V389 Cygni, also known asHD 201433 andHR 8094, is amultiple star system about 390light years from the Earth, in the constellationCygnus. It is visible as a 5th-magnitude star, making it faintly visible to thenaked eye of an observer far fromcity lights. One component of that system is aslowly pulsating B-type star (SPB) causing the system's brightness to vary from magnitude 5.55 to 5.71 over a period of 1.4 days.[6]
V389 Cygni is catalogued as a multiple star with four visible components. The faint companions TYC 2701-897-1 and UCAC4 602-123109 are unrelated background objects,[15] at59″ and73″ respectively.[16] A 5th-magnitude and 8th-magnitude star separated by3.3″ form acommon proper motion pair, generall referred to as components A and B). The brighter star, component A, is aspectroscopic binary and the system also harbours an unseen third star, making it a triple and the system as a whole then includes four stars.[8] Both the visible stars arechemically peculiar, A being anAp star and B anAm star.[17] The blended spectral class of the pair is B9V, with the brighter star having a class of B9VspSi (or B9 Si Mg)[17] and the fainter kA2.5hA7VmA9n.
Component A of V389 Cygni was discovered to be aspectroscopic binary fromspectra obtained in 1918. In 1921,Reynold K. Young of theDominion Astrophysical Observatory derived its orbit from 49 additional spectra obtained in 1920-1921. He found it to have a circular orbit, with a period of 3.3137 days. He noted that the star showed evidence of variability.[13]
Alight curve for V389 Cygni, plotted fromTESS data.[18] The 1.4289 day period[6] is marked in red.
In 1922 Kurt Bottlinger and Paul Guthnick detected variability in V389 Cygni.[19]Between 1936 and 1942, Guthnick made extensive photoelectric observations of V389 Cygni. He found that sometimes the brightness appeared to change irregularly, and at other times two periods, 1.12912 and 1.19328 days, could be seen. Neither period was related to the orbital period of the spectroscopic binary. Guthnick postulated that the system consisted of twoCepheid variables orbiting each other,[20][21] but it is now believed that only one of the stars in the close binary pair is variable, and it is an SPB star.[4]
In 1978, Frank Gieseking and Wilhelm Seggewiss refined Young's orbit determination for the spectroscopic binary (new period3.313168±0.000008 days), and found that V389 Cygni is a triple star. The third, unseen component, orbits the close binary pair with a period of154.09±0.02 days. They were unable to derive a nonzero eccentricity for either orbit.[19] In 1989, David Barlow re-analyzed earlier data and found that while the orbit of the inner binary appeared to be circular, the data were best fit if the orbit of the third star had an eccentricity of0.311±0.057.[7]
In 2017, Thomas Kallingeret al. published an extensive spectroscopic andastroseismic study of V389 Cygni. They found 29 pulsation frequencies in theBRITE satellite data for the star. They were able to derive an eccentricity value for the inner binary pair's orbit of0.015±0.003. Their astroseismic results indicate that the outer layer of the SPB star is in the process of becoming tidally locked to its close companion, but the inner portion of the star still rotates at a significantly different speed.[4]
^abHøg, E.; Fabricius, C.; Makarov, V. V.; Urban, S.; Corbin, T.; Wycoff, G.; Bastian, U.; Schwekendiek, P.; Wicenec, A. (March 2000). "The Tycho-2 catalogue of the 2.5 million brightest stars".Astronomy and Astrophysics.355:L27 –L30.Bibcode:2000A&A...355L..27H.ISSN0004-6361.
^abGlebocki, R.; Gnacinski, P. (2005). "VizieR Online Data Catalog: Catalog of Stellar Rotational Velocities (Glebocki+ 2005)".VizieR On-line Data Catalog: III/244. Originally Published in: 2005csss...13..571G; 2005yCat.3244....0G.3244.Bibcode:2005yCat.3244....0G.
^Hoffleit, Dorrit; Jaschek, Carlos (1991). "The Bright star catalogue".New Haven, Conn.: Yale University Observatory, 5th Rev.ed.Bibcode:1991bsc..book.....H.
