The search for exomoons – moons orbiting planets outside our solar system – is a challenging but potentially rewarding
endeavor. These celestial bodies could offer valuable insights into planet formation, the history of planetary
migration, and even the possibility of habitable environments beyond Earth. However, detecting these relatively small
objects at vast distances requires innovative observational techniques. A new study proposes a novel approach: building
an interferometer with significantly longer baselines than existing instruments.
Interferometry, in essence, combines the light collected by multiple telescopes to create a virtual telescope with a
much larger aperture. This increased aperture translates to higher resolution, allowing astronomers to discern finer
details and detect fainter objects. The Very Large Telescope Interferometer (VLTI), for example, links several
telescopes at the European Southern Observatory (ESO) in Chile. However, the new study suggests that an interferometer
with baselines extending kilometers – far beyond the VLTI's current capabilities – could dramatically improve exomoon
The core of the proposed method relies on astrometry, the precise measurement of the positions and motions of stars and
other celestial objects. As a planet orbits a star, the star itself exhibits a slight wobble due to the planet's
gravitational pull. Similarly, if a planet has a moon, the planet will also wobble slightly as it orbits the common
center of mass. This wobble, though minuscule, can be detected through extremely precise astrometric measurements. The
study suggests that an interferometer capable of achieving an astrometric precision of 1 microarcsecond (μas) would be
able to detect Earth-mass and even sub-Earth-mass exomoons orbiting Jupiter-like planets at distances of 50 to 200
parsecs from Earth. A parsec is a unit of distance commonly used in astronomy, equivalent to about 3.26 light-years.
Therefore, this new technology could potentially find exomoons hundreds of light years away.
This proposed instrument wouldn't directly image the exomoons. Instead, it would infer their existence from the subtle
wobble they induce in their host planets. This method is particularly effective for detecting moons orbiting large
planets, as their greater gravitational influence makes the wobble more pronounced. The target planets are Jupiter-like
because larger planets exert a greater gravitational influence on their moons, making the 'wobble' more pronounced and
easier to detect. Detecting smaller, Earth-sized planets and their moons presents a significantly greater challenge.
The ability to detect Earth-mass and sub-Earth-mass exomoons is particularly exciting because it opens up the
possibility of finding potentially habitable environments. While Jupiter-like planets themselves are unlikely to harbor
life, their moons could, under certain circumstances, possess liquid water and other conditions conducive to life.
Europa, one of Jupiter's moons in our own solar system, is a prime example of a moon with a subsurface ocean that could
potentially support life. Learning more about the search for habitable zones is therefore highly relevant.
While the study presents a promising avenue for exomoon detection, it's essential to acknowledge the limitations.
Building and operating a kilometric baseline interferometer would be a technologically complex and expensive
undertaking. Furthermore, even with such an instrument, detecting exomoons will remain a challenging task, requiring
extremely precise measurements and sophisticated data analysis. Another important factor is the dynamic stability of the
exomoon's orbit. The study focuses on exomoons in dynamically stable orbits, meaning that their orbits are not disrupted
by gravitational interactions with other planets or stars in the system. However, many exoplanetary systems are
dynamically complex, and it's not always clear whether a moon can maintain a stable orbit for extended periods.
Despite these challenges, the prospect of detecting exomoons and exploring their potential for habitability makes the
development of new observational techniques a worthwhile pursuit. An interferometer with kilometer-long baselines could
represent a significant step forward in our search for these elusive objects, potentially revolutionizing our
understanding of planetary systems and the distribution of potentially habitable environments in the universe.
Understanding the broader field of exoplanet exploration provides context for these advancements.