Bridging Unstratified and Stratified Simulations of the Streaming Instability for $τ_s=0.1$ Grains (2505.23902v1)

Abstract: The streaming instability (SI), driven by aerodynamic coupling between solids and the gas under a global radial pressure gradient, concentrates solids and facilitates planetesimal formation. Unstratified simulations are commonly used to study the SI, based on the assumption that they approximate conditions near the disk midplane. However, it remains unclear how accurately these unstratified simulations capture the midplane dust-gas dynamics in stratified disks. To address this, we examine the saturated state of the SI in stratified simulations and compare dust-gas dynamics to those in unstratified simulations across various radial pressure gradients. To this end, we consider a dimensionless dust stopping time ($\tau_s$) of 0.1 and perform 2D axisymmetric, stratified simulations. We find that the formation of dust filaments during dust settling exhibits morphological similarities to those in unstratified simulations. In the saturated state, we find that as the pressure gradient increases, the velocity dispersions of the gas and dust, as well as the strength of dust diffusion, increase. Most importantly, at any given pressure gradient, the velocity dispersions and density distributions of the gas and dust in our stratified simulations closely match those in unstratified simulations. While further exploration across the parameter space is needed, our results suggest that, for $\tau_s=0.1$, unstratified simulations represents well the midplane dust--gas dynamics in stratified disks before any strong clumping occurs. Consequently, our results confirm that in the saturated state, the streaming turbulence in stratified simulations behaves similarly to that in unstratified simulations for the parameter values explored here.