Abstract
Aluminium oxide (AlOx) tunnel junctions are important components in a range of nanoelectric devices including superconducting qubits where they can be used as Josephson junctions. While many improvements in the reproducibility and reliability of qubits have been made possible through new circuit designs, there are still knowledge gaps in the relevant materials science. A better understanding of how fabrication conditions affect the density, uniformity, and elemental composition of the oxide barrier may lead to the development of lower noise and more reliable nanoelectronics and quantum computers. In this paper, we use molecular dynamics to develop models of Al–AlOx–Al junctions by iteratively growing the structures with sequential calculations. With this approach, we can see how the surface oxide grows and changes during the oxidation simulation. Dynamic processes such as the evolution of a charge gradient across the oxide, the formation of holes in the oxide layer, and changes between amorphous and semi-crystalline phases are observed. Our results are widely in agreement with previous work including reported oxide densities, self-limiting of the oxidation, and increased crystallinity as the simulation temperature is raised. The encapsulation of the oxide with metal evaporation is also studied atom by atom. Low density regions at the metal–oxide interfaces are a common feature in the final junction structures which persists for different oxidation parameters, empirical potentials, and crystal orientations of the aluminium substrate.
Highlights
Superconducting quantum computers often use aluminium oxide tunnel junctions as Josephson junctions to introduce the required nonlinearity[1,2,3,4,5,6,7]
The system is allowed to evolve until a stable oxide layer forms on the aluminium surface
The oxidation of aluminium is known to self-terminate when a thin amorphous oxide layer has been formed[22,46] and, as the magnitude of the tunnelling current in Josephson junctions is exponentially dependent on the thickness of the oxide layer, the factors which affect the self-limiting thickness are important considerations for device design[47]
Summary
Superconducting quantum computers often use aluminium oxide tunnel junctions as Josephson junctions to introduce the required nonlinearity[1,2,3,4,5,6,7]. The tunnel barrier in such junctions is formed by a thin dielectric film of amorphous aluminium oxide (AlOx) which separates two metallic contacts. We aim to address this gap in the literature from a computational perspective. The quantities reported, such as material density and stoichiometric Al:O ratio, and the conditions under which the oxide develops amorphous or crystalline features, can inform the fabrication of superconducting qubits with increased quality and reliability
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