Sulfur is the tenth most abundant element in the Universe and plays a crucial role in biological systems. Some sulfur compounds have even been proposed as essential catalysts for the formation of amino acids in space. However, while the cosmic budgets of carbon and oxygen are relatively well constrained, the gas-phase abundance of sulfur remains uncertain by several orders of magnitude. This prevents us from using sulfur as a reliable probe of star and planet formation.
In the Solar System, sulfur is widespread across planets and moons. It is found in solid form within Mercury’s polar regions, as sulfur oxides in the atmosphere of Venus, and as sulfate minerals across the surface of Mars. On Earth, it is present in nearly every environmental reservoir, atmosphere, oceans, rocks, and living organisms.
In the interstellar medium, however, many questions remain open about where sulfur is stored and in which molecular species. Even the relative amounts of sulfur in the gas and solid phases are poorly constrained. This is largely because the main reservoirs of sulfur are difficult to observe with current ground-based and space facilities. The SUL4LIFE project takes a decisive step toward solving the long-standing mystery of sulfur chemistry in space through an innovative approach built on three main pillars.
(i) We are building an unprecedented database of high-quality observations of sulfur-bearing molecules. This will allow us to trace how sulfur is distributed and transformed, from the earliest molecular clouds to the protoplanetary disks where planets take shape.
(ii) We are carrying out ab initio calculations and laboratory experiments to determine the key reaction rates that control sulfur chemistry. These results are crucial to refine chemical models and make them truly reliable.
(iii) We now know that the chemical composition of planet-forming disks is largely inherited from the very first stages of star formation. Advanced 3D bi-fluid (gas + dust) magneto-hydrodynamic simulations coupled with chemistry (chemo-MHD) tare used o follow the journey of matter from natal clouds all the way to planet-forming regions, enabling us to make accurate chemical predictions.
By combining these three approaches, SUL4LIFE will reveal how sulfur is incorporated into protoplanetary disks, a key step in understanding planet formation and, ultimately, the chemical origins of life.