In 2017, it was announced that the object's mass may be as low as 12.7
Jupiter masses and might be considered a
rogue planet rather than a
brown dwarf as it seems to be a member of the relatively young, 200 million-year-old Carina-Near stellar
moving group. In 2018 astronomers said "Detecting SIMP J01365663+0933473 with the
VLA through its
auroral radio emission, also means that we may have a new way of detecting exoplanets, including the elusive rogue ones not orbiting a parent star ... This particular object is exciting because studying its magnetic dynamo mechanisms can give us new insights on how the same type of mechanisms can operate in extrasolar planets – planets beyond our Solar System ... We think these mechanisms can work not only in brown dwarfs, but also in both gas giant and terrestrial planets." During the observation with the VLA only one pulse was detected for SIMP0136. The
magnetic flux of SIMP0136 was estimated to be 3.2
kG. In 2025 significant
auroral activity was detected on SIMP0136. A re-analysis of the JWST data found that the atmophere showed a temperature inversion at the
stratosphere, caused by auroral heating, driven by
electron precipitation. The
methane and
carbon monoxide abundance were found to be in
chemical disequelibrium and methane abundance decreases at the temperature inversion. Observations with JWST/NIRSpec and
NIRISS were used to find a transition of methane absorption to methane emission at low pressures (high
altitudes). A similar methane emission was found previously only in
CWISEP J1935−1546. This transition is explained with auroral heating from
electron precipitation. In 2017 the rotational velocity and
radial velocity were measured. It was found that SIMP0136 can be seen almost
equator-on with an
inclination of 80 ±12°.
Weather and clouds This planetary-mass object provided the first evidence for periodic variability flux variations among
T dwarfs. A team observed this object with the 1.8-m
Perkins Telescope Observatory near
Flagstaff, Arizona in 2015. SIMP0136 was observed in 15 nights, spread out over 90 days. The variation has been interpreted as a signature of weather patterns coming in and out of view over the object's 2.4h rotation period. The shape of this lightcurve evolves over timescales of days, which has been interpreted as a sign of evolution of the cloud patterns in its atmosphere. In 2016 a phase shift between
Spitzer and
Hubble observations was noticed, which was measured to be 33.4 ±3.9°. In 2023 a team found that SIMP0136 has patchy
forsterite (Mg2SiO4) clouds above an
iron cloud deck. This patchy cloud layer covers between 69% and 72% of the surface of the object. In 2024 a team re-analysed the 2015 data and detected a
phase shift between the
J-band and
Ks-band of °. The team concluded that the phase shift can be explained with at least two different patchy cloud layers. The J- and Ks-bands both probe different layers of the atmosphere. A study with JWST
NIRSpec and
MIRI observed two rotations and were used to study the object in detail. The study found that the variability comes from different parts of the atmosphere, depending on the wavelength. A signal deep within the atmosphere is thought to be connected to patchy iron clouds. Another signal higher up could come from patchy silicate clouds. A third signal comes from high above the clouds and is connected to hot spots, which could represent the aurora or upwelling of hot gas. Some of the light curves produced can only be explained with changing carbon chemistry. In a re-analysis the variability was found to be caused by changes of the temperature profile above 10
mbar. The effective temperature changed from 1243 K at the coldest to 1248 K at the hottest, which is an
byamplitude of 5 K (or 5°C; 9°F). The spectrum required patchy silicate clouds, which were found not to be the primary cause of variability; the variability was found to be caused by magnetic and thermodynamic mechanisms. The changes of temperature also correlated with a change in abundance of
carbon dioxide and
hydrogen sulfide, which may suggest chemical changes driven by dynamics and storms. == See also ==