CANOPUS 03/06 - Variable Stars III

ECLIPSING BINARIES. Stars that revolve around their mutual centre of gravity, their baricentre, will eclipse each other if the plane of their orbits lies in, or nearly in, the line of sight from the Earth. During their revolutions around each other they will eclipse and transit each other. This causes their total brightness to vary and thus they are classed among variable stars although the stars may not undergo any intrinsic variations. When these stars are to the left and right of each other, they are at their brightest and when they are in line with the line of sight from the Earth, they are at their dimmest.

The first star of this sort to be discovered, was ALGOL (Ra's al Ghoel) or Beta Persei. Its variability was known in the days of the Babylonians and because it was the only star known to vary in brightness, having a period of 2 7/8 days (2,86731 days) it was called the Demon star. Its brightness varies from magnitude 2,12 down to magnitude 3,40. The eclipse of the brighter star by the dimmer star lasts about 10 hours. This is the lapse of time for star B to move from B₁ to B₃ on the Graph of variability. The deaf and dumb John Goodricke who lived to the ripe old age of 22 years, was the first to explain the variability (in 1782) to be due to the two stars of a double star, revolving around each other. When the dimmer star comes to the point B₁ it just begins to eclipse the brighter star A. The fact that the light curve is curved downwards at point B₁ is due to limb-darkening (just like the Sun). As the star B moves past in front of star A it cuts off more and more of the light from A and there is a steady decrease in brightness, the magnitude of the pair dimming from 2,12 down to 3,40 when the B-star is at point B₂, its primary minimum. At B₂ the brightness suddenly increases. This sudden increase in brightness shows that the eclipse is only partial or if it is total the two stars must be equal in size so that there is only one moment of minimum brightness. In the case of a total eclipse a measurable time will elapse while the dimmer star is transiting the brighter so that there will be a flattening in the graph.

At B₃ when the dim star just stops eclipsing the bright star there is a curve in the light curve due to limb darkening.

As star B moves away from the primary star a slight increase in brightness takes place because of light from the primary being reflected from the surface of the dimmer star. Then a dimming of the total light takes place when star B moves in behind the brighter star A. The fact that there is now a flattening of the curve shows that the dimmer star is larger than the brighter because a measurable time elapses while the area of the light of B is cut off by A at B₅.

Then limb darkening has its effect again before a slight dimming takes place as star B moves away from star A. The whole process then begins again from point B₇ onwards.

If the secondary minimum is exactly half-way between the two primary minima, it shows that the orbits of the stars are circles or the line of apsides, in which the major axes lie, is in the line of sight from the Earth.

If the secondary minimum is not exactly in the middle between the two primary minima, it shows that the orbits are ellipses. The greater the removal of the secondary minimum from the middle the greater the eccentricity of the ellipses. So the eccentricity of the orbits can be calculated from the position of the secondary minimum. In the case of Algol the eccentricity of the two orbits works out at 0,033 (nearer to circles than the orbits of six of the Sun's planets).

3. If both the primary and secondary minima are flattened, such as in U Sagittae, the diameters of the stars can be calculated by monitoring the moments of 1st, 2nd, 3rd and 4th contact. Then the absolute magnitudes and the separate magnitudes can also be calculated

4. The line of apsides which is the major axis of the two ellipses rotates in a period of 32 years. This is due to the gravitational perturbation of a third star in the system. The mass of the third body can also be calculated. It works out to 1,3 solar mass and it has an absolute magnitude of 3,2.

ALGOL	Star A	Star B	Star C
Mass ( x Sun )	3,5	1,0	1,3
Diameter ( x Sun )	3,0	3,4	1,5
Absolute Magnitude	-0,2	3,4	3,2
Luminosity ( x Sun )	100	3,6	4,4
Spectral Type	B8 V	K0 IV	F2 V

Star	R.A	Dec.	Magn	itude	Period	Spectral
Algol Type			Max	Min	days	type
Beta Per	03 07,0	+40 56	2,12	3,40	2,86731	B8V; K0 IV; A
Delta Ori	05 32,0	-00 18	1,94	2,63	5,7324	B0 III; O 9V *
V Pup	07 58,0	-49 14	4,7	5,2	1,454	B IVp; B3 IV
CV Vel	09 00,5	-51 32	6,5	7,3	6,889	B0 V; B2 V
V 505 Sgr	19 52,9	-51 32	6,48	7,50	1,182	A0 V; F8 IV
Beta Lyrae	Type
Beta Lyr	18 49,9	+33 32	3,34	4,30	12,935	B7 Ve; A8p
Mu¹ Sco	16 51,9	-38 03	2,8	3,08	1,44027	B1,5 V; B6,5V
U Her	17 17,2	+33 06	4,6	5,3	2,157	B1,5 Vp; B5 III
UW Cma	07 18,2	-24 34	4,84	5,83	4,39341	O7 Ia; O
GG Lup	15 18,9	-40 47	5,4	6,0	2,164175	B5; A6
W Ursae M	ajoris type
S Ant	09 52,3	-28 38	6,4	6,92	0,648345	A9 Vn
YY Eri	04 12,2	-10 28	8,8	9,5	0,321495	G5; G5
V502 Oph	16 41,4	+00 30	8,34	8,84	0,453393	G2 V; F9 V