Dipole coupling of a double quantum dot to a microwave resonator (1108.5378v1)

Abstract: Quantum coherence in solid-state systems has been demonstrated in superconducting circuits and in semiconductor quantum dots. This has paved the way to investigate solid-state systems for quantum information processing with the potential benefit of scalability compared to other systems based on atoms, ions and photons. Coherent coupling of superconducting circuits to microwave photons, circuit quantum electrodynamics (QED), has opened up new research directions and enabled long distance coupling of qubits. Here we demonstrate how the electromagnetic field of a superconducting microwave resonator can be coupled to a semiconductor double quantum dot. The charge stability diagram of the double dot, typically measured by direct current (DC) transport techniques, is investigated via dispersive frequency shifts of the coupled resonator. This hybrid all-solid-state approach offers the potential to coherently couple multiple quantum dot and superconducting qubits together on one chip, and offers a method for high resolution spectroscopy of semiconductor quantum structures.

• The paper demonstrates strong dipole coupling between quantum dot charge states and a microwave resonator using a tailored gate structure.
• The experimental setup employs a GaAs substrate with an aluminum coplanar resonator to optimize interactions at the standing wave anti-node.
• Numerical simulations validate the Jaynes-Cummings model and highlight scalable approaches for quantum information processing.

Dipole Coupling of a Double Quantum Dot to a Microwave Resonator

This paper presents a detailed paper on the dipole coupling of a semiconductor double quantum dot to a superconducting microwave resonator. The subsequent exploration of the interactions between solid-state quantum systems and electromagnetic fields offers intriguing insights and potential pathways for new technological advancements, particularly within the field of quantum information processing.

Overview of Experimental Setup

The experiment employs a hybrid system encompassing both quantum dots and a microwave resonator. The system is constructed on a GaAs substrate with an aluminum coplanar waveguide resonator. The quantum dots are configured at an anti-node of the standing wave pattern of the microwave resonator, allowing optimal interaction. The quantum dot configuration consists of left and right dots placed in series concerning the source and drain.

The researchers introduce a specific gate structure to allow capacitive coupling between the quantum dots and the microwave resonator. By tuning the gate voltages, the static potentials on the quantum dots are modulated, which in turn influences the coupling dynamics with the resonator.

Quantum Dynamics and Coupling Mechanism

One of the key results of this paper is the establishment of a strong dipole coupling between the resonator field and the charge states in the quantum dots. Classical measurements, like the charge stability diagram, reveal typical charge transport patterns which are perturbed when engaging the microwave field. The authors identify coupling via a gate that aids in adjusting the interaction strength, thus controlling the dipole interaction.

The quantum mechanical model used to describe the system focuses on the Jaynes-Cummings Hamiltonian, indicating strong coupling phenomena when the system is in resonance. The classical frequency shifts and amplitude variations provide empirical validation for the macroscopic descriptions of coupling dynamics.

Numerical Simulations and Analysis

Numerical simulations are performed to model the resonator’s response under varying quantum dot gate potentials, resonating frequencies, and tunnel couplings. These simulations incorporate realistic parameters, including decoherence and damping effects, providing a good match with the experimental data.

Implications and Future Work

The significance of this dipole coupling scheme is substantial within the quantum computing domain, where coherent interactions between quantum bits are paramount. This paper suggests a viable platform for integrating quantum dot architectures with microwave resonators, facilitating scalable quantum information processing.

Given the insights offered by this research, potential future work could explore extending this paradigm to integrate spin qubits, made possible using ferromagnetic leads or exploiting spin-orbit interactions. The platform may also allow for high-time-resolution and high-frequency-resolution spectroscopy of quantum states in semiconductor materials.

This paper affirms the potential of solid-state systems to play a crucial role in the quantum technologies landscape by pioneering ways to manipulate and measure quantum systems with high precision using existing semiconductor technologies.