Title: Digital quantum simulation of scalar Yukawa coupling

Abstract: Motivated by the revitalized interest in the digital quantum simulation of coupled fermion-boson models from medium- and high-energy physics, we investigate the nonequilibrium dynamics following a Yukawa-interaction quench on IBM Q. Adopting -- due to current quantum-hardware limitations -- a single-site (zero-dimensional) version of the scalar Yukawa-coupling model as our point of departure, we design low-depth quantum circuits that emulate its dynamics with up to three bosons. In particular, using advanced circuit-optimization techniques, in the one-boson case we demonstrate circuit compression, i.e.~design a constant-depth circuit containing only two CNOT gates, regardless of the total simulation time. In the three-boson case -- where such a compression is not possible -- we design a circuit in which one Trotter step entails $8$ CNOTs, this number being far below the maximal CNOT-cost of a generic three-qubit gate. Using an analogy with the travelling salesman problem, we also provide a CNOT-cost estimate for quantum circuits emulating the system dynamics for higher boson-number truncations. Based on the designed circuits, we quantify the system dynamics for the initial vacuum state by evaluating the expected boson number at an arbitrary time after a Yukawa-interaction quench, as well as the survival probability of the initial state (the Loschmidt echo). Finally, we make use of the designed circuits to drive adiabatic transitions and compute the energies of the ground- and first excited state of the model under consideration. We validate our results by performing error mitigation in the form of zero-noise extrapolation, finding an excellent agreement of our obtained results with the exact ones obtained through classical benchmarking.