Your search keyword '"Troianskyi, V."' showing total 17 results

1. Photometry and model of near-Earth asteroid 2021 DW1 from one apparition

Author

Kwiatkowski, T., Koleńczuk, P., Kryszczyńska, A., Oszkiewicz, D., Kamiński, K., Kamińska, M. K., Troianskyi, V., Skiff, B., Moskowitz, N., Kashuba, V., Kim, M. -J., Kim, T., Mottola, S., Santana-Ros, T., Kluwak, T., Buzzi, L., Bacci, P., Birtwhistle, P., Miles, R., and Chatelain, J.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

On 4 March 2021 at 9 UTC a 30-m in diameter near-Earth asteroid 2021 DW1 passed the Earth at a distance of 570000 km, reaching the maximum brightness of V=14.6 mag. We observed it photometrically from 2 March, when it was visible at V=16.5 mag, until 7 March (V=18.2 mag). During that time 2021 DW1 swept a 170 degrees long arc in the northern sky, spanning solar phase angles in the range from 36 to 86 degrees. This made it an excellent target for physical characterisation, including spin axis and shape derivation. Convex inversion of the asteroid lightcurves gives a sidereal period of rotation P=0.013760 +/- 0.000001 h, and two solutions for the spin axis ecliptic coordinates: (A) lambda_1=57 +/- 10, beta_1=29 +/- 10, and (B) lambda_2=67 +/- 10, beta_2=-40 +/- 10. The magnitude-phase curve can be fitted with a standard H, G function with H=24.8 +/- 0.5 mag and an assumed G=0.24. The asteroid colour indices are g-i=0.79 +/- 0.01 mag, and i-z=0.01 +/- 0.02 mag which indicates an S taxonomic class, with an average geometric albedo p_V=0.23 +/- 0.02. The asteroid effective diameter, derived from H and p_V, is D=30 +/- 10 m. It was found that the inclination of the spin axis of 2021 DW1 is not perpendicular to the orbital plane (obliquity epsilon=54 +/- 10 or epsilon=123 +/- 10). More spin axes of VSAs should be determined to check, if 2021 DW1 is an exception or a typical case., Comment: 9 pages, 9 figures, submitted to A&A (version after revision)

Published

2021

2. Potential asteroid discoveries by the ESA Gaia mission: Results from follow-up observations

Author

Carry, B., Thuillot, W., Spoto, F., David, P., Berthier, J., Tanga, P., Mignard, F., Bouquillon, S., Mendez, R . A., Rivet, J. -P., Van Suu, A. Le, Dell'Oro, A., Fedorets, G., Frezouls, B., Granvik, M., Guiraud, J., Muinonen, K., Panem, C., Pauwels, T., Roux, W., Walmsley, G., Petit, J. -M., Abe, L., azian, V. Ayv, Baillié, K., Baransky, A., Bendjoya, P., Dennefeld, M., Desmars, J., Eggl, S., Godunova, V., Hestroffer, D ., Inasaridze, R., Kashuba, V., Krugly, Y. N., Molotov, I. E., Robert, V., Simon, A., Sokolov, I., Souami, D., Tarady, V., Taris, F., Troianskyi, V., Vasylenko, V., and Vernet, D.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Since July 2014, the ESA Gaia mission has been surveying the entire sky down to magnitude 20.7 in the visible. In addition to the millions of stars, thousands of Solar System Objects (SSOs) are observed daily. By comparing their positions to those of known objects, a daily processing pipeline filters known objects from potential discoveries. However, owing to Gaia's specific scanning law designed for stars, potential newly discovered moving objects are characterized by very few observations, acquired over a limited time. This aspect was recognized early in the design of the Gaia data processing. A daily processing pipeline dedicated to these candidate discoveries was set up to release calls for observations to a network of ground-based telescopes. Their aim is to acquire follow-up astrometry and to characterize these objects. From the astrometry measured by Gaia, preliminary orbital solutions are determined, allowing to predict the position of these potentially new discovered objects in the sky accounting for the large parallax between Gaia and the Earth (separated by 0.01 au). A specific task within the Gaia Consortium has been responsible for the distribution of requests for follow-up observations of potential Gaia SSO discoveries. Since late 2016, these calls for observations (called alerts) are published daily via a Web interface, freely available to anyone world-wide. Between November 2016 and July 2020, over 1700 alerts have been published, leading to the successful recovery of more than 200 objects. Among those, six have provisional designation assigned with the Gaia observations, the others being previously known objects with poorly characterized orbits, precluding identification at the time of Gaia observations. There is a clear trend for objects with a high inclination to be unidentified, revealing a clear bias in the current census of SSOs against high inclination populations., Comment: Submitted to Astronomy & Astrophysics

Published

2020

3. ASASSN-18fk: A new WZ Sge-type dwarf nova with multiple rebrightenings and a new candidate for a superhumping intermediate polar

Author

Pavlenko, E., Niijima, K., Mason, P., Wells, N., Sosnovskij, A., Antonyuk, K., Simon, A., Pit, N., Littlefield, C., Itoh, H., Kiyota, S., Tordai, T., Dubovsky, P., Vanmunster, T., Stone, G., Kato, T., Sergeev, A., Godunova, V., Lyumanov, E., Antonyuk, O., Baklanov, A., Babina, Ju., Isogai, K., Romanyuk, Ya., Troianskyi, V., and Kashuba, V.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We present the result of a multi-longitude campaign on the photometric study of the dwarf nova ASASSN-18fk during its superoutburst in 2018. It was observed with 18 telescopes at 15 sites during ~70 nights within a three-month interval. Observations covered the main outburst, six rebrightenings and 50-d decline to a near-quiescent state. We identify ASASSN-18fk as WZ Sge-type dwarf nova with multiple rebrightenings and show the evolution of the 0.06-d superhump period over all stages of the superoutburst. A strong 22-min brightness modulation that superimposed on superhumps is found during rebrightenings and decline. Some evidence of this modulation in a form of a sideband signal is detected during the very onset of the outburst. We interpret the 22-min modulation as a spin period of the white dwarf and suggest that ASASSN-18fk is a good candidate for a superhumping intermediate polar., Comment: 12 pages, 8 figures

Published

2019

4. Temporary capture of a small body into a geocentric orbit

Author

Bazyey, O., primary, Tokovenko, A., additional, and Troianskyi, V., additional

Published

2023

5. First reported observation of asteroids 2017 AB8, 2017 QX33, and 2017 RV12

Author

Troianskyi, V., primary, Kashuba, V., additional, Bazyey, O., additional, Okhotko, H., additional, Savanevych, V., additional, Khlamov, S., additional, and Briukhovetskyi, A., additional

Published

2023

6. PHYSICAL PROPERTIES OF “HOT POPULATION” OBJECTS IN THE KUIPER BELT

Author

Okhotko, N., primary, Troianskyi, V., additional, and Bazyey, O., additional

Published

2022

7. Photometry and model of near-Earth asteroid 2021 DW1 from one apparition

Author

Kwiatkowski, T., primary, Koleńczuk, P., additional, Kryszczyńska, A., additional, Oszkiewicz, D., additional, Kamiński, K., additional, Kamińska, M. K., additional, Troianskyi, V., additional, Skiff, B., additional, Moskowitz, N., additional, Kashuba, V., additional, Kim, M.-J., additional, Kim, T., additional, Mottola, S., additional, Santana-Ros, T., additional, Kluwak, T., additional, Buzzi, L., additional, Bacci, P., additional, Birtwhistle, P., additional, Miles, R., additional, and Chatelain, J., additional

Published

2021

8. Potential asteroid discoveries by the ESA Gaia mission

Author

Carry, B., primary, Thuillot, W., additional, Spoto, F., additional, David, P., additional, Berthier, J., additional, Tanga, P., additional, Mignard, F., additional, Bouquillon, S., additional, Mendez, R. A., additional, Rivet, J.-P., additional, Le Van Suu, A., additional, Dell’Oro, A., additional, Fedorets, G., additional, Frezouls, B., additional, Granvik, M., additional, Guiraud, J., additional, Muinonen, K., additional, Panem, C., additional, Pauwels, T., additional, Roux, W., additional, Walmsley, G., additional, Petit, J.-M., additional, Abe, L., additional, Ayvazian, V., additional, Baillié, K., additional, Baransky, A., additional, Bendjoya, P., additional, Dennefeld, M., additional, Desmars, J., additional, Eggl, S., additional, Godunova, V., additional, Hestroffer, D., additional, Inasaridze, R., additional, Kashuba, V., additional, Krugly, Y. N., additional, Molotov, I. E., additional, Robert, V., additional, Simon, A., additional, Sokolov, I., additional, Souami, D., additional, Tarady, V., additional, Taris, F., additional, Troianskyi, V., additional, Vasylenko, V., additional, and Vernet, D., additional

Published

2021

9. ДИНАМИКА КОЛЕЦ АСТЕРОИДА (10199) CHARIKLO

Author

Troianskyi, V. V., Astronomical Observatory, Odessa National University, and Bazyey, O. A.

Subjects

астероиды, спутник Chariklo, кольца астероида, спутник-пастух, 523.4, asteroids, satellites Chariklo, rings asteroid, shepherd satellite

Abstract

In 2014 it was reported on opening two rings around asteroid (10199) Chariklo (Braga-Ribas F., et al., 2014, Nature,508, 72–75) and it became the fifth object of the Solar system known to have ring system, after Jupiter, Saturn, Uranus and Neptune. The main component of the system is the biggest Centaur. This work considers the erosion time of rings in the asteroid system (10199) Chariklo, that is due to a number of effects. Also, we have calculated themass and period of rotation of the asteroid’s shepherd satellite. В 2014 году сообщалось(Braga-Ribas F., et al., 2014, Nature, 508, 72–75) об открытии двух колец вокруг астероида (10199) Chariklo; он стал пятым объектом Солнечной системы у которого обнаружена система колец, после Юпитера, Сатурна, Урана и Нептуна. Главный компонент системы является самым крупным Кентавром. В работе рассмотрено время эрозии колец в астероидной системе (10199) Chariklo, которая происходит из-за ряда эффектов. Также мы определили массу и период обращения предполагаемого спутника-пастуха данного астероида. У 2014 роцi було повiдомлено (Braga-Ribas F., et al., 2014, Nature, 508, 72–75) про вiдкриття двох кiлець навколо астероїда (10199)Chariklo; вiн став п’ятим об’єктом Сонячної системи, у якого виявлено система кiлець, пiсля Юпiтера, Сатурна, Урана i Нептуна. Головний компонент системи є найбiльшим Кентавром. У роботi розглянуто час ерозiї кiлець в астероїднiй системi (10199) Chariklo, що вiдбувається через низку ефектiв. Також ми визначили масу i перiод обертання передбачуваного супутника-пастуха даного астероїда.

Published

2018

10. Observations and Orbits of Comets

Author

Kulichenko, N., Pomazan, A. V., Maigurova, N. V., Bodryagin, D. V., Bacci, P., Maestripieri, M., Tesi, L., Fagioli, G., Bonomi, R., Facchini, M., Coffano, A., Marinello, W., Micheli, M., Pizzetti, G., Soffiantini, A., Cernis, K., Haver, R., Gorelli, R., Piazzolla, L. M., Jaeger, M., Prosperi, E., Prosperi, S., Vollmann, W., Wiebe, Y., Kaiser, G., Puccini, S., Buriev, A. M., Ibrohimov, A. A., Safarov, A. G., Ayubov, D. K., Asoev, H. G., Foglia, S., Galli, G., Naves, R., Campas, M., Hasubick, W., Scotti, J. V., Altieri, B., Bouy, H., Verdoes-Kleijn, G., Carry, B., Kadota, K., Abe, H., Seki, T., Sato, H., Rodríguez, D., Ionescu, D., Christie, G. W., Natusch, T., Gilmore, A. C., Kilmartin, P. M., Meech, K. J., Kleyna, J., Woodworth, D., Kashuba, V., Troianskyi, V., Kashuba, S., Baransky, A., Tochonyy, V., Gunko, N., Pogrebtsov, N., Radomskiy, V., Ruban, E., Pavluk, Y., Kurginian, E., Ershov, D., Zadorozhny, O., Kasyanchuk, A., Bakaieva, O., Shevchuk, D., Bondar, D., Pais, T., Smolynec, V., Balam, D. D., Tubbiolo, A. F., Leonard, G. J., Matheny, R. G., Kowalski, R. A., Fuls, D. C., Johnson, J. A., Christensen, E. J., Gibbs, A. R., Grauer, A. D., Larson, S. M., Seaman, R. L., Shelly, F. C., Moritz, N., Childs, W., Ikari, Y., Masi, G., Schwartz, M., Holvorcem, P., Dupouy, P., de Vanssay, J. B., James, N., Soulier, J.-F., Aymami, J. M., Camarasa, J., Linder, J., Montoro, L., Bosch, J. M., Bryssinck, E., Diepvens, A., Shurpakov, S., Gao, X. Liao X., Liao, X., Lindner, P., Dangl, G., Mainzer, A. K., Bauer, J. M., Grav, T., Masiero, J. R., Dailey, J. W., Cutri, R. M., Wright, E. L., Nugent, C., Sonnett, S., Kramer, E., Gaitan, J., Tremosa, L., Zhao, H. B., Li, B., Zhaori, G., Hong, R. Q., Hu, L. F., Lu, H., Tan, H. J., Ohshima, Y., Barona Felgosa, L., Belli, L., Bilhaj, M., Bosse, M., Schmidt, M., Breitenstein, P., Mccormick, J., Carstens, R., Drummond, J., Bulger, J., Goggia, T., Lowe, T., Schultz, A., Willman, M., Chambers, K., Chastel, S., Denneau, L., Flewelling, H., Huber, M., Lilly, E., Magnier, E., Wainscoat, R., Waters, C., Weryk, R., Pei, W., Hambsch, F.-J., Hambsch, J., Lutkenhoner, B., Paul, N., Gasparovic, G., Chen, Y., Cox, P., Betzler, A. S., Sherrod, P. C., Sherrod, L. P., Bell, C., Peterson, H., Chapman, A., Sparrenberger, M., Gonzalez, J., Hills, K., Benavides, R., Carson, P., Morales, M., Gerhard, C., Fichtl, R., Haeusler, B., Ditz, P., Hudin, L., Sugawara, K., Nohara, H., Buzzi, L., Concari, P., Cremaschini, C., Tombelli, M., Tilley, S. M., van Buitenen, G., Dymock, R., Camilleri, P., Williams, H., Heinze, A., Weiland, H., Stalder, B., Tonry, J., Sherstyuk, A., Rowe, B., Wilde, D., Flynn, R. L., Allen, L., Trilling, D., James, D., Herrera, D., Fuentes, C., Rajagopal, J., Axelrod, T., Valdes, F., Lipunov, V., Podesta, R., Gorbovskoy, E., Tiurina, N., Balanutsa, P., Kuznetsov, A., Kornilov, V., Chazov, V., Lopez, C., Podesta, F., Levato, H., Saffe, C., Maury, A., Vanssay, J. B., Noël, T., Sandness, B., Maur, A., Jacques, C., Pimentel, E., Barros, J., Acosta, A., Sofia, A., Silvia, A., Jackson, F., Limon, F., Farf, R., Wells, G., Bamberger, D., Williams, G. V., and Pomies, Marie-Paule

Subjects

[SDU.ASTR.IM] Sciences of the Universe [physics]/Astrophysics [astro-ph]/Instrumentation and Methods for Astrophysic [astro-ph.IM]

Abstract

Available from the Minor Planet Center.

Published

2017

11. RESONANCES IN SATURN’S SYSTEM

Author

Voitko, A. S., primary and Troianskyi, V. V., additional

Published

2017

12. RESONANCES IN ASTEROID SYSTEMS

Author

Troianskyi, V., primary

Published

2016

13. THE SOLAR-RADIATION PRESSURE EFFECTS ON THE ORBITAL EVOLUTION OF ASTEROID MOONS

Author

Troianskyi, V. V., Bazyey, O. A., Troianskyi, V. V., and Bazyey, O. A.

Abstract

In the theory of motion, disturbances are divided into gravitational and non-gravitational ones. In this paper, we discuss the effects of solar-radiation pressure on the orbital evolution of asteroid moons. It is known from the laws of physics that the smaller an object is the more pressure is exerted on it by solar radiation. That is the reason why asteroid moons with their small sizes are exposed to the solar-radiation pressure so much.

Published

2016

14. THE QUANTITY AND QUALITY OF OBSERVATIONAL NIGHTS MONITORED WITH USING THE ASTRONOMICAL INSTRUMENTS AT THE SUBURBAN OBSERVATION STATIONS OF ASTRONOMICAL OBSERVATORY OF ODESSA NATIONAL UNIVERSITY

Author

Kashuba, S. G., Gorbanev, Yu. M., Andrievsky, S. M., Marsakova, V. I., Troianskyi, V. V., Kashuba, S. G., Gorbanev, Yu. M., Andrievsky, S. M., Marsakova, V. I., and Troianskyi, V. V.

Abstract

The Astronomical Observatory of Odessa National University named after I.I. Mechnikov is one of the four astronomical observatories which exist in classical universities.The Observatory has a main office in the T.G. Shevchenko Park that located near historical center of Odessa. The Observatory also has several observation stations: in the Odessa suburb Mayaki and Kryzhanovka villages.

Published

2016

15. EFFECT OF NON-SPHERICITY OF GRAVITATIONAL FIELD OF THE ASTEROID ON THE ITS SATELLITES ORBITS EVOLUTION

Author

Troianskyi, V. V., primary

Published

2015

16. THE SOLAR-RADIATION PRESSURE EFFECTS ON THE ORBITAL EVOLUTION OF ASTEROID MOONS

Author

Troianskyi, V. V., primary and Bazyey, O. A., additional

Published

2015

17. THE QUANTITY AND QUALITY OF OBSERVATIONAL NIGHTS MONITORED WITH USING THE ASTRONOMICAL INSTRUMENTS AT THE SUBURBAN OBSERVATION STATIONS OF ASTRONOMICAL OBSERVATORY OF ODESSA NATIONAL UNIVERSITY

Author

Kashuba, S. G., primary, Gorbanev, Yu. M., additional, Andrievsky, S. M., additional, Marsakova, V. I., additional, and Troianskyi, V. V., additional

Published

2015