in the
constellation of Carina (bottom right) As a fourth-magnitude star, η Carinae is comfortably visible to the naked eye in all but the most
light-polluted skies in inner-city areas according to the
Bortle scale. Its brightness has varied over a wide range, from the second-brightest star in the sky for a few days in the 19th century, to well below naked-eye visibility. Its location at around 60°S in the far
southern celestial hemisphere means it cannot be seen by observers in Europe and much of North America. Located between Canopus and the Southern Cross, η Carinae is easily pinpointed as the brightest star within the large naked-eye Carina Nebula. In a telescope the "star" is framed within the dark "V"
dust lane of the nebula and appears distinctly orange and clearly non-stellar. High magnification will show the two orange lobes of a surrounding
reflection nebula known as the
Homunculus Nebula on either side of a bright central core. Variable star observers can compare its brightness with several 4th- and 5th-magnitude stars closely surrounding the nebula. Discovered in 1961, the weak
Eta Carinids meteor shower has a
radiant very close to η Carinae. Occurring from 14 to 28 January, the shower peaks around 21 January. Meteor showers are not associated with bodies outside the Solar System, making the proximity to η Carinae merely a coincidence.
Visual spectrum composite of η Carinae showing the unusual emission spectrum (near-IR image spectrum from the Hubble
Space Telescope Imaging Spectrograph CCD) The
strength and
profile of the
lines in the η Carinae
spectrum are highly variable, but there are a number of consistent distinctive features. The spectrum is dominated by
emission lines, usually broad although the higher excitation lines are overlaid by a narrow central component from dense
ionised nebulosity, especially the
Weigelt Blobs. Most lines show a
P Cygni profile but with the absorption wing much weaker than the emission. The broad P Cygni lines are typical of strong
stellar winds, with very weak
absorption in this case because the central star is so heavily obscured.
Electron scattering wings are present but relatively weak, indicating a clumpy wind.
Hydrogen lines are present and strong, showing that η Carinae still retains much of its
hydrogen envelope.
HeI lines are much weaker than the hydrogen lines, and the absence of HeII lines provides an upper limit to the possible temperature of the primary star. NII lines can be identified but are not strong, while carbon lines cannot be detected and oxygen lines are at best very weak, indicating
core hydrogen burning via the
CNO cycle with some mixing to the surface. Perhaps the most striking feature is the rich FeII emission in both
permitted and forbidden lines, with the forbidden lines arising from excitation of low density nebulosity around the star. The earliest analyses of the star's spectrum are descriptions of visual observations from 1869, of prominent emission lines "
C, D, b, F and the principal green nitrogen line". Absorption lines are explicitly described as not being visible. The letters refer to
Fraunhofer's spectral notation and correspond to
Hα, HeI, FeII, and Hβ. It is assumed that the final line is from FeII very close to the green
nebulium line now known to be from OIII. Photographic spectra from 1893 were described as similar to an
F5 star, but with a few weak emission lines. Analysis to modern spectral standards suggests an early F
spectral type. By 1895 the spectrum again consisted mostly of strong emission lines, with the absorption lines present but largely obscured by emission. This spectral transition from F
supergiant to strong emission is characteristic of
novae, where ejected material initially radiates like a pseudo-
photosphere and then the emission spectrum develops as it expands and thins. The spectrum of light reflected from the
Weigelt Blobs, and assumed to originate mainly with the primary, is similar to the
extreme P Cygni-type star which has a spectral type of B0Ieq. Further light echo observations show that following the peak brightness of the Great Eruption the spectrum developed prominent P Cygni profiles and
CN molecular bands, although this is likely from the material being ejected which may have been colliding with
circumstellar material in a similar way to a Type IIn
supernova. In the second half of the 20th century, much higher-resolution visual spectra became available. The spectrum continued to show complex and baffling features, with much of the energy from the central star being recycled into the infrared by surrounding dust, some reflection of light from the star from dense localised objects in the circumstellar material, but with obvious high-ionisation features indicative of very high temperatures. The line profiles are complex and variable, indicating a number of absorption and emission features at various
velocities relative to the central star. The 5.5-year orbital cycle produces strong spectral changes at periastron that are known as spectroscopic events. Certain wavelengths of radiation suffer eclipses, either due to actual
occultation by one of the stars or due to passage within opaque portions of the complex stellar winds. Despite being ascribed to orbital rotation, these events vary significantly from cycle to cycle. These changes have become stronger since 2003 and it is generally believed that long-term secular changes in the stellar winds or previously ejected material may be the culmination of a return to the state of the star before its Great Eruption.
Ultraviolet taken by ESA /
Hubble The
ultraviolet spectrum of the η Carinae system shows many emission lines of ionised metals such as FeII and CrII, as well as
Lymanα (Lyα) and a continuum from a hot central source. The ionisation levels and continuum require the existence of a source with a temperature at least 37,000 K. Certain FeII UV lines are unusually strong. These originate in the Weigelt Blobs and are caused by a
low-gain lasing effect. Ionised hydrogen between a blob and the central star generates intense Lyα emission which penetrates the blob. The blob contains
atomic hydrogen with a small admixture of other elements, including iron
photo-ionised by radiation from the central stars. An accidental
resonance (where emission coincidentally has a suitable energy to
pump the excited state) allows the Lyα emission to pump the Fe+
ions to certain
pseudo-metastable states, creating a
population inversion that allows the
stimulated emission to take place. This effect is similar to the
maser emission from dense pockets surrounding many cool supergiant stars, but the latter effect is much weaker at optical and UV wavelengths and η Carinae is the only clear instance detected of an ultraviolet
astrophysical laser. A similar effect from pumping of metastable OI states by Lyβ emission has also been confirmed as an astrophysical UV laser.
Infrared Infrared observations of η Carinae have become increasingly important. The vast majority of the electromagnetic radiation from the central stars is absorbed by surrounding dust, then emitted as
mid- and
far infrared appropriate to the temperature of the dust. This allows almost the entire energy output of the system to be observed at wavelengths that are not strongly affected by
interstellar extinction, leading to estimates of the luminosity that are more accurate than for other
extremely luminous stars. η Carinae is the brightest source in the night sky at mid-infrared wavelengths. Far infrared observations show a large mass of dust at 100–150 K, suggesting a total mass for the Homunculus of 20
solar masses () or more. This is much larger than previous estimates, and is all thought to have been ejected in a few years during the Great Eruption.
High energy radiation |X-rays around η Carinae (red is low energy, blue higher) Several
X-ray and
gamma ray sources have been detected around η Carinae, for example 4U 1037–60 in the 4th
Uhuru catalogue and 1044–59 in the
HEAO-2 catalog. The earliest detection of X-rays in the η Carinae region was from the Terrier-Sandhawk rocket, followed by
Ariel 5,
OSO 8, and Uhuru sightings. More detailed observations were made with the
Einstein Observatory,
ROSAT X-ray telescope,
Advanced Satellite for Cosmology and Astrophysics (ASCA), and
Chandra X-ray Observatory. There are multiple sources at various wavelengths right across the high energy electromagnetic spectrum: hard X-rays and gamma rays within 1 light-month of the η Carinae; hard X-rays from a central region about 3 light-months wide; a distinct partial ring "horse-shoe" structure in low-energy X-rays 0.67 parsec (2.2 light-years) across corresponding to the main shockfront from the Great Eruption; diffuse X-ray emission across the whole area of the Homunculus; and numerous condensations and arcs outside the main ring. All the high-energy emission associated with η Carinae varies during the orbital cycle. A spectroscopic minimum, or X-ray eclipse, occurred in July and August 2003, and similar events in 2009 and 2014 have been intensively observed. The highest-energy gamma rays above 100
MeV detected by
AGILE show strong variability, while lower-energy gamma rays observed by
Fermi show little variability.
Radio emission Radio emissions have been observed from η Carinae across the
microwave band. It has been detected in the
21 cm HI line, but has been particularly closely studied in the
millimetre and
centimetre bands.
Masing hydrogen
recombination lines (from the combining of an electron and proton to form a hydrogen atom) have been detected in this range. The emission is concentrated in a small non-point source less than 4
arcseconds across and appears to be mainly free-free emission (thermal
bremsstrahlung) from ionised gas, consistent with a compact HII region at around 10,000 K. High resolution imaging shows the radio frequencies originating from a disk a few arcseconds in diameter, 10,000
astronomical units () wide at the distance of η Carinae. ==Surroundings==