Polar molecules near superconducting resonators: a coherent, all-electrical, molecule-mesoscopic interface

TL;DR

This paper demonstrates a method to integrate polar molecules with superconducting resonators, enabling coherent, electrical control for scalable quantum computing architectures.

Contribution

It introduces a novel approach for trapping, cooling, and manipulating polar molecules near superconducting resonators, combining molecular coherence with solid-state scalability.

Findings

Electrostatically trapped polar molecules exhibit strong confinement and fast electrical gate control.

Electrical noise can be significantly suppressed through proper preparation and manipulation.

The setup enables a scalable cavity QED quantum computer architecture with long-lived molecular states.

Abstract

The challenge of building a scalable quantum processor requires consolidation of the conflicting requirements of achieving coherent control and preservation of quantum coherence in a large scale quantum system. Moreover, the system should be compatible with miniaturization and integration of quantum circuits. Mesoscopic solid state systems such as superconducting islands and quantum dots feature robust control techniques using local electrical signals and self-evident scaling based on advances in fabrication; however, in general the quantum states of solid state devices tend to decohere rapidly. In contrast, quantum optical systems based on trapped ions and neutral atoms exhibit dramatically better coherence properties, while miniaturization of atomic and molecular systems, and their integration with mesoscopic electrical circuits, remains an important challenge. Below we describe methods for the integration of a single particle system -- an isolated polar molecule -- with mesoscopic solid state devices in a way that produces robust, coherent, quantum-level control. The methods described include the trapping, cooling, detection, coherent manipulation and quantum coupling of isolated polar molecules at sub-micron dimensions near cryogenic stripline microwave resonators. We show that electrostatically trapped polar molecules can exhibit strong confinement and fast, purely electrical gate control. Furthermore, the effect of electrical noise sources, a key issue in quantum information processing, can be suppressed to very low levels via appropriate preparation and manipulation of the polar molecules. Our setup provides a scalable cavity QED-type quantum computer architecture, where entanglement of distant qubits stored in long-lived rotational molecular states is achieved via exchange of microwave photons.