• Karachentsev I.D., D'Onghia E., Jin Z., et al.Identification of Intermediate-mass Black Hole Candidates among a Sample of Sd Galaxies. 2024,ApJ,Vol.971,is.2,p.123 (20 pp.). 2024ApJ...971..123D
  • Karachentsev I.D., Zhang C.P., Kaisin S.S., et al.Addition of the Local Volume sample of galaxies from the FAST HI survey. 2024,A&A,Vol.684L,p.24 (9 pp.). 2024A&A...684L..24K
  • D'Orazi V., Baratella M., Sheminova V.A.,Abundances of neutron-capture elements in selected solar- type stars. 2024,A&A,Vol.688,p.A227 (18 pp.). 2024A&A...688A.227S
  • Tautvaišienė G., Pilyugin L.S.,Central oxygen abundances in the spiral galaxies of the MaNGA survey: Galaxies with central starbursts. 2024,A&A,Vol.689,p.A269 (14 pp.). 2024A&A...689A.269P
  • Khan F.M., Mayer L., Javed F., et al.The Potential for Long-lived Intermediate-mass Black Hole Binaries in the Lowest Density Dwarf Galaxies. 2024,ApJ,Vol.976,is.1,p.22 (9 pp.). 2024ApJ...976...22K
  • O'Sullivan E., Schellenberger G., Rajpurohit K., et al.A Deep Dive into the NGC 741 Galaxy Group: Insights into a Spectacular Head-tail Radio Galaxy from VLA, MeerKAT, uGMRT, and LOFAR. 2024,ApJ,Vol.976,is.1,p.64 (21 pp.). 2024ApJ...976...64R

 

 

 

 

Random photo

gao_fb_typkiev.jpg

Astrographs

2019-07-30

The Tepfer–Steingel double astrograph

The Tepfer double astrograph (D=40 cm, F=550 cm) one of the first instruments installed at the Golosiiv site (1946). It is used for studying stellar proper motions, structure of the Galaxy, positions of the Solar System bodies, and Moon study. Observations are carried out in the International B, V system, down to 15m. A new dome for the double long-focus astrograph was completed in 1991.

The Tepfer–Steingel double astrograph

The Zeiss double wide-angle astrograph

The Zeiss double wide-angle astrograph (D = 40 cm, F = 200 cm) was mounted in 1975. The limiting photographic magnitude is 16m. Planets, asteroids, and comets are observed with this instrument for compiling different catalogues. Plates obtained with this telescope are used for the Northern Sky Survey (FON).

The Zeiss double wide-angle astrograph

instruments

2019-07-30

Observation sites

The Observatory was planned as an astrometric institution, and its first telescopes were the Wanschaff vertical circle (D=19 cm, F=2.5 m) and the Tepfer–Steingel double long-focus astrograph (D=40 cm, F=5.5 m). The Wanschaff vertical circle was used for determining absolute declination of stars and planets. Most observations are made by night, but the Sun, Venus, Mercury, and few bright stars are observed in the daytime. Observations made with this instrument served as the basis for six catalogues.

Over the years, the field of investigations widened, and new telescopes were installed: the small solar telescope with a spectrograph (1954), the chromospheric telescope (1957), the AZT-2 reflector (D = 70 cm) in 1959, the horizontal solar telescope ATsU-5 (D = 44.5 cm, F = 17 m) in 1965, the Zeiss double wide-angle astrograph (D = 40 cm, F = 2 m) in 1975. The Meridian Axial Circle (1987) is used for highly precision positional observations of celestial objects.

Construction works at the Golosiiv site have gone over the course of its existence: a mechanical workshop was built in 1964, a dome for the double wide-angle astrograph was built in 1975, the main observatory building was constructed in 1976, and the construction of the fine mechanics and optics building and a new dome for the double long-focus astrograph was completed in 1991.

The observatory bases on the Maidanak Mountains (Uzbekistan), Tariha (Bolivia), and the high-altitude Observatory on the Peak of Terskol were built by the GAO's efforts. The astrophysical observatory on Terskol Peak in the Northern Caucasus (altitude 3100 m, near mountain Elbrus) was constructed in 1970−1991 by the Main Astronomical Observatory as its high-altitude observation station. From 1992 this observatory forms a part of the International Centre for Astronomical, Medical and Ecological Research (ICAMER). This Centre was created in 1992 by the National Academy of Sciences of Ukraine, the Russian Academy of Sciences and the Government of Kabardino-Balkaria. It is headed by Dr. V. K. Tarady. The equipment of the Terskol Station consists of the horizontal solar telescope ATsU-26, a specialized solar telescope SEF-1 (D=0.5 m and 0.2 m), the 60-cm reflector telescope, and the 2-meter Ritchey−Chretien coude telescope which was put into operation in 1995.

The 70 cm reflector AZT-2 The Tepfer–Steingel double astrograph Satellite Laser Ranging
The 2-m Ritchey-Chretien-Coude Telescope The Large Horizontal Solar Telescope ATsU-26 The Zeiss double wide-angle astrograph
 
The Meridian Axial Circle The Horizontal Solar Telescope ATsU-5  

Kyiv Internet Telescope


Welcome to the KIT website!

KIT (Kyiv Internet Telescope) is a joint project driven by the Main Astronomical Observatory of the National Academy of Science of Ukraine (MAO NASU) in close collaboration with the Astronomical Observatory of the Kyiv Taras Shevchenko University of Ministry of Education and Science of Ukraine (AO KNUTS MESU).

Mostly funded by the Science and Technology Center in Ukraine (STCU) and the National Academy of Science of Ukraine (NASU) with the participation of the AO KNUTS MESU, is devoted to the characterization of planets located outside our solar system (exoplanets) and to the study of comets and other small bodies in our solar system. It consists of a 35cm robotic telescope located at the Lisnyky Observational Station of the AO KNUTS MESU.

You will find on this site information about KIT. Please take the time to visit. If you have any question please feel free to contact us at the email address below.

 

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Science

Research of the stars with planets which pass apparent star disk (transiting exoplanets).

The transit method based on a detection star brightness decrease during a passing of planet in front of its disk. Observed brightness system decries when planet pass star disk and its volume depend of the relative sizes star and planet. Method allows to determine a planet radius, and orbit period and its inclination what together with method of radial velocity gives us opportunity to calculate planet mass.

 

International project “The DWARF project: Eclipsing binaries - precise clocks to discover exoplanets”

Observational campaign on the search for planets around of eclipsing binaries systems. Project include network of North hemisphere telescopes with apertures from 25 to 200 cm from more as 20 observatories involved.

Principal investigator of the project are Theodor Pribulla from Astronomical Institute Slovak Academy of Sciences Tatranska Lomnica (http://www.astro.sk/~pribulla/).

Scientific background: system brightness decries when a brighter star shade with another star. Moment of the time of the glow minima is named primary eclipse. The second eclipse has smaller amplitude when the star with a lower brightness pass behind a brighter star. It is usually can be observed too. If there is the planet in this system, stars under this planet gravity will shift relative to the mass centre of the stars-planet system and they will follow along the modified orbit. Therefore minima eclipse moments will vary constantly.

The goal of the project is the research of a displacements periodicity in these minima on a base of exact determination of the moment’s eclipse minima.

 

Study of cometary activity at large heliocentric distances

Small bodies from the outskirts of the Solar system are considered to be relatively unmodified remnants of the early stage of the solar system formation. Therefore, they can retain information about the abundance of volatile materials in comet progenitors and the local physical conditions at the stage of their origin. Being scattered in the inner region of the Solar System, some of small bodies become considerably active developing as comets at heliocentric distances larger than 4 AU.

This phenomenon cannot be explained by classical theories.There are different hypotheses considering different physical mechanisms, which can trigger physical activity at such large heliocentric distances. The monitoring of dynamically new comets, when they move far from the Sun, can reveal various patterns of the development of the cometary activity and provide data for studying the brightness evolution and dust composition of their coma. Furthermore, this is also a means to discriminate between different physical mechanisms triggering and sustaining the physical activity of comets.



KIT Team

  • Yaroslav Romanyuk
    Position: Senior Scientist Research, Main Astronomical Observatory of NASU
    Functions: Principal Investigator, Project Administrative Manager, Instrument Manager, On Site Technical Support - (exoplanets, eclipsing binaries, comets, asteroids))
    E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Valery Kleshchonok
    Position:Head of Department AO NKNUTS MESU
    Functions:Co-Investigator, Science and Software Manager - (occultation phenomena, asteroids, comets)
    E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Victoriia Krushevska
    Position: Senior Scientist Research MAO NASU
    Functions: Co-Investigator (exoplanets, eclipsing binaries)
    E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Yuliana Kuznyetsova
    Position: Research Associate MAO NASU
    Functions: Co-Investigator (exoplanets)
    E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Iryna Kulyk
    Position:Senior Scientist Research MAO NASU
    Functions: Co-Investigator (comets)
    E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Mykola Buromsky
    Position:Principal engineer AO KNUTS MESU
    Functions: Co-Investigator (occultation phenomena)
    E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

Acknowledgements

We would like to thank the following persons for the help provided during the setup of the project:

  • Oleg Svyatogorov, Victor Karbovskiy, Yuri Ivanov, Myhailo Sosonkin, Myhailo Medvedsky and all staff of the Main Astronomical Observatory of NASU who helped us with telescope development and mounting.
  • Zhanna Pishkalo, from Lisnyky Observatory for continuous support.
  • Volodymyr Reshetnyk and Andrew Simon and Ivan Hatko for test observations.
  • Sergii and Andrii Verbytsky from White Swan Co for equipment and its support.

We also give a special thanks to the whole MAO NASU and Lisnyky Observatory staff for their constant help and support!

Former Collaborators : Oleksandr Sergyeyev, Mykola Karpov, Vira Godunova, Maxym Andreev from International Center for Astronomical, Medical and Ecological Research of National Academy of Science of Ukraine ICAMER NASU), Igor Luk'yanyk, Volodymyr Reshetnyk, Vasyl Danylevsky, Vasyl Ivchenko, Viktor Lapchuk from AO KNUTS MESU, Oleg Svyatogorov, Borys Zhilyaev, Irina Verlyuk from MAO NASU - were participants of the Project “The Ukrainian synchronous Network of Internet Telescopes” (UNIT) during which KIT was developed.



Equipment

  • KIT: optical tube
    Model: Celestron 1400 XLT
    Type: Shmidt-Cassegrain
    Material: aluminium
    Diameter: 355 mm (14 inch)
    System focal ratio: F/11
    Focusing system: main mirror move
    Weight: 20.4 kg
  • The mount
    Model: WS240GT
    Type: German equatorial
    Motors: Brush Commutated DC Motors
    Speed: up to 10 deg/sec
    Pointing accuracy (with
    pointing model):
    1.7 arcmin
    Weight: 48 kg
  • Camera 1
    Model: QImaging Rolera MGi
    CCD: CCD97
    Array size: 512 x 512 pixels
    CCD type: back-illuminated
    Pixel size: 16 microns
    Pixel scale: 0.844 arcsec/pixels
    Field of view: 8.55 x 8.55 arcmin
    Full well: 240,000e- (1x1); 800,000e- (2x2, non-EM mode)
    Read-out noise: <1 e- rms in EM mode
    Readout Frequency: 10, 5MHz (EM mode); 5, 1MHz (normal mode)
    Dark current: 0.5 e-/pix/s
    Digital Output: 14 bits
    Cooling: -25°C below ambient
    Weight: 3.18 kg
  • Camera 2
    Model: SBIG ST-8XME
    CCD: KAF-1603ME
    Array size: 1530x1020 pixels (13.8 x 9.2 mm)
    Pixel size: 9 microns
    Pixel scale: 0.475 arcsec/pixels
    Field of view: 12.1x7.65 arcmin
    Full well: 100,000 electrons
    Gain: 1.5 el/ADU
    Peak QE: 85% at 650 nm
    Read-out noise: 17e. RMS electrons
    Read-out time: ~2 seconds with USB 2.0
    Dark current: 1e./pixel/sec at 0° C
    Cooling: -35°C below ambient
    Temperature stability: 0.1°C
    Weight: 0.6kg
  • The filter wheel
    Model: Own design
    Filter type: diameter 32 mm filters
    Max. filter thickness: 7 mm
    Weight: 1.3 kg (1wheel with 8 filters)
    Filters (wheel 1): Johnson/Cousins BVRcIc U
    Electronic: Controller for Filters and Autofocus
  • Software
    Operating system: Microsoft Windows XP Pro
    Observation schedule: CCENTER (own development)
    Telescope control: Telescope (own development)
    Camera control: QCam (own development)
    Filter wheel control: Filters (own development)
    Focus control: Autofocus (own development)
    Plate solving: Platesolvexp
    Standard driver: ASCOM

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Site

Lisnyky Observational Station of the AO KNUTS MESU located in the village Lisnyky, at an altitude of 143 m a.s.l. and 7 km out of South border of Kyiv. There are some 70-85 clear nights per year.

KIT Coordinates:

Latitude : 50° 17' 53 (N) 50,2970 (N)
Longtitude: 30° 31' 27 (E) 30,4978 (E)
Altitude: 143 m a.s.l.