Non-uniqueness of (Stochastic) Lagrangian Trajectories for Euler Equations
Abstract
We are concerned with the (stochastic) Lagrangian trajectories associated with Euler or Navier-Stokes equations. First, in the vanishing viscosity limit, we establish sharp non-uniqueness results for positive solutions to transport equations advected by weak solutions of the 3D Euler equations that exhibit kinetic energy dissipation with Ct,x1/3- regularity. As a corollary, in conjunction with the superposition principle, this yields the non-uniqueness of associated (deterministic) Lagrangian trajectories. Second, in dimension d≥2, for any 1p+1r>1 or p∈(1,2),r=∞, we construct solutions to the Euler or Navier-Stokes equations in the space LtrLp Lt1W1,1, demonstrating that the associated (stochastic) Lagrangian trajectories are not unique. Our result is sharp in 2D in the sense that: (1) in the stochastic case, for any vector field v∈ CtLp with p>2, the associated stochastic Lagrangian trajectory associated with v is unique (see KR05); (2) in the deterministic case, the LPS condition guarantees that for any weak solution v∈ CtLp with p>2 to the Navier-Stokes equations, the associated (deterministic) Lagrangian trajectory is unique. Our result is also sharp in dimension d≥2 in the sense that for any divergence-free vector field v∈ Lt1W1,s with s>d, the associated (deterministic) Lagrangian trajectory is unique (see CC21).
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