IRC +10216

CW Leonis

CW Leonis in ultraviolet showing the bowshock
Observation data Epoch J2000      Equinox J2000
Constellation	Leo
Right ascension	09h 47m 57.406s
Declination	+13° 16′ 43.56″
Apparent magnitude (V)	10.96 - 14.80
Characteristics
Spectral type	C9,5e
Apparent magnitude (R)	10.96
Apparent magnitude (J)	7.34
Apparent magnitude (H)	4.04
Apparent magnitude (K)	1.19
Variable type	Mira
Astrometry
Proper motion (μ)	RA: 35 ± 1 mas/yr Dec.: 12 ± 1 mas/yr
Parallax (π)	10.56 ± 2.02mas
Distance	approx. 310 ly (approx. 90 pc)
Details
Mass	0.7 - 0.9 M☉
Radius	826 R☉
Luminosity	6,250 - 15,800 L☉
Temperature	1,915 - 2,105 K
Other designations
CW Leo, Peanut Nebula, IRC+10216, IRAS 09452+1330, PK 221+45 1, Zel 0945+135, RAFGL 1381, 2MASS J09475740+1316435, SCM 50
Database references
SIMBAD	data

IRC +10216 or CW Leonis is a well-studied carbon star that is embedded in a thick dust envelope. It was first discovered in 1969 by a group of astronomers led by Eric Becklin, based upon infrared observations made with the 62 inches (1.6 m) Caltech Infrared Telescope at Mount Wilson Observatory. Its energy is emitted mostly at infrared wavelengths. At a wavelength of 5 μm, it was found to have the highest flux of any object outside the Solar System.

CW Leonis is believed to be in a late stage of its life, blowing off its own sooty atmosphere to form a white dwarf in a distant future. Based upon isotope ratios of magnesium, the initial mass of this star has been constrained to lie between 3–5 solar masses. The mass of the star's core, and the final mass of the star once it becomes a white dwarf, is about 0.7–0.9 solar masses. Its bolometric luminosity varies over the course of a 649-day pulsation cycle, ranging from a minimum of about 6,250 times the Sun's luminosity up to a peak of around 15,800 times. The overall output of the star is best represented by a luminosity of 11,300 L_☉.

The carbon-rich gaseous envelope surrounding this star is at least 69,000 years old and the star is losing about (1–4) × 10⁻⁵ solar masses per year. The extended envelope contains at least 1.4 solar masses of material. Speckle observations from 1999 show a complex structure to this dust envelope, including partial arcs and unfinished shells. This clumpiness may be caused by a magnetic cycle in the star that is comparable to the solar cycle in the Sun and results in periodic increases in mass loss. Various chemical elements and about 50 molecules have been detected in the outflows from CW Leonis, among others nitrogen, oxygen and water, silicon and iron.