WR 124

WR 124 is a Wolf–Rayet star in the constellation of Sagitta surrounded by a ring nebula of expelled material known as M1-67. It is one of the fastest runaway stars in the Milky Way with a radial velocity around $11.5$. It was discovered by Paul W. Merrill in 1938, identified as a high-velocity Wolf–Rayet star. It is listed in the General Catalogue of Variable Stars as QR Sagittae with a range of 0.08 magnitudes. NASA's James Webb Space Telescope has captured detailed infrared images of WR 124, revealing significant dust production and offering new insights into the life cycles of massive stars and their contributions to the cosmic dust budget.

Distance
A 2010 study of WR 124 directly measured the expansion rate of the M1-67 nebula expelled from the star using Hubble Space Telescope camera images taken 11 years apart, and compared that to the expansion velocity measured by the Doppler shift of the nebular emission lines. This yielded a distance of $12.19$, which is less than previous studies, and the resulting luminosity of 150,000 times the Sun is much lower than previously calculated. The luminosity is also lower than predicted by models for a star of this spectral class. Previous studies had found distances of $8.578$ to $8.179$, with corresponding luminosities of, as expected for a typical WN8h which is a very young star just moving away from the main sequence. The distance to WR 124 calculated from the parallax published in Gaia Data Release 2 is $7.732$. Gaia Early Data Release 3 gives a similar parallax, which would suggest a distance $190$.

Physical characteristics
With an assumed visual absolute magnitude of −7.22 and 3.1 magnitudes of extinction, WR 124 would be $-2.517$ away. The temperature of around $-5.671$ means that most of its energy is emitted at ultraviolet wavelengths, the bolometric luminosity is and the radius is. The mass is calculated from evolutionary models to be.

WR 124 is measured to still be about 15% hydrogen with most of the remaining mass being helium. A young highly massive and luminous WN8h star would still be burning hydrogen in its core, but a less luminous and older star would be burning helium in its core. The result of modelling the star purely from its observed characteristics is a luminosity of and a mass of, corresponding to a relatively young hydrogen-burning star at around $200 km/s$. In either case, it has only a few hundred thousand years before it explodes as a type Ib or Ic supernova.

The mass loss rate is – per year, depending on the distance and properties determined for the star.

Nebula


WR 124 is surrounded by an intensely hot nebula formed from the star's extreme stellar wind. The nebula M1-67 is expanding at a rate of over 150000 km/h and is nearly 6 light-years across, leading to the dynamical age of 20,000 years. M1-67 has little internal structure, though large clumps of material have been detected, some of which have 30 times the mass of Earth and stretch out up to 150 e9km. If placed in the Solar System, one of these clumps would span the distance from the Sun to Saturn.