Related papers: Theory of multi-dimensional quantum capacitance and its application to spin and charge discrimination in quantum-dot arrays

Theory of multi-dimensional quantum capacitance and its application to spin and charge discrimination in quantum-dot arrays

URL: http://arxiv.org/abs/2210.10546v1
Date: Wed, 19 Oct 2022 13:38:55 GMT
Title: Theory of multi-dimensional quantum capacitance and its application to spin and charge discrimination in quantum-dot arrays
Authors: Andrea Secchi and Filippo Troiani
Abstract summary: Quantum states of a few-particle system capacitively coupled to a metal gate can be discriminated by measuring the quantum capacitance. This approach is here generalized to the multi-voltage case, through the introduction of the quantum capacitance matrix.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum states of a few-particle system capacitively coupled to a metal gate can be discriminated by measuring the quantum capacitance, which can be identified with the second derivative of the system energy with respect to the gate voltage. This approach is here generalized to the multi-voltage case, through the introduction of the quantum capacitance matrix. The matrix formalism allows us to determine the dependence of the quantum capacitance on the direction of the voltage oscillations in the parameter space, and to identify the optimal combination of gate voltages. This approach is applied to the case of a quantum-dot array, described in terms of a Hubbard model. Here, we first identify the potentially relevant regions in the multi-dimensional voltage space with the boundaries between charge stability regions, determined within a semiclassical approach. Then, we quantitatively characterize such boundaries by means of the quantum capacitance matrix. Altogether, this provides a procedure for optimizing the discrimination between states with different particle numbers and/or total spins.

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