G. Fénisse, D.V. Bekaert, P.-H. Blard, J. Duprat, I. Mattia, M. Genge, M.D. Suttle, O. Barres, C. Engrand, Y. Marrocchi.

Earth and Planetary Science Letters
Volume 663, 1 August 2025, 119396

Voir en ligne :https://doi.org/10.1016/j.epsl.2025.119396

Abstract: Interplanetary dust particles (IDPs) and micrometeorites (MMs), from 1 µm to 5 mm, are the primary source of extraterrestrial (ET) material currently accreted on Earth. The flux of ET particles smaller than ∼50 µm is typically determined through optical counting, but it remains uncertain and may deviate from predictions made by numerical simulations. The volatile element content carried by this flux is still not well-constrained and is influenced by the potential effects of atmospheric heating.
We developed a clean, pressurized system to extract cosmic dust from ∼38 kg of clean snow collected near the Concordia station (Dome C, Antarctica). We measured helium isotope concentrations in various granulometric fractions (> 62 µm, 25–62 µm, 5–25 µm and < 5 µm). The inferred global 3HeET annual flux is (1.25±0.03) × 10⁻¹² ccSTP·cm⁻²·ka⁻¹ (weighted mean±1SD), consistent with previous 3HeET flux estimates from marine sediments and polar samples. Our data shows that the majority of the 3HeET flux (70 %) is carried by particles in the 5–25 µm size range, with 20 % attributed to the 25–62 µm fraction. Using an empirical relationship between 3HeET concentrations and cosmic particle mass, we convert these fluxes into a global ET mass flux for particle diameters < 100 µm of (3.5±0.5) kilotons·a⁻¹ (weighted mean±1SD). This result is about 3 times higher than collection estimates from (Rojas et al., 2021) and aligns with CABMOD-ZoDy modeling, after atmospheric entry (Carrillo-Sánchez et al., 2020). This 3HeET method is suited for detecting particles smaller than 100 µm, while collection results are more relevant for larger fractions.