A new View of Young galaxies with ALMA and JWST

Most of the stars in the Universe formed billions of years ago, at a time when young galaxies were enshrouded in thick blankets of cosmic dust. This dust hides the very light that astronomers rely on to trace how galaxies grow. For decades, this has made it extremely difficult to understand how early galaxies assembled their stars.

The situation has improved dramatically in recent years thanks to two revolutionary observatories: the Atacama Large Millimeter/submillimeter Array (ALMA) and the James Webb Space Telescope (JWST). ALMA can detect the dust and cold gas that fuel star formation, while JWST has the power to pierce through dust and reveal the hidden stars themselves. Together, they offer—for the first time—the possibility of building a complete picture of galaxy growth in the early Universe.

The VOYAJ project (“A new View of Young galaxies with ALMA and JWST”) is designed to seize this unique opportunity. Its objectives are threefold:

- Reveal the hidden stellar populations in dusty galaxies that dominated cosmic star formation about 10 billion years ago.

- Trace the fuel for star formation by directly detecting the cold molecular gas in these galaxies, using the most reliable tracers.

- Push these studies to the cosmic dawn, less than one billion years after the Big Bang, when the first massive galaxies emerged.

Already within the first reporting period, VOYAJ has made major progress toward these goals. Using JWST, we directly detected the underlying stars in heavily dust-obscured galaxies for the first time, solving a decades-old observational challenge. On the gas side, we carried out the first empirical tests of alternative gas tracers ([CI] versus CO) on homogeneously selected distant galaxies, providing essential calibrations for future large surveys. Perhaps most strikingly, we discovered the most distant dynamically cold disk galaxy ever observed—a rotating structure already in place just 700 million years after the Big Bang.

By combining these breakthroughs, the project is on its way toward building the first truly high-definition view of young galaxies across cosmic time. The expected impact of VOYAJ is to transform our picture of galaxy evolution: showing how galaxies built their stars, acquired and regulated their gas, and developed the ordered structures we see in the present-day Universe. In doing so, it addresses one of the most fundamental questions in astrophysics: how did galaxies like our own come to be?

During this reporting period, the project has made substantial progress across all three work packages, leveraging new observations from ALMA and JWST as well as methodological innovations.

Revealing hidden stellar populations: Using JWST imaging in combination with existing ALMA data, we directly detected the underlying stars in heavily dust-obscured galaxies for the first time (Hodge et al. 2025). This breakthrough overcomes a decades-old limitation in the study of galaxy evolution. In parallel, we developed and tested a novel resolved spectral energy distribution (SED) fitting technique (Li et al. 2024), which allows us to construct spatially resolved maps of stellar and dust emission. Ongoing work applies this methodology to the newly observed dusty galaxies, shedding new insight into the internal structure and formation of vigorously star-forming galaxies at z ~ 2–3.

Tracing the molecular gas: A major activity has been the analysis of molecular gas reservoirs using CO and [CI] emission. In Frias Castillo et al. (2025), we presented one of the first direct comparisons of these tracers in unlensed high-redshift dusty galaxies, demonstrating the potential of [CI] as an alternative gas mass indicator. In Boogaard et al. (2025), we applied the innovative TUNER radiative transfer framework to the well-studied galaxy GN20, enabling self-consistent modeling of its CO and dust emission. This represents an important methodological advance, replacing simple multi-component models with a physically motivated gas density distribution. Ongoing work extends the cold gas observations to a statistically significant sample of distant galaxies.

Pushing to the earliest epochs: At z > 7, we mapped [CII] emission on sub-kiloparsec scales in the galaxy REBELS-25, revealing the most distant dynamically cold disk galaxy known to-date (Rowland et al. 2024). This result demonstrates that ordered rotating structures were already in place only 700 million years after the Big Bang, challenging models of early galaxy assembly. Ongoing work is extending these studies with complementary CO observations and dedicated JWST imaging.

Together, these activities mark major steps toward the project’s overall objectives: to build the first complete, high-resolution picture of how young galaxies formed their stars, acquired their gas, and developed their structures across cosmic time.

The project has already delivered several advances that move the field significantly beyond the state of the art.

Hidden stellar populations: By combining JWST and ALMA data, we achieved the first reliable detections of the stellar populations in dusty, star-forming galaxies (Hodge et al. 2025). This breakthrough overcomes a decades-old limitation and enables accurate morphological characterization and stellar mass measurements in galaxies that dominate cosmic star formation.

New methodologies: We developed a resolved SED-fitting framework (Li et al. 2024) that maps stars and dust within galaxies on sub-kiloparsec scales, and introduced the TUNER radiative transfer model (Boogaard et al. 2025), which uses a physically motivated gas density distribution with minimal free parameters. Both represent major methodological advances with broad relevance.

Gas mass tracers: Our comparison of CO and [CI] emission in unlensed galaxies at high redshift (Frias Castillo et al. 2025) provides one of the first empirical calibrations of [CI] as a molecular gas tracer, a critical step for advancing our understanding of how galaxies fuel their star formation.

Earliest disk galaxy: At z > 7, we discovered the most distant dynamically cold disk yet observed (Rowland et al. 2024). The presence of an ordered rotating structure so soon after the Big Bang was unexpected, and it reshapes models of early galaxy assembly.

Together, these results strengthen European leadership in early-Universe astronomy and provide new tools for the community. Looking forward, further expansion of the galaxy samples, continued development of modeling frameworks, and access to facilities such as ALMA and JWST will be key to ensuring full impact and uptake.