D O U B L E S T A R S, sometimes abbreviated as just doubles, can be considered as the group of the broader category of gravitationally bound star systems that have two or more visible components. Under this sweeping definition, the triple stars and other multiple systems all fall under the same umbrella. Double stars in fact are fairly common types of stellar objects, and at the last count, over 102 000 are presently recognised (2006).
The very simplest definition for any double star is when two stars just happen to lie close together in the sky. At a casual glance, an observer would be uncertain if these two stars were orbiting each other or were merely joined by chance alignment. Such doubles are called pairs or visual pairs, whose familiar usage often loosely suggests optically observing of a number of double stars in the night sky. Assessing their motions in respect to each star, may in time, provide enough evidence to prove that they do indeed orbit about each other. Such systems are more specifically referred to binaries or true binaries. Other double stars sometimes do not show any real evidence of motion and appear fixed, or simply appear to move in straightened paths through space. The latter of these are called optical double stars. Most known binary stars have not complete on whole revolution, but are distinguished from the pairs only by having a known curved path or some partial arc.
One of the primary aims, which becomes the major task for any serious observer, is to find the true physical association of double stars - whether real or not. It also includes the discovery and refinement of this connection, achieved by the careful measurement of the position angle and separation at known observation dates. When these positions are combined with other measures, mathematical reductions can be applied to determine the probability of some celestial perspective or physical union.
Although measurements maybe important, doubles can also be observed just for fun. Certainly there is nothing quite so attractive as seeing two close bright stars placed within a populated starry field. Some of the brightest also familiar show significant colour differences. Probably the best example is the very beautiful northern system of Beta Persei (β Per) or Alberio, which has a lovely golden yellow primary star contrasted with its fainter gorgeous sapphire blue companion. Another classic in the southern skies is x Velorum (Dunlop 95) - dubbed Alberio Australis, which has the contrasting colours of rich orange-yellow and pale blue. Both β Per and x Vel can be seen readily in small telescopes.
Our southern skies does have its fair share of interesting doubles. These include. the nearest star, Alpha Centauri (α Cen), Alpha (1,2) Crucis (α1,2 Cru), Theta Eridani / Acamar (θ Eri) and p Eridani (Dunlop 5) - all being “must see” pairs for any new southern observer or northern hemisphere visitor.
Much pleasure can be gained by simply seeing the many different configurations between the almost countless numbers of pairs. They make reasonable distractions during the time of Full Moon when deep-sky observing of faint objects are severely affected by bright moonlight. Numerous other pairs offer the further challenge of being difficult to resolve. In these circumstances separation of the two often requires combinations of acquired observational skills and excellent seeing conditions. For some it is just a good opportunity to test out the quality of their telescope’s optics.
Multiple stars or multiples are small stellar groups that contain between three and twenty components. They have properties that do not apply in the same way as binary systems. Consequentially multiples have different kind of sub-types, being organised into different groups or so-called hierarchal arrangements.
The largest groups of multiples are the triple stars, which often have the combination of a close pair with another more distant companion. One classic example of this is the nearest star system of Alpha Centauri. Here the close pair A and B stars orbit in 79.8 years while the C star is Proxima Centauri that orbits once every 100 000 years or so. Some triples may have this distant companion as the brightest star, and the both stars of the main double appearing fainter. Although this might seem a paradox, but it is usually resolved when the masses are determined, as the combined mass of the close pair prove larger than the solitary mass of its smaller companion.
Another type of common multiple systems are the trapezia. These are named after the brightest stellar object in the Orion Nebulae - the famous Trapezium. These multiples can contain four or more stars that are all roughly the same mass and size, however unlike other multiples, they are very young and are gravitationally unstable. Some of these systems may eventually revert to stable triple systems - forming close pairs, with a solitary companion star orbiting at some distance. The other star(s) are violently rejected from the system altogether, and these may explain the high-velocity runaway stars observed in the Milky Way.
Other examples of general multiples include; α Crucis and Sigma (σ) Orionis, both of which being visible in small telescopes.
In the naming of components for double stars is more traditional than necessarily accurate, however, in more recent times this has slowly becoming more standardised. Common sources in the literature sometimes vary from time to time. However, the following trends are applied;
The brighter or major star is called the primary and the companion or second star is called the secondary. Sometimes the term comes, or plural comites, is also applied, but has been outdated for nearly ninety years. If both stars are of equal brightness or magnitude, the discoverer’s distinction is used. This primary to secondary then applies until the true masses are determined. The difference in brightness between the two stars is termed the Delta-m, written as Δm and usually quoted to one decimal place.
Each of the brightest component can also be nominated as ‘A’, the faintest ‘B’. For multiple systems, the components are listed in decreasing magnitude, and are referred to as the companions ‘B’, ‘C’, ‘D’, etc. Pairs that are nominated ‘AB’ are binary stars. In multiple systems, which star is which, can get quite complicated, often with combinations of the these component letters. For identification or descriptive purposes the system, or any telescopic astronomical object, the diurnal motion of the Earth can be used to show the position of the surrounding objects. Distances between the two objects is the separation and is normally measured in second of arc.
These are also combined with the visual co-ordinate terms which influenced by the Earth’s motion in space. These apply to the compass directions of n north and s south, sometimes with the terms p preceding and f following. Each preceding star is before the object- known if the star is allowed to partly drift through the field, while the following star tracks behind the object. This system is very useful because the telescope’s optical configuration becomes irrelevant.
Another system of orientation is the quadrant position which is sometimes used. No only can this be applied to double stars, but may be usefully employed with telescopic deep-sky objects and their various observed features.
| Quadrant 1 nf North-Following |
Quadrant 2 sf South-Following |
Quadrant 3 sp South Preceding |
Quadrant 4 np North-Preceding |
Far more useful and specific are the descriptions of any double’s orientation an position by the two quantities ; Position Angle (PA or θ) and Separation (Sep. or ρ)
POSITION ANGLE is defined as the angle of the primary through the secondary, as measured in the angle deviating from NORTH increasing towards the EAST.
A 0o position angle is celestial north, the 90o position angle is EAST, 180o is SOUTH, 270o is WEST through to 360o that is again NORTH. The position angle is influenced by the Precession of the Equinoxes, so all values must refer to a certain epoch. Ie. Epoch 1950.0 or 2000.0. It is important to note that these quoted values are easily converted, if necessary, which often applies when using older star or double star catalogues.
SEPARATION is simply defined as the distance between the centre of the two stars measured in seconds of arc or abbreviated as arcsec or just; ″. For the widest pairs, separation is sometimes given minutes of arc or arcmin, abbreviated sometimes as; ′, though the practice of this is usually discouraged with double star observers in favour of units in arcsec. Ie. 120 arcsec instead of 2 arcmin, or 120″ instead of 2′
This distance of 1 arcsec corresponds to the very tiny angle subtending roughly 1/1800th of the lunar diameter. Most telescopic doubles are usually defined as star which are less than 300 arcsec - being below naked-eye resolution. Many pairs observed by amateurs are usually below
Once learning if some visual pair is binary, then the motion that increases in position angle is said to orbit in a direct motion, while a decreasing one is referred to as retrograde motion. This has to be distinguished, because unlike the planets, it indicates the likely orbital movements of the two stars, which may be in either direction.
In the binary’s true orbit, closest orbital approach is called apastron, while the furthest distance is periastron. Binary motions in this latter circumstance will rapidly change - especially if the orbit is highly eccentric, near apastron. During periastron the observed change will be slower.
Based on the separation of various pairs it is sometimes useful to categorise them into sub-groups. This helps both in writing up descriptions or estimating the apertures or magnification required to see them. The Table below is a useful recommended guide of separations for amateurs.
| DESCRIPTOR | SEPARATION arcsec |
APERTURE |
| Difficult | <0.5″ | <23cm |
| Very Close | 0.5″ to 2.0″ | 23cm to 5.8cm |
| Close | 2.0″ to 5.0″ | 5.8cm to 2.3cm |
| Standard | 5.0″ to 10″ | 2.3cm to 1.2cm |
| Wide | 10″ to 30″ | 1.2cm to 3.9mm |
| Open | 30″ to 60″ | 3.9mm to 1.9mm |
| Very Wide | >60″ | >1.9mm |
| Naked-eye | >300″ | -- |
Astronomers for sometime have known that knowledge about double stars does contribute to some of the most important aspects in the development of stellar evolution and the general nature of stars. As stars are fundamental building blocks of most objects, such properties as mass, density, stellar atmospheric phenomena, shape etc. becomes desirable quantities for any type of theoretical analysis.
Observing many of the wider bright double stars can be easily achieved using binoculars or small telescopes. Examples can be easy pairs like Alpha and Gamma Crucis. Most can be seen regardless of the quality of the observing conditions. There are several dozen pairs in this category to satisfy the curious observe at any time of the night or year.
Closer double stars or binary stars can sometimes more problematic, and can be sometimes be not a very simple task -even for experienced observers. Often they require knowledge and considerations such as observation conditions, telescope resolution, differences in brightness to simple recognition of the system. Each of these factors must be taken into account, and can ONLY be gained by some observational experience. Any newcomer to observational astronomy could learn much about observing techniques and in finding objects - even if the stargazer has no real interest in this topic.
If you wish to start looking at doubles it is often importantly suggested to have access to several common references listing pairs and one or two decent star atlases. Ie. Sky Atlas 2000.0. Uranometria 2000.0, etc. or electronic astronomical programs, like Megastar or Sky Map Pro.
It is probably best to start with the brighter pairs that are fairly wide apart and are easily located near known bright stars. Such examples are Alpha Crucis at the base of the Southern Crux, followed by Gamma Crucis at the top of the Cross. Next you could follow say, Alpha Centauri, which might prove a little difficult in the next few years (2007-2011). After this you might like to try some more wide pairs with large differences in magnitude. This could be followed by some more challenging examples that are below 5 arcsec, attempting those of equal magnitudes followed by ones with larger differences in brightness.
If you have the aperture above 25cm to 30cm, observers might like to attempt far more difficult pairs like Beta Centauri and Beta Muscae. These can be difficult to split under poor seeing conditions, and observing them over several nights will probably given an appreciation of the difficulties faced under differing seeing conditions.
