Integrating singlet-triplet qubits with superconducting resonators

Singlet-triplet qubits possess many appealing traits for building a quantum computer, in large part because they have reduced coupling to charge yet retain fast single-qubit gate speeds. While they are limited by their slow and short range two-qubit gate, incorporating superconducting resonators into the singlet-triplet qubit architecture shows promise for alleviating both issues. However, the singlet-triplet qubit is extremely sensitive to changes in its electrostatic environment, which can be affected both by the fabrication process for the resonator and by the presence of the proximal resonator gate. Moreover, because the singlet-triplet qubit has reduced coupling to charge, achieving high-fidelity gates requires a high-impedance resonator, which carries unique fabrication constraints. In my talk, I will discuss measurements we have done to study and quantify the impacts of these changes, as well as techniques we have developed to mitigate any negative effects.