The Streaming Instability in 3D: Conditions for Strong Clumping

Abstract

The streaming instability (SI) is a leading mechanism for planetesimal formation, driving the aerodynamic concentration of solids in protoplanetary disks. The SI triggers strong clumping (i.e., strong enough for clumps to collapse) when the solid-to-gas column density ratio, Z, exceeds a threshold, . This threshold depends on the dimensionless stopping time, τs. Although the strong-clumping threshold has been explored over the last decade, it has been determined largely through 2D axisymmetric simulations. In this work, we perform a suite of 3D, vertically stratified simulations to establish a clumping threshold across 10-3 ≤ τs ≤ 1.0. Additionally, we study SI-driven concentration that is unique to 3D. We find that is as low as ≈ 0.002 at τs=0.1 and exceeds ≈ 0.03 at τs=10-3. Compared to 2D, our 3D results yield lower for τs > 0.02, but higher for τs ≤ 0.02, with a sharp transition between τs = 0.02 and 0.03. This transition correlates with midplane density ratio (ε): ε < 1 where 3D gives lower thresholds, and ε > 1 where 3D gives higher thresholds. We also find a filaments-in-filaments structure when ε < 1, which enhances clumping compared to 2D. By contrast, when ε > 1 and τs ≤ 0.03, dust filaments in 3D do not drift inward, suppressing filament mergers and strong clumping. In 2D, filaments drift inward regardless of ε, triggering strong clumping easier in this regime. Our results underscore the necessity of 3D simulations for accurately capturing SI-driven concentration and building the strong-clumping threshold.