A pair of recent Monte Carlo studies have reported evidence for and against a crossover from weak-to strongdisorder criticality in the one-dimensional dirty boson problem. The Monte Carlo analyses rely on measurement of two observables: the effective Luttinger parameter K eff and the superfluid susceptibility χ . The former quantity was previously calculated analytically, using the strong-disorder renormalization group (SDRG), by Altman, Kafri, Polkovnikov, and Refael. Here, we use an extension of the SDRG framework to find a nonuniversal anomalous dimension η sd characterizing the divergence of the susceptibility with system size, χ ∼ L 2−η sd . We show that η sd obeys the hyperscaling relation η sd = 1/2K eff . We also identify an important obstacle to measuring this exponent on finite-size systems and comment on the implications for numerics and experiments. Disordered bosonic systems pose theoretical challenges because of the unique pathologies of their noninteracting limits: At low temperatures, bosons condense into a localized single-particle state, forming a configuration that is intrinsically unstable to interactions. Therefore, Giamarchi and Schulz pioneered the study of the so-called "dirty boson problem" by perturbing a strongly interacting one-dimensional system with weak disorder. They identified a superfluidinsulator transition, belonging to the Kosterlitz-Thouless (KT) universality class, at which disorder is perturbatively irrelevant, 1 see also Refs. 2,3. It was long believed that this universality always characterizes the one-dimensional transition. In the past decade, the possibility has emerged that a novel criticality, also of KT type but with certain nonuniversal disorder-dependent features, takes over at sufficiently strongdisorder strength. This "strong-disorder criticality," first proposed by Altman, Kafri, Polkovnikov, and Refael, 4-6 remains unconfirmed.7 Recent Monte Carlo results by Hrahsheh and Vojta may provide evidence of the crossover between the two types of universality, 8 while calculations by Pielawa and Altman support the existence of a strong-disorder fixed point. 9 Meanwhile, experimental advances in various contexts, including cold atoms, spin systems, and dirty superconductors, have made it especially urgent to gain a better theoretical understanding of the seemingly universal properties of the dirty boson problem. [10][11][12][13][14][15] In this Rapid Communication, we extend the analysis of the universal aspects of the one-dimensional (1D) superfluidinsulator transition in the strong-disorder regime. In particular, we analytically calculate the superfluid susceptibility near the transition. This affords us a different perspective on recent numerical developments and allows us to clarify their relationship with the theoretical strong-disorder renormalization group (SDRG) framework. The model that we concentrate on is the particle-hole symmetric rotor modelThis model can describe a 1D array of superconducting islands connected by Josephson junctions, and we assume stron...
