Mars 1, also known as 1962 Beta Nu 1, Mars 2MV-4 and Sputnik 23, was an automatic interplanetary station launched in the direction of Mars on November 1, 1962,[3][4] the first of the SovietMars probe program, with the intent of flying by the planet at a distance of about 11,000 km (6,800 mi). It was designed to image the surface and send back data on cosmic radiation, micrometeoroid impacts and Mars' magnetic field, radiation environment, atmospheric structure, and possible organic compounds.[3][4]
After leaving Earth orbit, the spacecraft and the Molniya booster's fourth stage separated and the solar panels were deployed. Early telemetry indicated that there was a leak in one of the gas valves in the orientation system so the spacecraft was transferred to gyroscopic stabilization. It made sixty-one radio transmissions, initially at two-day intervals and later at five days, containing a large amount of interplanetary data.[3]
On March 21, 1963, when the spacecraft was at a distance of 106,760,000 km (66,340,000 mi) from Earth on its way to Mars, communications ceased, probably due to failure of the spacecraft's antenna orientation system.[3][4] Mars 1's closest approach to Mars probably occurred on June 19, 1963 at a distance of approximately 193,000 km (120,000 mi), after which the spacecraft entered an orbit around the Sun.[4]
Spacecraft design
Mars 1 was a modified Venera-type spacecraft in the shape of a cylinder 3.3 m (11 ft) long and 1 m (3.3 ft) in diameter.[3][4] The spacecraft measured 4 m (13 ft) across with the solar panels and radiators deployed. The cylinder was divided into two compartments. The upper 2.7 m (8.9 ft), the orbital module, contained guidance and on-board propulsion systems. The experiment module, containing the scientific instrumentation, comprised the bottom 0.6 m (2.0 ft) of the cylinder. A 1.7 m (5.6 ft) parabolic high gain antenna was used for communication, along with an omnidirectional antenna and a semi-directional antenna. Power was supplied by two solar panel wings with a total area of 2.6 m2 (28 sq ft) affixed to opposite sides of the spacecraft. Power was stored in a 42 ampere-hour cadmium-nickel battery.[4]
Mars 1 was equipped with three primary radio systems operating at wavelengths of 1.6 meters, 32 centimeters, and in the centimeter range (5 and 8 centimeters).[6] The 32-centimeter wavelength transmitter, situated in the orbital module,[7] utilized a high-gain antenna, primarily transmitting on 922.76 MHz. It was supplemented by the 1.6-meter wavelength transmitter, linked with omnidirectional antennae on the solar panels, which operated on 183.6 MHz for downlink and likely near 102 MHz for uplink, serving both for telemetry and as a backup communication system in case of orientation system failure.[6]
For detailed observations, the 8-centimeter wavelength transmitter in the experiment module was dedicated to transmitting television images, utilizing a signal coherent with the main 922.76 MHz link but at a higher frequency of 3691.04 MHz.[6] Additionally, an impulse transmitter operating in the 5-centimeter band (around 5840-5890 MHz range) was also housed in the experiment module.[7] This system, characterized by impulse modulation, was designed to transmit image data at approximately 90 pixels/sec using pulse-position modulation, with an average power consumption of 50 watts and peak power of 25 kilowatts per pulse.[6]
The Mars 1 station was initially programmed for automatic data transmission every two days, later adjusted to every five days post December 13. Ground commands could also trigger transmissions from the station as required.[7]
Temperature control was achieved using a binary gas–liquid system and hemispherical radiators mounted on the ends of the solar panels. The craft carried various scientific instruments including a magnetometer probe, television photographic equipment, a spectroreflexometer, radiation sensors (gas-discharge and scintillation counters), a spectrograph to study ozone absorption bands, and a micrometeoroid instrument.[3][4]
Scientific results
The probe recorded one micrometeorite strike every two minutes at altitudes ranging from 6,000 to 40,000 km (3,700 to 24,900 mi) from Earth's surface due to the Taurids meteor shower, and also recorded similar densities at distances from 20 to 40 million kilometres (12,000,000 to 25,000,000 mi) from Earth.[3][4]
Magnetic field intensities of 3–4 nanoteslas (nT, also known as gammas) with peaks as high as 6–9 nT were measured in interplanetary space.
The radiation zones around Earth were detected,[8][9] and their magnitude confirmed.[4]
Designation
This spacecraft is also referenced as Sputnik 23 and Mars 2MV-4. It was originally designated Sputnik 30 in the U.S. Naval Space Command Satellite Situation Summary.
^ abcdefghiMihos, Chris (January 11, 2006). "Mars (1960-1974): Mars 1". Department of Astronomy, Case Western Reserve University. Archived from the original on October 13, 2013. Retrieved January 26, 2014.
Payloads are separated by bullets ( · ), launches by pipes ( | ). Crewed flights are indicated in underline. Uncatalogued launch failures are listed in italics. Payloads deployed from other spacecraft are denoted in (brackets).
Missions are ordered by launch date. Sign † indicates failure en route or before intended mission data returned. ‡ indicates use of the planet as a gravity assist en route to another destination.