Get to know Q-line

A quantum computer (QC) is a device that exploits quantum behavior to solve a computational problem that cannot be tackled, or would take too long to solve, in a classical computer. In order to build a functioning QC, several physical systems have been proposed to be used as platforms for quantum bits or “qubits”, e.g., photons, trapped atoms/ions, nuclear spins in molecules immersed in liquid solutions and point defects in solids. The latter system is advantageous from the point of view of scalability since integrated quantum devices could, in principle, be built by means of adapted fabrication techniques developed in the semiconductor industry. Nevertheless, it remains challenging to position the point defects in a deterministic array and to integrate them into large networks. The scientific aim of Q-Line is to carry out a theoretical assessment of the potential use of line defects (dislocations) as a “quantum bus”, able to both create a deterministic pattern of relevant point defects and to connect them by means of localized phonons. Until now, dislocations have only been considered as detrimental for the correct functioning of QC. Therefore, Q-Line opens a completely new area of research, aligned with the quantum technologies flagship of the European Commission and will help putting Europe at the forefront of the development of quantum technologies.

 

Based on our state-of-the-art atomistic simulations, we propose that, in order to have potential for quantum applications, dislocations should be undissociated screws and be electrically inactive. Such conditions are satisfied in cubic silicon carbide (3C-SiC). Our results show that the undissociated screw dislocation in this material is able to attract defect-based qubits into its core. As a consequence, it would allow the creation of a one-dimension array of qubits along its line direction. Furthermore, we show that the strain field induced by this specific dislocation type is able to modulate the electronic properties of the qubit located in its core, without itself being electrically active. For the specific case of the neutral divacancy in 3C-SiC, know to have real potential as qubit, our results show that these modulations result in the loss of its potential as a qubit. However, these same modulations could transform defects with no potential as qubits when located in bulk, into promising options when located inside the core of the screw dislocations. Altogether our findings represent a paradigm shift within quantum technologies, as they point out that dislocations can be used as active building blocks of future defect-based quantum computers.