Quantum and Tunnelling Capacitance in Charge and Spin Qubits
Abstract
We present a theoretical analysis of the capacitance of a double quantum dot in the charge and spin qubit configurations probed at high-frequencies. We find that in general the total capacitance of the system consists of two state-dependent terms: The quantum capacitance arising from adiabatic charge motion and the tunnelling capacitance that appears when repopulation occurs at a rate comparable or faster than the probing frequency. The analysis of the capacitance lineshape as a function of externally controllable variables offers a way to characterize the qubits' charge and spin state as well as relevant system parameters such as charge and spin relaxation times, tunnel coupling, electron temperature and electron g-factor. Overall, our analysis provides a formalism to understand dispersive qubit-resonator interactions which can be applied to high-sensitivity and non-invasive quantum-state readout.
Cite
@article{arxiv.1604.02884,
title = {Quantum and Tunnelling Capacitance in Charge and Spin Qubits},
author = {R. Mizuta and R. M. Otxoa and A. C. Betz and M. F. Gonzalez-Zalba},
journal= {arXiv preprint arXiv:1604.02884},
year = {2017}
}
Comments
9 pages, 6 figures