Photon-number dependent Hamiltonian engineering for resonators

What is claimed: 1 . A method for controlling a quantum interaction in a cavity system comprising a first electromagnetic resonator coupled to a first ancilla quantum bit (qubit), the method comprising: determining a target Hamiltonian associated with the cavity system dependent on one or more photon-number states of the first electromagnetic resonator; designing an external electromagnetic field for driving the first ancilla qubit to achieve an interaction between the external field and the cavity system that emulates the target Hamiltonian while minimizing a decoherence of the one or more photon-number states of the first electromagnetic cavity due to an excitation of the first ancilla qubit by the external electromagnetic field; and driving the first ancilla qubit with the external electromagnetic field designed to induce a quantum evolution of the cavity system to a quantum state. 2 . The method of claim 1 wherein: the first electromagnetic resonator is associated with a cavity resonance and the first ancilla qubit is associated with a qubit resonance between a ground state and an excited state; and the first electromagnetic resonator and the ancilla qubit are coupled via a dispersive coupling. 3 . The method of claim 2 , wherein the qubit resonance of the first ancilla qubit is split into a series of sub-resonances depending on photon-number states of the first electromagnetic resonator due to the dispersive coupling. 4 . The method of claim 3 , wherein minimizing the decoherence of the one or more photon-number states of the electromagnetic cavity comprises minimizing a population of the excited state by the external electromagnetic field. 5 . The method of claim 3 , wherein minimizing the decoherence of the one or more photon-number states of the electromagnetic cavity comprises minimizing a micromotion of the first ancilla qubit induced by the external electromagnetic field. 6 . The method of claim 3 , wherein designing the external electromagnetic field comprises determining a number of frequency components, and field amplitudes and frequency detunings from the sub-resonances for the frequency components. 7 . The method of claim 6 , wherein designing the external electromagnetic field comprises assigning a predetermined set of detunings from the sub-resonances and adjusting the field amplitudes of the frequency components to minimize a population of the exited state or micromotion of the ancilla qubit. 8 . The method of claim 7 , wherein the predetermined set of detunings are each commensurate with a coupling strength between the first ancilla qubit and the first electromagnetic resonator. 9 . The method of claim 1 , wherein the target Hamiltonian comprises one or more photon-photon interactions. 10 . The method of claim 9 , wherein the target Hamiltonian comprises a photon-photon interaction that cancels a self-Kerr nonlinearity in the first electromagnetic resonator. 11 . The method of claim 1 , wherein the quantum evolution comprises a quantum logic operation or a quantum simulation of a many-body quantum system. 12 . The method of claim 11 , wherein the quantum logic operation comprises an error-transparent Z-rotation operation. 13 . The method of claim 1 , wherein: the cavity system further comprises a second electromagnetic resonator coupled to the first electromagnetic resonator, a second ancilla qubit coupled to the second electromagnetic resonator, and a third qubit coupled to the first electromagnetic resonator and the second electromagnetic resonator; and the target Hamiltonian is further dependent on one or more photon-number states of the second electromagnetic resonator in addition to the one or more photon-number states of the first electromagnetic resonator. 14 . The method of claim 13 wherein the target Hamiltonian comprises interactions between photons in the first electromagnetic resonator and the photons in the second electromagnetic resonator. 15 . The method of claim 14 , wherein the quantum evolution comprises a controlled-Z-rotation operation for realizing a controlled-phase quantum gate. 16 . The method of claim 1 , wherein the electromagnetic resonator comprises a planar or three-dimensional superconducting microwave resonator. 17 . The method of claim 16 , wherein the ancilla qubit comprises a superconducting transmon qubit. 18 . The method of claim 17 , wherein the superconducting microwave resonator and the superconducting transmon are capacitively coupled. 19 . A system for controlling a quantum interaction, comprising: a cavity system comprising a first electromagnetic resonator coupled to a first ancilla quantum bit (qubit); an electromagnetic field generator; and a controller coupled to the cavity system and the electromagnetic field generator, wherein the controller is configured to perform the methods of claim 1 . 20 . A system for controlling a quantum interaction, comprising: a cavity system comprising a first electromagnetic resonator coupled to a first ancilla quantum bit (qubit); an electromagnetic field generator; and a controller coupled to the cavity system and the electromagnetic field generator, wherein the controller is configured to: determine a target Hamiltonian associated with the cavity system dependent of one or more photon-number states of the first electromagnetic resonator; optimize an external electromagnetic field for driving the first ancilla qubit to achieve an interaction between the external field and the cavity system that emulate the target Hamiltonian while minimizing a decoherence of the one or more photon-number states of the first electromagnetic cavity due to an excitation of the first ancilla qubit by the external electromagnetic field; and trigger the electromagnetic field generator to generate the optimized external electromagnetic field to drive the first ancilla qubit to induce a quantum evolution of the cavity system to a quantum state.