the Soviet Union on July 10, 1987. It was put into an orbit of about 800 km (500 mi). Its mission was to monitor the oceans for naval and merchant vessels, and had a mission life of about eleven months.

Kosmos 1402 was a Soviet spy satellite that malfunctioned, resulting in the uncontrolled re-entry of its nuclear reactor and its radioactive uranium fuel. Kosmos 1402 was launched on August 30, 1982, and re-entered the atmosphere on 23 January 1983. The fission reactor entered a few days later; on 7 February 1983.

Nuclear power in space is the use of nuclear power in outer space, typically either small fission systems or radioactive decay for electricity or heat. Another use is for scientific observation, as in a Mössbauer spectrometer. The most common type is a radioisotope thermoelectric generator, which has been used on many space probes and on crewed lunar missions. Small fission reactors for Earth observation satellites, such as the TOPAZ nuclear reactor, have also been flown. A radioisotope heater unit is powered by radioactive decay and can keep components from becoming too cold to function, potentially over a span of decades.

BES-5, also known as Bouk or Buk, was a Soviet thermoelectric generator that was used to power 31 satellites in the US-A (RORSAT) project. The heat source was a uranium 235 fast fission nuclear reactor (FNR).

Kosmos 2421 was a Russian reconnaissance satellite launched in 2006, but began fragmenting in early 2008. It also had the Konus-A science payload designed by Ioffe Institute to detect gamma-ray bursts. Three separate fragmentation events produced about 500 pieces of trackable debris. About half of those had already re-entered Earth's atmosphere by the fall of 2008.

References

Wiedemann, C.; Oswald, M.; Stabroth, S.; Klinkrad, H.; Vörsmann, P. (2005). "Modeling of RORSAT NaK droplets for the MASTER 2005 upgrade". Acta Astronautica. 57 (2–8): 478–489. Bibcode:2005AcAau..57..478W. doi:10.1016/j.actaastro.2005.03.014.

↑ Regina Hagen (8 November 1998). "Summary of space-based nuclear power systems" . Retrieved 19 March 2023.
↑ positron pollution from TOPAZ
1 2 David. S.F. Portree; Joseph P. Loftus Jr. (January 1999). Orbital Debris: A Chronology (PDF) (Report). NASA. Retrieved 19 March 2023.
↑ "Spy Satellite Reactor Now in a Safe Orbit, Its Trackers Report". The New York Times. 5 October 1988. Retrieved 19 March 2023.
↑ Wiedemann, C.; Oswald, M.; Stabroth, S.; Klinkrad, H.; Vörsmann, P. (2005). "Size distribution of NaK droplets released during RORSAT reactor core ejection". Advances in Space Research. 35 (7): 1290–1295. Bibcode:2005AdSpR..35.1290W. doi:10.1016/j.asr.2005.05.056.
↑ C. Wiedemann et al, "Size distribution of NaK droplets for MASTER-2009", Proceedings of the 5th European Conference on Space Debris, 30 March-2 April 2009, (ESA SP-672, July 2009).
↑ A. Rossi et al, "Effects of the RORSAT NaK Drops on the Long Term Evolution of the Space Debris Population", University of Pisa, 1997.
↑ "US-A". astronautix.com. Retrieved 31 October 2023.

External links

Encyclopedia Astronautica article on the US-A RORSAT programme.
The US-A program and radio observations thereof
Leonard David (29 March 2004). "Havoc in the Heavens: Soviet-Era Satellite's Leaky Reactor's Lethal Legacy". Space.com. Archived from the original on 5 April 2004.
Leonard David (15 January 2009). "Old Nuclear-Powered Soviet Satellite Acts Up". Space.com.
Science & Global Security, 1989, Vol. 1. Background on space nuclear power. scienceandglobalsecurity.org

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Regina Hagen (8 November 1998). "Summary of space-based nuclear power systems" . Retrieved 19 March 2023.

[2] sitron pollution from TOPAZ

[portree-3] 1 2 David. S.F. Portree; Joseph P. Loftus Jr. (January 1999). Orbital Debris: A Chronology (PDF) (Report). NASA. Retrieved 19 March 2023.

[4] "Spy Satellite Reactor Now in a Safe Orbit, Its Trackers Report". The New York Times. 5 October 1988. Retrieved 19 March 2023.

[wiedemann2005-5] Wiedemann, C.; Oswald, M.; Stabroth, S.; Klinkrad, H.; Vörsmann, P. (2005). "Size distribution of NaK droplets released during RORSAT reactor core ejection". Advances in Space Research. 35 (7): 1290–1295. Bibcode:2005AdSpR..35.1290W. doi:10.1016/j.asr.2005.05.056.

[wiedemann2009-6] C. Wiedemann et al, "Size distribution of NaK droplets for MASTER-2009", Proceedings of the 5th European Conference on Space Debris, 30 March-2 April 2009, (ESA SP-672, July 2009).

[rossi2009-7] A. Rossi et al, "Effects of the RORSAT NaK Drops on the Long Term Evolution of the Space Debris Population", University of Pisa, 1997.

[8] "US-A". astronautix.com. Retrieved 31 October 2023.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]