Mikhailo Lomonosov (satellite)

Mikhailo Lomonosov (MVL-300)
	A model of the Mikhailo Lomonosov
Mission type	Astronomy
Operator	MSU
COSPAR ID	2016-026A
SATCAT no.	41464
Website	lomonosov.sinp.msu.ru
Mission duration	Planned: 3 years
Spacecraft properties
Manufacturer	VNIIEM
Launch mass	620 kg (1,370 lb)
Payload mass	170 kg (370 lb)
Power	~300 W
Start of mission
Launch date	28 April 2016, 02:01 UTC
Rocket	Soyuz-2.1a/Volga
Launch site	Vostochny Site 1S
Contractor	Roscosmos
End of mission
Deactivated	14 January 2019
Decay date	16 December 2023
Orbital parameters
Reference system	Geocentric
Regime	Sun-synchronous
Semi-major axis	6,856 kilometers (4,260 mi)
Perigee altitude	478.2 km (297.1 mi)
Apogee altitude	492.9 km (306.3 mi)
Inclination	97.3 degrees
Period	94.2 minutes
TUS
Instruments
TUS	Orbital ultraviolet telescope (300–400 nm)
BDRG	X-ray and gamma radiation detector
UFFO	UV-optic telescope and X-ray camera
ShOK	Wide-angle optical cameras
DEPRON	Electron, proton, and neutron dosimeter
ELFIN-L	Charged particles detector
IMISS-1	Microelectromechanical inertial measuring unit
BI	Information unit

Mikhailo Lomonosov (MVL-300, or Mikhailo, or more commonly Lomonosov; MVL stands for Mikhail Vasilyevich Lomonosov^[4]) was an astronomical satellite operated by Moscow State University (MSU) named after Mikhail Lomonosov.^[5]

Mission

The objective of the mission was the observation of gamma-ray bursts, high-energy cosmic rays and transient phenomena in the Earth's upper atmosphere.^[5]

Launch

The mission launch was initially planned for 2011 when 300 years since the birthday of Mikhail Lomonosov was celebrated.^[6] After several postponements the mission was finally launched on 28 April 2016 from the Vostochny Cosmodrome by the Soyuz 2.1a launch vehicle, on the first launch from new cosmodrome.^[7]

Scientific payload

The spacecraft is equipped with seven scientific instruments:^[4]^[1]

Tracking Ultraviolet Set Up system (TUS) was designed to measure fluorescence light radiated by EAS (Extensive Air Showers) of Ultra High Energy Cosmic Rays (UHECR) in the Earth atmosphere as well as for transients' studies within UV-range. This was the first space based instrument dedicated to these phenomena. The TUS-project started in 2001.^[8]
Block for X-ray and gamma-radiation detection (BDRG) is intended for detecting and monitoring gamma-ray bursts and for producing a trigger signal for ShOK cameras (see below);
UFFO consists of X-ray and 10 cm UV telescopes intended for studying gamma-ray bursts;
Optic cameras of super-wide field of vision (ShOK) is a pair of wide-field optical cameras, which main purpose is a prompt detection of the optical radiation of gamma-ray bursts after receiving trigger signals from BDRG;
Dosimeter of Electrons, PROtons and Neutrons (DEPRON) measures absorbed doses and spectra of electrons, protons, neutrons and heavy nuclei;
Electron Loss and Fields Investigator for Lomonosov (ELFIN-L) comprises the Energetic Particle Detector for Electrons (EPDE), Energetic Proton Detector for Ions (EPDI) and Flux Gate Magnetometer (FGM). Its main purposes is to study energetic particles in the Earth magnetosphere;
IMISS-1 is a device intended to test microelectromechanical inertial modules.

End of mission

The TUS-telescope aboard Lomonosov stopped data collection in late 2017.^[8]

On June 30, 2018, it was published that the Lomonosov-satellite had suffered a malfunction in its data transmission system. Attempts to fix the problem were underway, but fixing the problem had so far been unsuccessful.^[9]

As of 14 January 2019, the problems had not been solved and all the scientific equipment of the satellite were powered off. The recovery attempts continued (some systems of the satellite were responsive, the problem was with scientific payload systems). Before succumbing to these difficulties, the satellite had worked for one and a half years for its intended purpose. With the failure of the Lomonosov satellite and the Spektr-R end of mission on 30 May 2019, the Russian space program lost both of its scientific satellites until the launch of Spektr-RG in July 2019.

The satellite decayed from orbit on 16 December 2023.^[10]

References

^ ^a ^b ^c ^d ^e "Космический аппарат "Ломоносов"" [The spacecraft "Lomonosov"] (in Russian). VNIIEM. Retrieved 21 March 2016.
^ ^a ^b ^c ^d ^e "MVL 300 Satellite details 2016-026A NORAD 41464". N2YO. 4 May 2016. Retrieved 4 May 2016.
^ ELFIN-L consists of three components: a flux gate magnetometer (FGM), an electron particle detector (EPDE), and an ion proton detector (EPDI)
^ ^a ^b "MVL-300 (Mikhailo Lomonosov)". Gunter's Space Page. Retrieved 21 March 2016.
^ ^a ^b "Soyuz prepared for first flight from Siberian cosmodrome". Spaceflight Now. Retrieved 21 March 2016.
^ "Садовничий: спутник "Михайло Ломоносов" будет запущен в 2011 году" ["Mihailo Lomonosov" satellite to be launched in 2011]. Ria Novosti (in Russian). 26 January 2010. Retrieved 5 February 2017.
^ "Первый пуск с Восточного прошёл успешно!" [The first launch from Vostochny has been successful!] (in Russian). Roscosmos. 28 April 2016. Retrieved 2017-02-05.
^ ^a ^b Khrenov, B.A.; Garipov, G.K.; Kaznacheeva, M.A.; Klimov, P.A.; Panasyuk, M.I.; Petrov, V.L.; Sharakin, S.A.; Shirokov, A.V.; Yashin, I.V.; Zotov, M.Yu.; Grinyuk, A.A.; Grebenyuk, V.M.; Lavrova, M.V.; Tkachev, L.G.; Tkachenko, A.V.; Saprykin, O.A.; Botvinko, A.A.; Senkovsky, A.N.; Puchkov, A.E.; Bertaina, M.; Golzio, A. (2020). "An extensive-air-shower-like event registered with the TUS orbital detector". Journal of Cosmology and Astroparticle Physics. 2020 (3): 033. arXiv:1907.06028. Bibcode:2020JCAP...03..033K. doi:10.1088/1475-7516/2020/03/033. S2CID 196621883.
^ "Mikhailo Lomonosov". russianspaceweb.com.
^ "MVL 300". N2YO.com. 16 December 2023. Retrieved 15 January 2024.

External links

Mikhailo Lomonosov at Russianspaceweb.com

[vniiem-1] "Космический аппарат "Ломоносов"" [The spacecraft "Lomonosov"] (in Russian). VNIIEM. Retrieved 21 March 2016.

[n2yo-2] "MVL 300 Satellite details 2016-026A NORAD 41464". N2YO. 4 May 2016. Retrieved 4 May 2016.

[3] ELFIN-L consists of three components: a flux gate magnetometer (FGM), an electron particle detector (EPDE), and an ion proton detector (EPDI)

[Gunter-4] "MVL-300 (Mikhailo Lomonosov)". Gunter's Space Page. Retrieved 21 March 2016.

[sfn-5] "Soyuz prepared for first flight from Siberian cosmodrome". Spaceflight Now. Retrieved 21 March 2016.

[6] "Садовничий: спутник "Михайло Ломоносов" будет запущен в 2011 году" ["Mihailo Lomonosov" satellite to be launched in 2011]. Ria Novosti (in Russian). 26 January 2010. Retrieved 5 February 2017.

[7] "Первый пуск с Восточного прошёл успешно!" [The first launch from Vostochny has been successful!] (in Russian). Roscosmos. 28 April 2016. Retrieved 2017-02-05.

[1907.06028-8] Khrenov, B.A.; Garipov, G.K.; Kaznacheeva, M.A.; Klimov, P.A.; Panasyuk, M.I.; Petrov, V.L.; Sharakin, S.A.; Shirokov, A.V.; Yashin, I.V.; Zotov, M.Yu.; Grinyuk, A.A.; Grebenyuk, V.M.; Lavrova, M.V.; Tkachev, L.G.; Tkachenko, A.V.; Saprykin, O.A.; Botvinko, A.A.; Senkovsky, A.N.; Puchkov, A.E.; Bertaina, M.; Golzio, A. (2020). "An extensive-air-shower-like event registered with the TUS orbital detector". Journal of Cosmology and Astroparticle Physics. 2020 (3): 033. arXiv:1907.06028. Bibcode:2020JCAP...03..033K. doi:10.1088/1475-7516/2020/03/033. S2CID 196621883.

[9] "Mikhailo Lomonosov". russianspaceweb.com.

[10] "MVL 300". N2YO.com. 16 December 2023. Retrieved 15 January 2024.

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v t e Russian space observatories
Current	Spektr-RG (2019–present)
Past	Spektr-R (2011–2019) Mikhailo Lomonosov (2016–2019)
Planned	Spektr-UV (2030) Gamma-400 (ru) (2030) Spektr-M (2030) OZIRIS

v t e ← 2015 Orbital launches in 2016 2017 →
January	Belintersat-1 Jason-3 IRNSS-1E Intelsat 29e Eutelsat 9B
February	BeiDou M3-S USA-266 / GPS IIF -12 Kosmos 2514 / GLONASS-M 751 Kwangmyŏngsŏng-4 USA-267 / Topaz-4 Sentinel-3A ASTRO-H / Hitomi
March	SES-9 Eutelsat 65 West A IRNSS-1F Resurs-P №3 ExoMars Trace Gas Orbiter, Schiaparelli EDM Soyuz TMA-20M Cygnus CRS OA-6 (Diwata-1, Flock-2e' × 20 , Lemur-2 × 9) Kosmos 2515 / Bars-M 2L BeiDou IGSO-6 Progress MS-02
April	Shijian-10 Dragon CRS-8, BEAM Sentinel-1B, MICROSCOPE, e-st@r-II Mikhailo Lomonosov IRNSS-1G
May	JCSAT-14 Yaogan 30 Galileo FOC-10, FOC-11 Thaicom 8 Kosmos 2516 / GLONASS-M 753 Ziyuan III-02, ÑuSat 1, 2
June	Kosmos 2517 / Geo-IK-2 №12 Intelsat 31 / DLA-2 USA-268 / Orion 9 BeiDou G7 Eutelsat 117 West B, ABS-2A Cartosat-2C, M3MSat, Flock-2p × 12, SathyabamaSat, Swayam MUOS-5 Chinese next-generation crew capsule scale model Shijian 16-02
July	Soyuz MS-01 Progress MS-03 Dragon CRS-9 USA-269 / NROL-61
August	Tiantong-1 01 Gaofen-3 JCSAT-16 QUESS / Mozi / Micius USA-270 / GSSAP-3, USA-271 / GSSAP-4 Intelsat 33e, Intelsat 36 Gaofen-10†
September	AMOS-6† INSAT-3DR OSIRIS-REx Ofek-11 Tiangong-2 SkySat × 4 ScatSat-1, Alsat-1B, Alsat-2B, BlackSky Pathfinder-1, Pratham, CanX-7, PISat
October	Sky Muster II, GSAT-18 Shenzhou 11 Cygnus CRS OA-5 (Lemur-2 × 4) Soyuz MS-02
November	Himawari 9 Shijian-17 XPNAV 1 WorldView-4, CELTEE 1, Prometheus-2 × 2, AeroCube 8 × 2, U2U, RAVAN Yunhai-1 Galileo FOC 7, 12, 13, 14 Soyuz MS-03 GOES-R Tianlian I-04
December	Progress MS-04 Göktürk-1 Resourcesat-2A WGS-8 HTV-6 / Kounotori 6, (EGG, TuPOD, UBAKUSAT, AOBA-VELOX, STARS, FREEDOM, ITF, Waseda-SAT, OSNSAT, Tancredo-1, TechEDSat, Lemur-2 × 4) Fengyun 4A CYGNSS × 8 EchoStar 19 Arase / ERG TanSat, Spark × 2 Star One D1, JCSAT-15 SuperView / Gaojing-1 01, 02, Bayi Kepu 1
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).