Encoding Electronic Spectra in Quantum Circuits with Linear T Complexity

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We construct quantum circuits which exactly encode the spectra of correlated electron models up to errors from rotation synthesis. By invoking these circuits as oracles within the recently introduced "qubitization" framework, one can use quantum phase estimation to sample states in the Hamiltonian eigenbasis with optimal query complexity O(\lambda / \epsilon) where \lambda is an absolute sum of Hamiltonian coefficients and \epsilon is target precision. For both the Hubbard model and electronic structure Hamiltonian in a second quantized basis diagonalizing the Coulomb operator, our circuits have T gate complexity O({N + \log (1/\epsilon})) where N is number of orbitals in the basis. This enables sampling in the eigenbasis of electronic structure Hamiltonians with T complexity O(N^3 /\epsilon + N^2 \log(1/\epsilon)/\epsilon). Compared to prior approaches, our algorithms are asymptotically more efficient in gate complexity and require fewer T gates near the classically intractable regime. Compiling to surface code fault-tolerant gates and assuming per gate error rates of one part in a thousand reveals that one can error correct phase estimation on interesting instances of these problems beyond the current capabilities of classical methods using only about a million superconducting qubits in a matter of hours.