Rogue planet

A rogue planet, also called a free-floating planet (FFP) or an isolated planetary-mass object (iPMO), is an interstellar object of planetary mass. It is not tied to any star or brown dwarf by gravity. These planets move through space alone, not orbiting a star like the planets in our solar system.

Rogue planets may start in planetary systems where they form and are later pushed out. They can also form by themselves, away from any planetary system. The Milky Way might have billions to trillions of rogue planets. Scientists hope to learn more with new tools like the Nancy Grace Roman Space Telescope.

The chance of a rogue planet coming into our solar system or harming life on Earth is very small. Experts think it would happen about once in a trillion times over the next 1,000 years. So we do not need to worry about rogue planets visiting us soon.

Some of these objects might form like stars. The International Astronomical Union has suggested calling these sub-brown dwarfs. One example is Cha 110913−773444, which may have been thrown from a planetary system or formed on its own.

Terminology

Scientists have different names for planets that float alone in space, not tied to any star. Some call them isolated planetary-mass objects (iPMOs) or free-floating planets (FFPs). The term rogue planet is often used when studying these planets. You might also hear them called starless planets or wandering planets, especially in news stories. In 2021, scientists found about 70 of these lonely planets.

Discovery

Isolated planets, called isolated planetary-mass objects, were first found in 2000. A team from the United Kingdom used a telescope called UKIRT to spot them in the Orion Nebula. Around the same time, a team from Spain used another telescope, Keck, to find similar objects in a group of stars called the σ Orionis cluster. In 1999, a team from Japan found objects in Chamaeleon I, which were confirmed later in 2004 by a team from the United States.

Observation

There are two main ways scientists look for rogue planets. One way is called microlensing. In 2011, scientists watched many stars and saw some get dimmer for a short time. This happens when a rogue planet passes in front of a star, like a magnifying glass. They think there may be more rogue planets than stars in our galaxy.

115 potential rogue planets in the region between Upper Scorpius and Ophiuchus (2021)

Another way to find rogue planets is by taking pictures of them. Scientists look at young areas where stars are born because these areas help them learn the age of objects. Some of these objects might be rogue planets that were thrown out of their solar systems. Scientists have found many of these objects. Some even have companions, forming pairs or groups. These discoveries help us learn more about rogue planets.

Main article: Microlensing Observations in Astrophysics

Formation

There are two main ways a rogue planet can form. One way is that it starts forming like a normal planet around a star but then gets pushed away into space. The other way is that it forms on its own, similar to how very small stars form, without needing a star nearby.

Recent studies show that rogue planets can form either by being thrown out of their original solar systems or by forming alone in clouds of gas and dust. Many of these planets probably began in solar systems before being pushed out, while others might form completely by themselves.

Fate

Most isolated planets float through space forever, never getting close to another star or planet. Very rarely, a planet might pass near a planetary system. When this happens, a few things can happen: the planet might stay free, it might get pulled a little by a star, or it might push another planet away. Usually, these planets get pulled just enough to travel a very long, stretched-out path around the star. But these paths don't last, and most of these planets get pushed back out into space again. Only a very small number of stars might hold onto one of these wandering planets for a short time.

Warmth

Artist's conception of a Jupiter-size rogue planet

Interstellar planets do not get much heat and are not warmed by a star. In 1998, a scientist named David J. Stevenson thought that some of these drifting planets might keep a thick atmosphere that does not freeze. He believed this could happen because of the special properties of a thick atmosphere that contains hydrogen.

When planets are thrown out of their solar systems, they receive less ultraviolet light. This helps keep their atmospheres intact. Even a planet about the size of Earth could hold onto gases like hydrogen and helium. The heat from deep inside the planet could keep its surface warm enough for liquid water to exist. These planets might stay active for a very long time. If they have strong magnetic fields and volcanic activity under the oceans, they might provide energy that could support life. However, these planets are hard to spot because they give off very little heat. We might detect them if they are close enough to Earth, using light reflected from the Sun or heat they give off in a special type of light called far-infrared.

List

The table below shows rogue planets that scientists think they have found. We do not yet know if these planets were thrown out of a solar system or if they formed all by themselves, far away from any star.

These planets were found using different methods. Some were spotted directly using telescopes. Others were discovered using a method called microlensing, where the gravity of the planet bends light from stars behind it, acting like a magnifying glass. These planets can only be studied during the short time when this bending of light happens.

Exoplanet	Mass (M_J)	Age (Myr)	Distance (ly)	Spectral type	Status	Stellar assoc. membership	Discovery
OTS 44	~11.5	0.5–3	554	M9.5	Likely a low-mass brown dwarf	Chamaeleon I	1998
S Ori 52	2–8	1–5	1,150		Age and mass uncertain; may be a foreground brown dwarf	σ Orionis cluster	2000
Proplyd 061-401	~11	1	1,344	L4–L5	Candidate, 15 candidates in total from this work	Orion nebula	2001
S Ori 70	3	3	1150	T6	interloper?	σ Orionis cluster	2002
Cha 110913-773444	5–15	2~	529	>M9.5	Confirmed	Chamaeleon I	2004
SIMP J013656.5+093347	11-13	200~	20–22	T2.5	Candidate	Carina-Near moving group	2006
Cha 1107−7626	6–10	1–5	620	L0–L1	Confirmed	Chamaeleon I	2008
UGPS J072227.51−054031.2	0.66–16.02	1000 – 5000	13	T9	Mass uncertain	none	2010
M10-4450	2–3	1	325	T	Candidate	rho Ophiuchi cloud	2010
WISE 1828+2650	3–6 or 0.5–20	2–4 or 0.1–10	47	>Y2	candidate, could be binary	none	2011
WISE 0825+2805	3.7±0.2	414±23	21.4±0.3	Y0.5	Candidate; age is assumed based on probable moving group association. The mass and radius depends on the object's age.	Corona of Ursa Major moving group	2015
CFBDSIR 2149−0403	4–7	110–130	117–143	T7	Candidate	AB Doradus moving group	2012
SONYC-NGC1333-36	~6	1	978	L3	candidate, NGC 1333 has two other objects with masses below 15 M_J	NGC 1333	2012
SSTc2d J183037.2+011837	2–4	3	848–1354	T?	Candidate, also called ID 4	Serpens Core cluster (in the Serpens Cloud)	2012
PSO J318.5−22	6.24–7.60	21–27	72.32	L7	Confirmed; also known as 2MASS J21140802-2251358	Beta Pictoris Moving group	2013
2MASS J2208+2921	11–13	21–27	115	L3γ	Candidate; radial velocity needed	Beta Pictoris Moving group	2014
WISE J1741-4642	4–21	23–130		L7pec	Candidate	Beta Pictoris or AB Doradus moving group	2014
WISE 0855−0714	3–10	>1,000	7.1	Y4	Age uncertain, but old due to solar vicinity object; candidate even for an old age of 12 Gyrs (age of the universe is 13.8 Gyrs). Closest known probable rogue planet	none	2014
2MASS J12074836–3900043	~15	7–13	200	L1	Candidate; distance needed	TW Hydrae association	2014
SIMP J2154–1055	9–11	30–50	63	L4β	Age questioned	Argus association	2014
SDSS J111010.01+011613.1	10.83–11.73	110–130	63	T5.5	Confirmed	AB Doradus moving group	2015
2MASS J11193254–1137466 AB	4–8	7–13	~90	L7	Binary candidate, one of the components has a candidate exomoon or variable atmosphere	TW Hydrae association	2016
WISEA 1147	5–13	7–13	~100	L7	Candidate	TW Hydrae association	2016
USco J155150.2-213457	8–10	6.907-10	104	L6	Candidate, low gravity	Upper Scorpius association	2016
Proplyd 133–353		0.5–1	1,344	M9.5	Candidate with a photoevaporating disk	Orion nebula	2016
Cha J11110675-7636030	3–6	1–3	520–550	M9–L2	Candidate, but could be surrounded by a disk, which could make it a sub-brown dwarf; other candidates from this work	Chamaeleon I	2017
PSO J077.1+24	6	1–2	470	L2	Candidate, work also published another candidate in Taurus	Taurus Molecular Cloud	2017
2MASS J1115+1937	6+8 −4	5–45	147	L2γ	has an accretion disk	Field, possibly ejected	2017
Calar 25	11–12	120	435		Confirmed	Pleiades	2018
2MASS J1324+6358	10.7–11.8	~150	~33	T2	unusually red and unlikely binary; robust candidate	AB Doradus moving group	2007, 2018
WISE J0830+2837	4-13	>1,000	31.3-42.7	>Y1	Age uncertain, but old because of high velocity (high Vtan is indicative of an old stellar population), Candidate if younger than 10 Gyrs	none	2020
2MASS J0718-6415	3 ± 1	16–28	30.5	T5	Candidate member of the BPMG. Extremely short rotation period of 1.08 hours, comparable to the brown dwarf 2MASS J0348-6022.	Beta Pictoris Moving group	2021
DANCe J16081299-2304316	3.1–6.3	3–10	104	L6	One of at least 70 candidates published in this work, spectrum similar to HR 8799c	Upper Scorpius association	2021
WISE J2255−3118	2.15–2.59	24	~45	T8	very red, candidate confirmed?	Beta Pictoris Moving group	2011, 2021
WISE J024124.73-365328.0	4.64–5.30	45	~61	T7	candidate	Argus association	2012, 2021
2MASS J0013−1143	7.29–8.25	45	~82	T4	binary candidate or composite atmosphere, candidate	Argus association	2017, 2021
SDSS J020742.48+000056.2	7.11–8.61	45	~112	T4.5	candidate	Argus association	2002, 2021
2MASSI J0453264-175154	12.68–12.98	24	~99	L2.5β	low gravity, candidate	Beta Pictoris Moving group	2003, 2023
CWISE J0506+0738	7 ± 2	22	104	L8γ–T0γ	Candidate member of the BPMG. Extreme red near-infrared colors.	Beta Pictoris Moving group	2023

Exoplanet	Mass (M_J)	Mass (M_🜨)	Distance (ly)	Status	Year of Announcement
OGLE-2012-BLG-1323L	0.0072–0.072	2.3–23		candidate; distance needed	2017
OGLE-2017-BLG-0560L	1.9–20	604–3,256		candidate; distance needed	2017
MOA-2015-BLG-337L	9.85	3,130	23,156	may be a binary brown dwarf instead	2018
OGLE-2017-BLG-1170L	3.06+1.34 −1.16		24,700	candidate	2019
OGLE-2017-BLG-1170L	1.85+0.79 −0.70		24,700	candidate	2019
OGLE-2016-BLG-1928L	0.001-0.006	0.3–2	30,000–180,000	candidate	2020
OGLE-2019-BLG-0551L	0.0242-0.3	7.69–95		Poorly characterized	2020
KMT-2019-BLG-2073L	0.19	59		candidate; distance needed	2020
VVV-2012-BLG-0472L	10.5	3,337	3,200		2022
MOA-9y-770L	0.07	22.3+42.2 −17.4	22,700		2023
MOA-9y-5919L	0.0012 or 0.0024	0.37+1.11 −0.27 or 0.75+1.23 −0.46	14,700 or 19,300		2023
KMT-2023-BLG-2669L	0.025–0.25	8–80		candidate; distance needed	2024
KMT-2024-BLG-0792L/OGLE-2024-BLG-0516L	0.219+0.075 −0.046	69.6+23.8 −14.6	3050+580 −430	candidate; planet could be either free-floating or on a very wide orbit	2026

Exoplanet	Mass (M_J)	Distance (ly)	Status	Stellar assoc. membership	Discovery
J1407b			Candidate ALMA detection; although the object's brightness and proximity is consistent with it being the same object that eclipsed the star V1400 Centauri in 2007, follow-up observations by ALMA are needed to confirm whether it is moving, let alone in the right direction.	none	2012, 2020