Ziyun Chen, Jerry Li (Sep 26 2025).

Abstract: We consider the problem of learning Hamiltonians from time evolution: given the ability to apply $e^{-iHt}$ for an unknown Hamiltonian on $n$ qubits, the goal is to recover the parameters of $H$. This is a well-studied problem in quantum learning theory, with applications to quantum metrology, sensing, device benchmarking, and many-body physics. For this problem, we demonstrate the first lower bounds which scale with the number of parameters of the unknown Hamiltonian. When the unknown Hamiltonian is arbitrary, we show that learning to error $\epsilon$ requires $2^{(1/2 - o(1))n} / \epsilon$ rounds of interaction with the Hamiltonian. If the Hamiltonian is additionally assumed to be $k$-local, we show that learning to constant error requires $n^{\Omega (k)}$ rounds of interaction with the Hamiltonian, resolving an open question of Tang. These bounds immediately imply that any learning algorithm with inverse polynomial time resolution requires super-polynomial total evolution time. Our lower bounds hold even for very simple planted spike detection problems, where the goal is to detect the presence of a single coefficient which is super-polynomially larger than the other coefficients of the Hamiltonian, as well as for average case instances.

Arxiv: https://arxiv.org/abs/2509.20665