The young Beta Pictoris system, an iconic example of a circumstellar dust disc, continues to reveal new secrets about giant planet formation thanks to the enhanced capabilities of the GRAVITY+ instrument on the Very Large Telescope Interferometer (VLTI). Astronomers led by Antonia von Stauffenberg from the Max Planck Institute for Astronomy have employed this advanced interferometric technology to probe the atmospheric composition and potential variability of Beta Pictoris b, a massive gas giant orbiting its host star about 63 light-years away.
Beta Pic b, with an estimated mass of 11 times that of Jupiter, completes an orbit every 23 years at a distance of roughly 10 astronomical units (au). Previous observations using the original GRAVITY instrument suggested a low ratio of carbon isotopes—^12CO to ^13CO—in the planet’s atmosphere, hinting that it might have formed beyond the CO snowline where carbon monoxide exists mostly as ice. This scenario implied that the planet potentially migrated inward to its current position within the warmer inner disc, where CO should predominantly be gaseous.
However, the latest data acquired with GRAVITY+, which features upgraded adaptive optics and improved stability, paint a different picture. The team reports a significantly higher ^12CO/^13CO abundance ratio, one that aligns well with isotopic ratios found in the Solar System and the broader interstellar medium. This finding places Beta Pic b’s origin inside the CO snowline, consistent with its current orbit and challenging previous assumptions about large planetary migrations in this system.
The detection of ^13CO required sophisticated analysis due to its faint signal, but its measurement alongside ^12CO underscores GRAVITY+’s extraordinary data quality. In addition to composition, the team observed subtle photometric variations likely linked to Beta Pic b’s rotation period of approximately 8.7 hours, hinting at dynamic atmospheric phenomena such as cloud patterns or chemical weather. While these variations need confirmation through more sensitive follow-up studies, they mark a fascinating glimpse into the atmospheric complexity of a young exoplanet.
Despite these advances, the study raises questions about the utility of carbon isotope ratios as clear tracers of planetary birthplaces. The homogeneity of measured ^12CO/^13CO ratios among numerous young gas giants suggests that the ratio may not reliably differentiate between formation zones inside or outside the snowline. Scientists suspect that current models of CO ice chemistry in protoplanetary discs lack crucial physics, preventing precise interpretation of isotope data as indicators of planetary origins.
This insight underscores the complexity of planet formation and the challenges inherent in decoding the histories of distant worlds. Nevertheless, GRAVITY+ stands out as a powerful instrument poised to revolutionize exoplanet characterization with its unparalleled precision. As researchers continue refining observational techniques and theoretical models, tools like GRAVITY+ are likely to unlock new avenues for understanding giant planet formation and atmospheric dynamics in young planetary systems.
The study exemplifies a step forward in planetary science, showing how cutting-edge instrumentation can refine and sometimes overturn prevailing interpretations. Beta Pictoris b remains a tantalizing laboratory for investigating the processes that shape planetary systems, and with continued observations, astronomers move closer to unraveling the complex interplay of chemistry, dynamics, and formation history written in exoplanet atmospheres.
Subject of Research: Not applicable
Article Title: 13CO and potential variability in β Pictoris b with GRAVITY+
News Publication Date: 9-Jul-2026
Web References: DOI: 10.1051/0004-6361/202660275
Image Credits: ESO/L. Calçada
Keywords: Beta Pictoris b, exoplanets, planet formation, circumstellar discs, carbon isotopes, GRAVITY+, Very Large Telescope Interferometer, atmospheric variability

