Quantum computation of three-wave interactions with engineered cubic couplings.

Quantum simulation hardware usually lacks native cubic couplings, which are essential building blocks in many physics applications. Nevertheless, we demonstrate that effective three-wave vertices can be realized on quantum computers. In particular, for the three-wave Hamiltonian of laser-plasma interactions, we show that its Hilbert space can be decomposed into a direct sum of $D$-dimensional subspaces. Within each subspace, physical states are readily mapped to quantum memory, and the Hamiltonian matrix becomes tridiagonal. The resultant unitary evolution is realized using two qubits on state-of-the-art quantum cloud services, which approximate the three-wave gate as products of $\sim$20 standard gates. This trotterization approach allows $\sim$10 repetitions of the three-wave gate on current quantum computers before results are corrupted by decoherence. As an alternative approach, the unitary evolution is also realized as a single gate using customized control pulses on the Quantum Design and Integration Testbed (QuDIT). Utilizing three levels of the transmon qudit, high-fidelity results are obtained for $\sim$100 three-wave gate repetitions. Moreover, reliable control pulses may also be synthesized cheaply using interpolation when parameters of the Hamiltonian deviate from those used in numerical optimization. Our results highlight the advantage of using customized gates in physics applications. The generalized multi-wave gates may be used to compute a large class of problems in nonlinear optics, weak turbulence, and lattice gauge theories.