It is known that for a possibly degenerate hypoelliptic Ornstein-Uhlenbeck operator $$ L= \frac{1}{2}\text{ tr} (QD^2 ) + \langle Ax, D \rangle = \frac{1}{2}\text{ div} (Q D ) + \langle Ax, D \rangle,\;\; x \in \R^N, $$ all (globally) bounded solutions of $Lu=0$ on $\R^N$ are constant if and only if all the eigenvalues of $A$ have non-positive real parts (i.e., $s(A) \le 0)$. We show that if $Q$ is positive definite and $s(A) \le 0$, then any non-negative solution $v$ of $Lv=0$ on $\R^N$ which has at most an exponential growth is indeed constant. Thus under a non-degeneracy condition we relax the boundedness assumption on the harmonic functions and maintain the sharp condition on the eigenvalues of $A$. We also prove a related one-side Liouville theorem in the case of hypoelliptic Ornstein-Uhlenbeck operators.
One-side Liouville theorems under an exponential growth condition for Kolmogorov operators
enrico priola
2024-01-01
Abstract
It is known that for a possibly degenerate hypoelliptic Ornstein-Uhlenbeck operator $$ L= \frac{1}{2}\text{ tr} (QD^2 ) + \langle Ax, D \rangle = \frac{1}{2}\text{ div} (Q D ) + \langle Ax, D \rangle,\;\; x \in \R^N, $$ all (globally) bounded solutions of $Lu=0$ on $\R^N$ are constant if and only if all the eigenvalues of $A$ have non-positive real parts (i.e., $s(A) \le 0)$. We show that if $Q$ is positive definite and $s(A) \le 0$, then any non-negative solution $v$ of $Lv=0$ on $\R^N$ which has at most an exponential growth is indeed constant. Thus under a non-degeneracy condition we relax the boundedness assumption on the harmonic functions and maintain the sharp condition on the eigenvalues of $A$. We also prove a related one-side Liouville theorem in the case of hypoelliptic Ornstein-Uhlenbeck operators.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
