in the near-infrared H-band, sorted according to orbital phase. Because some phases are poorly covered, Aa2 jumps at some points along its path. Algol is a multiple-star system with three confirmed and two suspected stellar components. From the point of view of the Earth, Algol Aa1 and Algol Aa2 form an
eclipsing binary because their
orbital plane contains the
line of sight to the Earth. The eclipsing binary pair is separated by only 0.062
astronomical units (au) from each other, whereas the third star in the system (Algol Ab) is at an average distance of 2.69 au from the pair, and the mutual
orbital period of the trio is 681 Earth days. The total mass of the system is about 5.8 solar masses, and the mass ratios of Aa1, Aa2, and Ab are about 4.5 to 1 to 2.5. The three components of the bright triple star used to be, and still sometimes are, referred to as β Per A, B, and C. The
Washington Double Star Catalog lists them as Aa1, Aa2, and Ab, with two very faint stars B and C about one
arcmin distant. A further five faint stars are also listed as companions. The close pair consists of a B8
main sequence star and a much less massive K0
subgiant, which is highly distorted by the more massive star. These two orbit every 2.9 days and undergo the eclipses that cause Algol to vary in brightness. The third star orbits these two every 680 days and is a
F1 main-sequence star. It has been classified as an
Am star, but this is now considered doubtful. Studies of Algol led to the
Algol paradox in the theory of
stellar evolution: although components of a binary star form at the same time, and massive stars evolve much faster than the less massive stars, the more massive component Algol Aa1 is still in the
main sequence, but the less massive Algol Aa2 is a
subgiant star at a later evolutionary stage. The paradox can be solved by
mass transfer: when the more massive star became a subgiant, it filled its
Roche lobe, and most of the mass was transferred to the other star, which is still in the main sequence. In some binaries similar to Algol, a gas flow can be seen. The gas flow between the primary and secondary stars in Algol has been imaged using Doppler
Tomography. This system also exhibits
x-ray and
radio wave flares. The x-ray flares are thought to be caused by the magnetic fields of the A and B components interacting with the mass transfer. The radio-wave flares might be created by magnetic cycles similar to those of
sunspots, but because the magnetic fields of these stars are up to ten times stronger than the field of the
Sun, these radio flares are more powerful and more persistent. The secondary component was identified as the radio emitting source in Algol using
Very-long-baseline interferometry by Lestrade and co-authors. Magnetic activity cycles in the chromospherically active secondary component induce changes in its radius of gyration that have been linked to recurrent orbital period variations on the order of ≈ via the
Applegate mechanism.
Mass transfer between the components is small in the Algol system but could be a significant source of period change in other
Algol-type binaries. (bottom middle), Algol Aa2 (right) and the
blue giant Bellatrix (left). The distance to Algol has been measured using very-long baseline
interferometry, giving a value of 94
light-years. and its
apparent magnitude was about −2.5, which is considerably brighter than the star
Sirius is today. Because the total mass of the Algol system is about 5.8 solar masses, at the closest approach this might have given enough
gravity to
perturb the
Oort cloud of the Solar System somewhat and hence increase the number of
comets entering the inner Solar System. However, the actual increase in net cometary collisions is thought to have been quite small. ==Names==