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Lower Bounds for Learning Hamiltonians from Time Evolution

Quantum Physics 2026-04-20 v4

Abstract

Learning about a Hamiltonian HH from its time evolution eiHte^{-iHt} is a fundamental task in quantum science. A flurry of recent work has developed powerful new algorithms with provable guarantees for this task, for a variety of natural settings. Despite this, relatively little is known about lower bounds for learning Hamiltonians. In particular, in the natural setting where we assume HH is a kk-local Hamiltonian on nn qubits, all existing algorithms require total evolution time at least nΩ(k)n^{\Omega (k)} to learn the parameters of HH, and it remained open whether one could obtain even faster algorithms -- or at the very least, if one could obtain better runtimes for simpler tasks, such as estimating a single designated coefficient of the Hamiltonian. In this work we show the answer is essentially no, by obtaining strong lower bounds for these problems. We find that not only do kk-local Hamiltonians require nΩ(k)n^{\Omega(k)} time evolution or interactions to learn, but also that in several senses, learning anything about a Hamiltonian is just as hard as learning everything. In particular, we find the same nΩ(k)n^{\Omega(k)} lower bound holds for learning a single coefficient of a kk-local Hamiltonian HH, even if the rest of HH is already known. We also show an nΩ(k)n^{\Omega(k)} lower bound for the task of effective Hamiltonian learning, where one seeks only to learn a unitary that approximately implements time evolution of HH. Several related lower bounds, such as for general sparse (but not necessarily local) HH are also given. On the technical side, we make a new connection between Hamiltonian learning lower bounds and the analysis of Boolean functions, where we introduce a novel extremal property that may be of independent interest.

Keywords

Cite

@article{arxiv.2509.20665,
  title  = {Lower Bounds for Learning Hamiltonians from Time Evolution},
  author = {Ziyun Chen and Jerry Li and Joseph Slote},
  journal= {arXiv preprint arXiv:2509.20665},
  year   = {2026}
}
R2 v1 2026-07-01T05:55:11.461Z