Large Scale Optimization of Disordered Hubbard Models through Tensor and Neural Networks

Abstract

We theoretically demonstrate a practical method for tuning randomly disordered 2D quantum-dot grids underlying spin qubit platforms using vision-based neural networks trained on tensor-network generated charge-stability data. We show that a simulatable local 3× 3 window already contains sufficient information to tune the central dot within a much larger array, thereby validating a sliding-window approach in which one tunes a local region and then translates that window across the lattice to calibrate a larger device. This avoids the computationally intractable necessity for obtaining the ground states for large systems with exponentially large Hilbert space. For the experimentally relevant case where only the on-site disorder is unknown, the neural network predicts the relevant parameters with very high fidelity in the 3× 3 setting [R2 >0.99], and after fine tuning on only a small number of larger-device samples, it retains high accuracy for the central dot of a 5× 5 plaquette [R2≈ 0.98]. When all the dots parameters are treated as unknown, prediction of the on-site disorder remains robust [R2>0.9 for both 3× 3 and 5× 5], although the remaining parameters are substantially more difficult to infer from the same charge-stability data. This shows that the most practically important disorder parameter for tuning can still be inferred reliably even in the fully disordered setting for the computationally difficult 5x5 arrays.