Level 1 - Absolute Beginner
Scientists have found a new planet near our solar system. It is called Ross 318 b. It travels around a small, cool star called a red dwarf.
The planet is bigger than Earth. Scientists call planets like this a super-Earth. Ross 318 b is about six times heavier than our planet.
The planet is in what scientists call the habitable zone. This is the area around a star where it is not too hot and not too cold for liquid water to exist.
The star that Ross 318 b orbits is only 28 light years away from us. In space, that is very close to Earth. Scientists want to learn more about this planet to see if it could support life.
- planet
- a large round object that orbits around a star, such as Earth orbits the Sun
- orbit
- to travel in a curved path around another object, as Earth orbits the Sun
- super-Earth
- a planet that is larger and heavier than Earth but smaller than the ice giants Neptune and Uranus
- red dwarf
- a type of small, cool, dim star that is the most common kind of star in the Milky Way galaxy
- habitable zone
- the region around a star where temperatures allow liquid water to exist on a planet's surface
- light year
- the distance that light travels in one year, about 9.5 trillion kilometers
- mass
- the total amount of matter in an object, related to but not the same as weight
- telescope
- an instrument that makes distant objects appear larger and closer so scientists can study them
Level 2 - Elementary
Italian and Brazilian astronomers have announced the discovery of a new exoplanet called Ross 318 b. The planet orbits a red dwarf star named Ross 318, located just 28 light years from Earth in the constellation Cetus.
Ross 318 b is classified as a temperate super-Earth. It has a minimum mass of about 6.2 times that of Earth and an estimated radius of about 1.74 times Earth's radius. It takes the planet 39.63 days to complete one orbit around its star.
The planet's surface temperature is estimated to be around minus 36 degrees Celsius. This places it within the conservative habitable zone of the star, which means it receives enough starlight that water could stay liquid on its surface if certain conditions are met.
The discovery was announced in May 2026. Astronomers used a technique called the radial velocity method, which detects the tiny wobble that a planet's gravity creates in its host star. Scientists are hoping that future telescopes will be able to study the planet's atmosphere.
- exoplanet
- a planet that orbits a star other than our own Sun, outside our solar system
- radial velocity method
- a technique for detecting exoplanets by measuring the tiny Doppler shift in a star's light caused by the planet pulling the star slightly back and forth
- equilibrium temperature
- the estimated surface temperature of a planet calculated from the amount of starlight it receives, not accounting for a greenhouse effect
- constellation
- a group of stars that forms a recognizable pattern in the night sky as seen from Earth
- Kelvin
- a scientific unit for measuring temperature where 0 Kelvin is absolute zero; 237 Kelvin equals about minus 36 degrees Celsius
- conservative habitable zone
- the most cautiously defined region around a star where scientists are confident that liquid water could exist on a rocky planet's surface
- atmospheric characterization
- the process of identifying the gases present in a planet's atmosphere, usually done by analyzing the starlight that passes through it
- arXiv
- an online database where scientists can share research papers before they are officially published in a peer-reviewed journal
Level 3 - Intermediate
Italian and Brazilian astronomers have reported the detection of Ross 318 b, a temperate super-Earth orbiting the nearby M3.5 spectral-type red dwarf Ross 318, also catalogued as Gliese 48, at a distance of approximately 28 light years. The discovery paper was posted to arXiv in May 2026, reporting a minimum mass of 6.21 Earth masses, an estimated radius of 1.74 Earth radii, and an orbital period of 39.63 days at a semi-major axis of 0.16 AU.
The planet's equilibrium temperature is calculated at 237 Kelvin, assuming a bond albedo comparable to Earth's. This places Ross 318 b within the conservative habitable zone defined by Kopparapu et al. (2013), where liquid water could stably exist on the surface under an Earth-like atmosphere. The planet receives approximately 58 percent of the stellar radiation that Earth receives from the Sun.
The host star Ross 318 is a slowly rotating, low-luminosity red dwarf with an effective temperature of 3,450 Kelvin and a rotation period of approximately 51.5 days. Red dwarfs are attractive targets for habitable-zone searches because their low luminosity moves the habitable zone close to the star, giving orbiting planets short orbital periods that produce strong enough Doppler signals to detect from the ground.
Future characterization looks promising. At 28 light years, Ross 318 is close enough that the Habitable Worlds Observatory, currently in the design phase for a 2040s launch, might be able to image the planet directly. The ESPRESSO spectrograph at the VLT and the NEID spectrograph at the WIYN 3.5-meter telescope have been identified by the discovery team as suitable for further Doppler monitoring. Atmospheric studies would require first detecting a transit of the planet across its star.
- M3.5 spectral type
- a classification for a mid-range red dwarf star, with an effective temperature around 3,400 to 3,600 Kelvin and much lower luminosity than the Sun
- semi-major axis
- the average distance between a planet and its host star, equal to half the longest diameter of an elliptical orbit
- bond albedo
- the fraction of total incoming solar or stellar radiation that a planet reflects back into space across all wavelengths, affecting its surface temperature
- insolation
- the amount of stellar radiation received by a planet's surface, typically compared to Earth's value as a ratio
- Kopparapu habitable zone
- a widely used scientific definition of the region around a star where liquid water could exist on a rocky planet's surface, based on 2013 calculations by Ravi Kumar Kopparapu
- Doppler monitoring
- repeated measurements of a star's radial velocity over time to track the gravitational effect of an orbiting planet
- Habitable Worlds Observatory
- a large space telescope under study by NASA, designed to directly image Earth-like planets around nearby stars in the 2040s
Level 4 - Advanced
The detection of Ross 318 b via radial velocity monitoring adds a temperate super-Earth to a small but growing catalog of potentially habitable-zone planets within 30 light years of the Sun, alongside Proxima Centauri b, Wolf 1061 c, and GJ 667 Cc. The host star Ross 318 (Gliese 48, TIC 379084450) is an M3.5V flare star at 8.68 parsecs, with a V magnitude of 11.55 and a rotation period of 51.5 days, indicating relatively low stellar magnetic activity for a mid-M dwarf, which is favorable for habitable-zone searches because high flare frequency and elevated coronal X-ray flux can suppress atmospheric retention on close-in rocky planets.
The planet's reported parameters place it in the conservative habitable zone boundary described by Kopparapu et al. (2013): minimum mass M sin i = 6.21 Earth masses, orbital period P = 39.63 days, semi-major axis a = 0.16 AU, and equilibrium temperature T(eq) = 237 Kelvin at a bond albedo assumption of 0.30. The planet receives a stellar flux ratio of 0.58 relative to Earth, placing it well within the conservative limits. However, the unknown inclination introduces an M sin i ambiguity: if the true inclination is less than 30 degrees, the true mass could exceed 12 Earth masses, shifting the planet toward the mini-Neptune regime rather than the rocky-planet domain.
The discovery team employed HARPS archival radial velocity data from the La Silla 3.6-meter telescope combined with new CARMENES spectra from Calar Alto, constructing a 412-epoch baseline spanning 8.4 years. A Gaussian process regression was applied to suppress stellar activity signals with periods related to the 51.5-day rotation period and its harmonics, recovering the planetary signal at a false-alarm probability below 0.001 percent. The Bayesian information criterion marginally favors a one-planet model, though a mild periodogram excess near 22 days raises the possibility of a second short-period companion, to be addressed in a follow-up campaign.
The astrobiological interest of Ross 318 b is tempered by standard uncertainties attending M-dwarf habitable-zone candidates: synchronous or pseudo-synchronous rotation driven by tidal interaction could suppress habitability through atmospheric collapse on the permanent night side, though this outcome is contested for planets receiving greater than 0.5 stellar flux units; the absence of a confirmed transit geometry forecloses near-term atmospheric characterization by JWST or Ariel; and the unknown bulk composition prevents distinguishing a water world from a volatile-poor rocky planet. The Habitable Worlds Observatory, whose science requirements are being defined by Astro2020 decadal survey working groups, identifies 28-light-year proximity as near the inner boundary for coronagraphic direct imaging feasibility at a target signal-to-noise ratio of 15 in the visible band.
- M3.5V flare star
- a red dwarf of spectral subtype M3.5 that exhibits periodic magnetic eruptions producing brief, intense increases in ultraviolet and X-ray emission
