Abstract
Finite-size error (FSE), the discrepancy between an observable in a finite system and in the thermodynamic limit, is ubiquitous in numerical simulations of quantum many body systems. Although a rough estimate of these errors can be obtained from a sequence of finite-size results, a strict, quantitative bound on the magnitude of FSE is still missing. Here we derive rigorous upper bounds on the FSE of local observables in real time quantum dynamics simulations initialized from a product state. In $d$-dimensional locally interacting systems with a finite local Hilbert space, our bound implies $ |\langle \hat{S}(t)\rangle_L-\langle \hat{S}(t)\rangle_\infty|\leq C(2v t/L)^{cL-\mu}$, with $v$, $C$, $c$, $\mu $ constants independent of $L$ and $t$, which we compute explicitly. For periodic boundary conditions (PBC), the constant $c$ is twice as large as that for open boundary conditions (OBC), suggesting that PBC have smaller FSE than OBC at early times. The bound can be generalized to a large class of correlated initial states as well. As a byproduct, we prove that the FSE of local observables in ground state simulations decays exponentially with $L$, under a suitable spectral gap condition. Our bounds are practically useful in determining the validity of finite-size results, as we demonstrate in simulations of the one-dimensional (1D) quantum Ising and Fermi-Hubbard models.
Highlights
Numerical simulations are crucial to our understanding of many-body quantum matter, and are routinely applied in all fields of physics and in chemistry
While our main focus is on dynamics, we show that the Finite-size errors (FSEs) of local observables in a many-body ground state decays
We have presented a rigorous upper bound on the FSE of local observables measured in numerical simulations of quantum dynamics starting from a large class of initial states
Summary
Numerical simulations are crucial to our understanding of many-body quantum matter, and are routinely applied in all fields of physics and in chemistry. The bounds are reasonably tight: The time at which the error bound becomes significant is only 20–25% smaller than the time at which the actual FSE becomes noticeable We demonstrate this for the nonequilibrium relaxation of the Fermi-Hubbard model (FHM) from a checkerboard state, inspired by experiments and theory of Refs. If one compares PBCs to OBCs with center site measurements, our error bound for PBCs decays twice as fast with distance as the bound for OBCs at early times, suggesting that PBCs give more reliable results at early times [67] These insights may lead to new methods; one example is that they show why the moving-average cluster expansion method of Ref. These insights may lead to new methods; one example is that they show why the moving-average cluster expansion method of Ref. [30] converges exponentially faster than alternative schemes
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