Phi Persei
Phi Persei, Latinized from formally named Dajiangjunbei, is a class B2Vep fourth-magnitude star in the constellation Perseus, located about 720 light-years from Earth.
Nomenclature
Phi Persei is the star's Bayer designation. Flamsteed followed Ptolemy in treating φ Persei as being in Andromeda and gave it the designation 54 Andromedae. It is isolated from the main stars of Perseus, but lies within its formal borders.In Chinese, 天大將軍, meaning Heaven's Great General, refers to an asterism consisting of φ Persei, γ Andromedae, 51 Andromedae, 49 Andromedae, χ Andromedae, υ Andromedae, τ Andromedae, 56 Andromedae, β Trianguli, γ Trianguli and δ Trianguli. Consequently, the Chinese name for φ Persei itself is 天大將軍二.
The IAU Working Group on Star Names approved the name Dajiangjunbei for Phi Persei A on 25 August 2025 and it is now so entered in the IAU Catalog of Star Names. This means the northern star of Dajiangjun, since the determinative star was already named.
System
Phi Persei is spectroscopic binary consisting of a blue main sequence primary of class B2 and a hot subdwarf secondary. The two stars have an orbit of 217 days and are separated by about. Phi Persei is a runaway star and extrapolating its space velocity backwards by the modelled age of the system places it within the Alpha Persei Cluster.The primary star rotates rapidly with a projected equatorial velocity of. Due to its rapid rotation, the primary star has a polar radius about and an equatorial radius of about. With an effective temperature of nearly, it has a bolometric luminosity nearly 15,000 times higher than the Sun. The rapidly-spinning star is surrounded by a circumstellar disk. The binary orbit, the spin of the primary star, and the disk are all seen nearly edge-on. There are no eclipses, but models of the system show that the disk significantly obscures the primary star. The primary formed as a star and has accreted material from its companion.
The secondary star is also a class O subdwarf, hotter than the primary but smaller and less massive. It is proposed that it is the core of a star, with the outer layers stripped as it expanded away from the main sequence. Its luminosity is higher than expected for a normal helium star, which suggests it may have evolved to helium shell burning. Although the subdwarf has a bolometric luminosity about half that of the primary, it emits most of its radiation as ultraviolet, being only about 3% as bright as the primary at visible wavelengths.