Kepler-93b

Kepler-93b is a hot, dense transiting Super-Earth exoplanet located approximately away in the constellation of Lyra, orbiting the G-type star Kepler-93. Its discovery was announced in February 2014 by American astronomer Geoffrey Marcy and his team. In July 2014, its radius was determined with a mere 1.3% margin of error, the most precise measurement ever made for an exoplanet's radius at the time.

Physical properties

The planet has a radius of around 1.478, with an uncertainty of just 0.019, making it the most precisely measured exoplanet ever in terms of radius as of July 2014. The planet is substantially denser than Earth at thanks to its high mass of roughly 4, consistent with a rocky composition of iron and magnesium silicate. In 2023, the planet's mass was revised upward to 4.66, placing its density at 7.93 g/cm³, roughly the same as the metal iron.
Based on these findings, the interior of the planet is likely similar to that of Earth and Venus, with an iron core making up around 26% of its total mass, compared to the 32.5 ± 0.1% of Earth and 31 ± 1% of Venus.
The planet orbits its host star every 4.73 days at a distance of, less than one-seventh the radius of Mercury's orbit. Its equilibrium temperature is approximately, which is as hot as lava and well above the melting point of aluminium.

Host star

The planet orbits a Sun-like star named Kepler-93. The star has a mass of 0.911 and a radius of 0.919. It has a temperature of and is 6.6 billion years old. In comparison, the Sun is 4.6 billion years old, has a temperature of and a spectral type of G2V. The apparent magnitude of the star is 9.931, making it too dim to be visible from Earth by the naked eye.
The star is host to an additional non-transiting confirmed companion, Kepler-93c, which was discovered using the radial-velocity method and announced in 2014, concurrently with Kepler-93b. The object is most likely a brown dwarf orbiting much farther out than Kepler-93b, though its precise nature remains uncertain. The discovery paper reported a lower limit on the mass of 3 and a minimal orbital period of, while a subsequent study in 2015 weighed the planet at >8.5 and presented an orbital period of >10 years, placing its orbit beyond 4.5 AU from the star, and a 2023 study increased these lower limits further, to a mass >21, an orbital period >48.6 years, and a semi-major axis >13 AU.