Gevrey Smoothing for Weak Solutions of the Fully Nonlinear Homogeneous Boltzmann and Kac Equations Without Cutoff for Maxwellian Molecules

Abstract: Abstract. It has long been suspected that the non-cutoff Boltzmann operator has similar coercivity properties as a fractional Laplacian. This has led to the hope that the homogenous Boltzmann equation enjoys similar regularity properties as the heat equation with a fractional Laplacian. In particular, the weak solution of the fully nonlinear non-cutoff homogenous Boltzmann equation with initial datum in Le., finite mass, energy and entropy, should immediately become Gevrey regular for strictly positive times. … Show more

“…Remark 1.5. This regularity is much weaker than the Gevrey regularity we proved in [4] for singular kernels of the form (3), but it is much stronger than the H ∞ smoothing shown in [11]. Moreover, it is exactly the right type of regularity one would expect for a coercive term of the form (7) from the analogy with the heat equation (11).…”

“…starting with arbitrary initial datum f 0 ≥ 0, f 0 ∈ L 1 2 ∩ L log L, one has f (t, ·) ∈ H ∞ for any positive time t > 0. Based upon our recent proof [4] of Gevrey smoothing for the homogeneous Boltzmann equation with Maxwellian molecules and angular singularity of the inverse-power law type (3), we can show a stronger than H ∞ regularisation property of weak solutions in the Debye-Yukawa case.…”

“…In this case, the coercive effects are much weaker and of the form −Q(g, f ) ≈ (log(1 − ∆)) µ+1 f + lower order terms, (7) as was noticed in [11], see also appendix A. In this work, as in [4,11], we consider only the socalled Maxwellian molecules approximation, where the collision kernel does not depend on v − v * , but only on the collision angle θ.…”

“…(1) For the weights needed in the proof of Theorem 1.4 we have a much stronger enhanced subadditivity bound, see Lemma 2.1. The proof is more involved than the one in [4], though. (2) Because of the stronger form of the subadditivity bound, we can allow for a bigger loss in the induction step.…”

“…For non-power-type Fourier multipliers this commutator is considerably more complicated than the one encountered in the H ∞ smoothing case. To overcome this, we follow the strategy we developed in [4], where an inductive procedure was invented to control the commutation error, in order to prove the Gevrey smoothing conjecture in the Maxwellian molecules case.…”

Strong smoothing for the non-cutoff homogeneous Boltzmann equation for Maxwellian molecules with Debye-Yukawa type interaction

“…Remark 1.5. This regularity is much weaker than the Gevrey regularity we proved in [4] for singular kernels of the form (3), but it is much stronger than the H ∞ smoothing shown in [11]. Moreover, it is exactly the right type of regularity one would expect for a coercive term of the form (7) from the analogy with the heat equation (11).…”

“…starting with arbitrary initial datum f 0 ≥ 0, f 0 ∈ L 1 2 ∩ L log L, one has f (t, ·) ∈ H ∞ for any positive time t > 0. Based upon our recent proof [4] of Gevrey smoothing for the homogeneous Boltzmann equation with Maxwellian molecules and angular singularity of the inverse-power law type (3), we can show a stronger than H ∞ regularisation property of weak solutions in the Debye-Yukawa case.…”

“…In this case, the coercive effects are much weaker and of the form −Q(g, f ) ≈ (log(1 − ∆)) µ+1 f + lower order terms, (7) as was noticed in [11], see also appendix A. In this work, as in [4,11], we consider only the socalled Maxwellian molecules approximation, where the collision kernel does not depend on v − v * , but only on the collision angle θ.…”

“…(1) For the weights needed in the proof of Theorem 1.4 we have a much stronger enhanced subadditivity bound, see Lemma 2.1. The proof is more involved than the one in [4], though. (2) Because of the stronger form of the subadditivity bound, we can allow for a bigger loss in the induction step.…”

“…For non-power-type Fourier multipliers this commutator is considerably more complicated than the one encountered in the H ∞ smoothing case. To overcome this, we follow the strategy we developed in [4], where an inductive procedure was invented to control the commutation error, in order to prove the Gevrey smoothing conjecture in the Maxwellian molecules case.…”

Strong smoothing for the non-cutoff homogeneous Boltzmann equation for Maxwellian molecules with Debye-Yukawa type interaction

Regularity of the Vlasov–Poisson–Boltzmann System Without Angular Cutoff

The smoothing effect in sharp Gevrey space for the spatially homogeneous non-cutoff Boltzmann equations with a hard potential