This page contains information on the tables for binary star systems. Here we will explain the various columns in the tables, what the different abbreviations mean, and which units are used. Scroll down to the example tables and click on a column header to find out more.
| System | Discovery | Spectral Type | Distance [parsec] | Mass ratio [m2/(m1+m2)] | a_binary [AU] | e_sec | Number of planets | Planet motion S-type, P-type | m1 [m_sun] | m2 [m_sun] | Comments |
|---|---|---|---|---|---|---|---|---|---|---|---|
| DP Leo AB b | 2009 | DA / M5V | 400.00 | 0.015 | 0.0027 | 0.00 | 1 | P | 0.6 | 0.009 | p=1.4967h |
| FW Tau AB b | 2013 | M4 / ? | 145.00 | 0.500 | 11 | 1 | P | 0.12 | 0.12 | ||
| g Cep Ab B | 2003 | K2V / ? | 13.79 | 20.3 | 0.36 | 1 | S | 1.4 |
Name or designation of the system and the structure of the system, where capital letters refer to a star, and small letters refer to a planet.
Example: DP Leo AB b
"Ab B" or "A Bb" refered to a S-Type planet, while "AB b" refer to a P-Type planet as marked in the column on the planetary motion. This part of the catalogue represents only the stellar data of the system.
All systems are linked to The Extrasolar Planets Encyclopaedia (http://exoplanet.eu/) or to the Open Exoplanet Catalogue (http://www.openexoplanetcatalogue.com/) where one can find additional data on the systems.
Gives the year of the first discovery.
This shows the spectral types of the stars. Unfortunately the data for some systems is incomplete.
Distance from the Sun to the system in units of parsecs (1 parsec = 3.26 light-years).
Given as dimensionless proportion m2/(m1+m2), where m1 is the mass of the first star and m2 is the secondary star's mass.
Represents the distance between the double stars given in astronomical units. (1 astronomical unit = 149 597 870.7 kilometres)
Represents the eccentricity of the second star. This parameter is very rarely known.
Systems with one planet are dominant, but multiplanet systems become more and more frequent.
In general, one can distinguish three types of planetary orbits in a binary star system (as shown in figure 1 in the introduction):
Mass of the first and the second star given in units of the masses of our Sun. (1 solar mass = 1.988 × 1030 kg)
| System | Discovery | Mass - M x sin i [M_Jupiter] | Semi-major axis [AU] | Orbital period [d] | Eccentricity | Argument of perihelion [deg] | Radius [R_J] | Inclination | Detection method |
|---|---|---|---|---|---|---|---|---|---|
| Kepler 432 b | 2014 | 5.41 | 0.310 | 52.501 | 0.512 | 65.60 | 1.45 | 88.17 | transit / rad. vel. |
| Kepler-14 b | 2011 | 8.400 | 6.79012 | 0.035 | 1.136 | 90 | transit | ||
| Kepler-16 b | 2011 | 0.333 | 0.7048 | 228.776 | 0.007 | 318.00 | 0.7538 | 90.0322 | transit |
The name or designation of the system; this part of the catalogue represents only the planetary data of the system.
All systems are linked to The Extrasolar Planets Encyclopaedia (http://exoplanet.eu/) or to the Open Exoplanet Catalogue (http://www.openexoplanetcatalogue.com/) where one can find additional data on the systems.
Gives the year of the first discovery.
Represents the minimum mass of the planet in units of one Jupiter mass. (1 Jupiter mass = 1.898 × 1027 kg)
From the observational point of view we only know the mass of the planet to within the unknown factor related to the inclination (i) of the orbit of the system. The actual mass of the planet is the observed quantity divided by sin (i); and clearly, since the maximum value of sin (i) = 1, the planet's actual mass must be larger than or equal to the measured quantity.
Represents the semi-major axis of the planet's orbit given in astronomical units.
Represents the orbital period of the planet given in days.
Represents the eccentricity of the planet.
Represents the angle from the body's ascending node to its periapsis, measured in the direction of motion.
Represents the planet's radius given in units of one Jupiter radius. (1 Jupiter radius = 71 492 km)
This value does not represent the orbital inclination of the planet, but it shows only the inclination relative to the line of sight.
Shows the different detection methods which were used for the observations.