Classification of brown dwarfs Spectral class M These are brown dwarfs with a spectral class of M5.5 or later; they are also called late-M dwarfs. All brown dwarfs with spectral type M are young objects, such as
Teide 1, which is the first M-type brown dwarf discovered, and
LP 944-20, the closest M-type brown dwarf.
Spectral class L The defining characteristic of
spectral class M, the coolest type in the long-standing classical stellar sequence, is an optical spectrum dominated by absorption bands of
titanium(II) oxide (TiO) and
vanadium(II) oxide (VO) molecules. However,
GD 165B, the cool companion to the white dwarf
GD 165, had none of the hallmark TiO features of M dwarfs. The subsequent identification of many objects like GD 165B ultimately led to the definition of a new
spectral class, the
L dwarfs, defined in the red optical region of the spectrum not by metal-oxide absorption bands (TiO, VO), but by metal
hydride emission bands (
FeH,
CrH,
MgH,
CaH) and prominent atomic lines of
alkali metals (Na, K, Rb, Cs). , over 900 L dwarfs had been identified,
Spectral class T As GD 165B is the prototype of the L dwarfs,
Gliese 229B is the prototype of a second new spectral class, the
T dwarfs. T dwarfs are pinkish-magenta. Whereas
near-infrared (NIR) spectra of L dwarfs show strong absorption bands of H2O and
carbon monoxide (CO), the NIR spectrum of Gliese 229B is dominated by absorption bands from
methane (CH4), a feature which in the Solar System is found only in the giant planets and
Titan. CH4, H2O, and molecular
hydrogen (H2) collision-induced absorption (CIA) give Gliese 229B blue near-infrared colors. Its steeply sloped red optical spectrum also lacks the FeH and CrH bands that characterize L dwarfs and instead is influenced by exceptionally broad absorption features from the
alkali metals
Na and
K. These differences led
J. Davy Kirkpatrick to propose the T spectral class for objects exhibiting H- and K-band CH4 absorption. , 355 T dwarfs were known. Early observations limited how distant T-dwarfs could be observed. T-class brown dwarfs, such as
WISE 0316+4307, have been detected more than 100 light-years from the Sun. Observations with JWST have detected T-dwarfs such as
UNCOVER-BD-1 up to 4500 parsec distant from the Sun.
Spectral class Y In 2009, the coolest-known brown dwarfs had estimated effective temperatures between , and have been assigned the spectral class T9. Three examples are the brown dwarfs
CFBDS J005910.90–011401.3,
ULAS J133553.45+113005.2 and
ULAS J003402.77−005206.7. The spectra of these objects have absorption peaks around 1.55 micrometres. However, the feature is difficult to distinguish from absorption by water and
methane,
Proposed spectral class H In 2025, astronomers
Kevin Luhman and
Catarina Alves de Oliveira proposed a new spectral class H (H from
hydrocarbon). Using data from the
James Webb Space Telescope, they identified many brown dwarfs in the star-forming region
IC 348, that have very low masses (many under the deuterium burning limit) and have an absorption line at 3.4 μm corresponding to an as-of-yet unidentified aliphatic hydrocarbon. Such absorption line would define the H-class.
Role of vertical mixing In the hydrogen-dominated atmosphere of brown dwarfs a
chemical equilibrium between
carbon monoxide and
methane exists. Carbon monoxide reacts with
hydrogen molecules and forms methane and
hydroxyl in this reaction. The hydroxyl radical might later react with hydrogen and form water molecules. In the other direction of the reaction, methane reacts with hydroxyl and forms carbon monoxide and hydrogen. The chemical reaction is tilted towards carbon monoxide at higher temperatures (L-dwarfs) and lower pressure. At lower temperatures (T-dwarfs) and higher pressure the reaction is tilted towards methane, and methane predominates at the T/Y-boundary. However, vertical mixing of the atmosphere can cause methane to sink into lower layers of the atmosphere and carbon monoxide to rise from these lower and hotter layers. The carbon monoxide is slow to react back into methane because of an energy barrier that prevents the breakdown of the
C-O bonds. This forces the observable atmosphere of a brown dwarf to be in a chemical disequilibrium. The L/T transition is mainly defined with the transition from a carbon-monoxide-dominated atmosphere in L-dwarfs to a methane-dominated atmosphere in T-dwarfs. The amount of vertical mixing can therefore push the L/T-transition to lower or higher temperatures. This becomes important for objects with modest surface gravity and extended atmospheres, such as giant
exoplanets. This pushes the L/T transition to lower temperatures for giant exoplanets. For brown dwarfs this transition occurs at around 1200 K. The exoplanet
HR 8799c, on the other hand, does not show any methane, while having a temperature of 1100K. Future observations with
JWST and the
ELTs might improve the sample of Y-dwarfs with observed spectra. Y-dwarfs are dominated by deep spectral features of methane, water vapor and possibly absorption features of
ammonia and
water ice. The prefix sd stands for
subdwarf and only includes cool subdwarfs. This prefix indicates a low
metallicity and kinematic properties that are more similar to
halo stars than to
disk stars. The red suffix describes objects with red color, but an older age. This is not interpreted as low surface gravity, but as a high dust content. Typical atmospheres of known brown dwarfs range in temperature from 2200 down to . Observations of known brown dwarf candidates have revealed a pattern of brightening and dimming of infrared emissions that suggests relatively cool, opaque cloud patterns obscuring a hot interior that is stirred by extreme winds. The weather on such bodies is thought to be extremely strong, comparable to but far exceeding Jupiter's famous storms. On January 8, 2013, astronomers using NASA's
Hubble and
Spitzer space telescopes probed the stormy atmosphere of a brown dwarf named
2MASS J22282889–4310262, creating the most detailed "weather map" of a brown dwarf thus far. It shows wind-driven, planet-sized clouds. The new research is a stepping stone toward a better understanding not only brown dwarfs, but also of the atmospheres of planets beyond the Solar System. In April 2020 scientists reported measuring wind speeds of (up to 1,450 miles per hour) on the nearby brown dwarf
2MASS J10475385+2124234. To calculate the measurements, scientists compared the rotational movement of atmospheric features, as ascertained by brightness changes, against the electromagnetic rotation generated by the brown dwarf's interior. The results confirmed previous predictions that brown dwarfs would have high winds. Scientists are hopeful that this comparison method can be used to explore the atmospheric dynamics of other brown dwarfs and extrasolar planets.
Observational techniques B, and
WISE 1828+2650 compared to red dwarf
Gliese 229A, Jupiter and our Sun
Coronagraphs have recently been used to detect faint objects orbiting bright visible stars, including Gliese 229B. Sensitive telescopes equipped with charge-coupled devices (CCDs) have been used to search distant star clusters for faint objects, including Teide 1. Wide-field searches have identified individual faint objects, such as
Kelu-1 (30 light-years away). Brown dwarfs are often discovered in surveys to discover
exoplanets.
Methods of detecting exoplanets work for brown dwarfs as well, although brown dwarfs are much easier to detect. Brown dwarfs can be powerful emitters of radio emission due to their strong magnetic fields. Observing programs at the
Arecibo Observatory and the
Very Large Array have detected over a dozen such objects, which are also called
ultracool dwarfs because they share common magnetic properties with other objects in this class. The detection of radio emission from brown dwarfs permits their magnetic field strengths to be measured directly.
Milestones • 1995: First brown dwarf verified.
Teide 1, an M8 object in the
Pleiades cluster, is picked out with a CCD in the Spanish Observatory of Roque de los Muchachos of the
Instituto de Astrofísica de Canarias. • First methane brown dwarf verified.
Gliese 229B is discovered orbiting red dwarf
Gliese 229A (20 ly away) using an
adaptive optics coronagraph to sharpen images from the reflecting telescope at
Palomar Observatory on Southern California's
Mount Palomar; follow-up infrared spectroscopy made with their
Hale Telescope shows an abundance of methane. • 1998: First X-ray-emitting brown dwarf found.
Cha Hα 1, an M8 object in the
Chamaeleon I dark cloud, is determined to be an X-ray source, similar to convective late-type stars. • 15 December 1999: First X-ray flare detected from a brown dwarf. A team at the University of California monitoring
LP 944-20 (, 16 ly away) via the
Chandra X-ray Observatory, catches a 2-hour flare. • 27 July 2000: First radio emission (in flare and quiescence) detected from a brown dwarf. A team of students at the
Very Large Array detected emission from LP 944–20. • 30 April 2004: First detection of a candidate
exoplanet around a brown dwarf:
2M1207b discovered with the
VLT and the first directly imaged exoplanet. • 20 March 2013: Discovery of the closest brown dwarf system: Luhman 16. • 25 April 2014: Coldest-known brown dwarf discovered.
WISE 0855−0714 is 7.2 light-years away (seventh-closest system to the Sun) and has a temperature between −48 and −13 °C.
Brown dwarfs X-ray sources image of
LP 944-20 before flare and during flare X-ray flares detected from brown dwarfs since 1999 suggest changing
magnetic fields within them, similar to those in very-low-mass stars. Although they do not fuse hydrogen into helium in their cores like stars, energy from the fusion of deuterium and gravitational contraction keep their interiors warm and generate strong magnetic fields. The interior of a brown dwarf is in a rapidly boiling, or convective state. When combined with the rapid rotation that most brown dwarfs exhibit,
convection sets up conditions for the development of a strong, tangled
magnetic field near the surface. The magnetic fields that generated the flare observed by
Chandra from
LP 944-20 has its origin in the turbulent magnetized
plasma beneath the brown dwarf's "surface". Using NASA's
Chandra X-ray Observatory, scientists have detected X-rays from a low-mass brown dwarf in a multiple star system. This is the first time that a brown dwarf this close to its parent star(s) (Sun-like stars TWA 5A) has been resolved in X-rays. The power of the radio emissions of brown dwarfs is roughly constant despite variations in their temperatures. Astronomers have estimated brown dwarf
magnetospheres to span an altitude of approximately 107 m given properties of their radio emissions. It is unknown whether the radio emissions from brown dwarfs more closely resemble those from planets or stars. Some brown dwarfs emit regular radio pulses, which are sometimes interpreted as radio emission beamed from the poles but may also be beamed from active regions. The regular, periodic reversal of radio wave orientation may indicate that brown dwarf magnetic fields periodically reverse polarity. These reversals may be the result of a brown dwarf magnetic activity cycle, similar to the
solar cycle. The first brown dwarf of spectral class M found to emit radio waves was
LP 944-20, detected in 2001. The first brown dwarf of spectral class L found to emit radio waves was
2MASS J0036159+182110, detected in 2008. The first brown dwarf of spectral class T found to emit radio waves was
2MASS J10475385+2124234. This last discovery was significant since it revealed that brown dwarfs with temperatures similar to exoplanets could host strong >1.7 kG magnetic fields. Although a sensitive search for radio emission from Y dwarfs was conducted at the
Arecibo Observatory in 2010, no emission was detected.
Recent developments Estimates of brown dwarf populations in the solar neighbourhood suggest that there may be as many as six stars for every brown dwarf. A more recent estimate from 2017 using the young massive star cluster
RCW 38 concluded that the Milky Way galaxy contains between 25 and 100 billion brown dwarfs. (Compare these numbers to the estimates of the number of stars in the Milky Way; 100 to 400 billion.) In a study published in Aug 2017
NASA's
Spitzer Space Telescope monitored infrared brightness variations in brown dwarfs caused by cloud cover of variable thickness. The observations revealed large-scale waves propagating in the atmospheres of brown dwarfs (similarly to the atmosphere of Neptune and other Solar System giant planets). These atmospheric waves modulate the thickness of the clouds and propagate with different velocities (probably due to differential rotation). In August 2020, astronomers discovered 95 brown dwarfs near the
Sun through the project Backyard Worlds: Planet 9. In 2024 the
James Webb Space Telescope provided the most detailed weather report yet on two brown dwarfs, revealing "stormy" conditions. These brown dwarfs, part of a
binary star system named
Luhman 16 discovered in 2013, are only 6.5 light-years away from Earth and are the closest brown dwarfs to the Sun. Researchers discovered that they have turbulent clouds, likely made of silicate grains, with temperatures ranging from to . This indicates that hot sand is being blown by winds on the brown dwarfs. Additionally, absorption signatures of carbon monoxide, methane, and water vapor were detected. == Binary brown dwarfs ==