Electron–longitudinal-acoustic-phonon scattering in double-quantum-dot based quantum gates

Quantum dot-based quantum computation employs extensively the exchange interaction between nearby electronic spins in order to manipulate and couple different qubits. The exchange interaction, however, couples the qubit states to charge noise, which reduces the fidelity of the quantum gates that employ it. The effect of charge noise can be mitigated by working at noise sweetspots in which the sensitivity to charge variations is reduced. In this work we study the response to charge noise of a double quantum dot based qubit in the presence of ac gates, with arbitrary driving amplitudes, applied either to the dot levels or to the tunneling barrier. Tuning with an ac driving allows to manipulate the sign and strength of the exchange interaction as well as its coupling to environmental electric noise. Moreover, we show the possibility of inducing a second-order sweetspot in the resonant spin-triplet qubit in which the dephasing time is significantly increased.

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Optimal control of universal quantum gates in a double quantum dot

Physical Review B ◽

10.1103/physrevb.97.235301 ◽

2018 ◽

Vol 97 (23) ◽

Cited By ~ 3

Author(s):

Leonardo K. Castelano ◽

Emanuel F. de Lima ◽

Justino R. Madureira ◽

Marcos H. Degani ◽

Marcelo Z. Maialle

Keyword(s):

Optimal Control ◽

Quantum Dot ◽

Quantum Gates ◽

Double Quantum ◽

Double Quantum Dot ◽

Universal Quantum

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On the robustness of the hybrid qubit computational gates through simulated randomized benchmarking protocols

Scientific Reports ◽

10.1038/s41598-020-74817-z ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Elena Ferraro ◽

Marco De Michielis

Keyword(s):

Quantum Dot ◽

Noise Model ◽

Statistical Characteristics ◽

Quantum Gates ◽

Average Error ◽

Double Quantum ◽

Double Quantum Dot ◽

Quantum Processor ◽

Noise Characterization ◽

Specific Quantum

Abstract One of the main challenges in building a quantum processor is to characterize the environmental noise. Noise characterization can be achieved by exploiting different techniques, such as randomization where several sequences of random quantum gates are applied to the qubit under test to derive statistical characteristics about the affecting noises. A scalable and robust algorithm able to benchmark the full set of Clifford gates using randomization techniques is called randomized benchmarking. In this study, we simulated randomized benchmarking protocols in a semiconducting all-electrical three-electron double-quantum dot qubit, i.e. hybrid qubit, under different error models, that include quasi-static Gaussian and the more realistic 1/f noise model, for the input controls. The average error of specific quantum computational gates is extracted through interleaved randomized benchmarking obtained including Clifford gates between the gate of interest. It provides an estimate of the fidelity as well as theoretical bounds for the average error of the gate under test.

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