Drive-induced nonlinearities of cavity modes coupled to a transmon ancilla

TL;DR

This paper investigates how off-resonant drives on transmon ancillas affect the nonlinearities of coupled cavity modes, revealing mechanisms for control and correction of cavity nonlinearities in quantum computing systems.

Contribution

It provides a comprehensive theoretical and experimental analysis of drive-induced nonlinearities and introduces a susceptibility-based method for efficient Kerr nonlinearity computation.

Findings

Drive can induce multiphoton resonances affecting cavity nonlinearities.

Large detuning leads to cavity-photon-number-dependent ac Stark shifts.

Drive amplitude can be tuned to cancel or modify Kerr nonlinearities.

Abstract

High-Q microwave cavity modes coupled to transmon ancillas provide a hardware-efficient platform for quantum computing. Due to their coupling, the cavity modes inherit finite nonlinearity from the transmons. In this work, we theoretically and experimentally investigate how an off-resonant drive on the transmon ancilla modifies the nonlinearities of cavity modes in qualitatively different ways, depending on the interrelation among cavity-transmon detuning, drive-transmon detuning and transmon anharmonicity. For a cavity-transmon detuning that is smaller than or comparable to the drive-transmon detuning and transmon anharmonicity, the off-resonant transmon drive can induce multiphoton resonances among cavity and transmon excitations that strongly modify cavity nonlinearities as drive parameters vary. For a large cavity-transmon detuning, the drive induces cavity-photon-number-dependent ac Stark shifts of transmon levels that translate into effective cavity nonlinearities. In the regime of weak transmon-cavity coupling, the cavity Kerr nonlinearity relates to the third-order nonlinear susceptibility function $\chi^{(3)}$ of the driven ancilla. This susceptibility function provides a numerically efficient way of computing the cavity Kerr particularly for systems with many cavity modes controlled by a single transmon. It also serves as a diagnostic tool for identifying undesired drive-induced multiphoton resonance processes. Lastly, we show that by judiciously choosing the drive amplitude, a single off-resonant transmon drive can be used to cancel the cavity self-Kerr nonlinearity or the inter-cavity cross-Kerr. This provides a way of dynamically correcting the cavity Kerr nonlinearity during bosonic operations or quantum error correction protocols that rely on the cavity modes being linear.