Feynman--Kac formula for the heat equation with a one-center point interaction in $d=3$
Abstract: We study Schrödinger operators with a one-center point interaction, formally defined by \begin{align*} -Δα=-Δ+α\,δ_0(\cdot), \end{align*} for $α\in\mathbb{R}$, and the associated heat equation \begin{align} \partial_t u=\tfrac{1}{2}Δα u,\quad u(0,x)=u_0(x)\in C_c{\infty}(\mathbb{R}3\setminus{0}).\label{eq:HEapp} \end{align} Here $Δ$ denotes the Laplacian (self-adjoint on $L2(\mathbb{R}3)$) and $δx$ the Dirac measure at $x$. The operator $-Δα$ can be realized either as a self-adjoint extension of $-Δ|{C_0{\infty}(\mathbb{R}3\setminus{0})}$ in $L2(\mathbb{R}3)$, or as the norm-resolvent limit of $-Δ+λ\varepsilon V(\cdot/\varepsilon)$ for suitable $λ_\varepsilon$ and $V:\mathbb{R}3\to\mathbb{R}$. In this paper we construct, for each $t>0$ and $x\in\mathbb{R}3\setminus{0}$, a probability law on path space and a normalizing function $G_tα(x)$ giving the following probabilistic representation of the solution to the associated equation: \begin{align*} u(t,x)=G_tα(x)\,\mathbb{E}\bigl[u_0\bigl(W{t,x}(t)\bigr)\bigr], \end{align*} where ${W{t,x}(s):0\le s\le t}$ is a continuous process depending on $(t,x,α)$. The result provides a Feynman--Kac type formula for the heat equation with a one-point interaction in three dimensions.
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