Quantum linear algebra for disordered electrons

We describe how to use quantum linear algebra to simulate a physically realistic model of disordered non-interacting electrons on exponentially many lattice sites. The physics of disordered electrons outside of one dimension challenges classical computation due to the critical nature of the Anderson localization transition or exponential localization lengths, while the atypical distribution of the local density of states limits the power of disorder averaged approaches. We overcome this by simulating an exponentially large disorder instance using a block-encoded hopping matrix of physical form where disorder is introduced by pseudorandom functions. Key physical quantities, including the reduced density matrix, Green's function, and local density of states, as well as bulk-averaged observables such as the linear conductivity, can then be computed using quantum singular value transformation, quantum amplitude estimation, and trace estimation.