Measurement-induced phase transition in a single-body tight-binding model

We study the statistical properties of a single free quantum particle evolving coherently on a discrete lattice in $d$ spatial dimensions where every lattice site is additionally subject to continuous measurement of the occupation number. Using perturbative renormalization group (RG) analysis, we show that the systems undergoes a Measurement-induced Phase Transition (MiPT) for $d>2$ from a $\textit{delocalized}$ to a $\textit{localized}$ phase as the measurement strength $\gamma$ is increased beyond a critical value $\gamma_{c}$. In the language of surface growth, the delocalized phase corresponds to a $\textit{rough}$ phase while the localized phase corresponds to a $\textit{smooth}$ phase. We support our analytical computations with numerical analysis which are in qualitative and quantitative agreement with the theory.