Boron-assisted stabilization of low-resistivity mixed-valence Cu-O thin films prepared by reactive magnetron sputtering

Abstract

This study systematically investigated the influence of boron incorporation in Cu-O thin films and the effect of oxygen partial pressure (p ox) on the phase evolution, chemical bonding, and electrical characteristics of the prepared films. A phase transition from Cu2O to Cu2O/Cu4O3 to CuO was observed as oxygen partial pressure increased. Boron incorporation significantly broadened the stability window of the Cu2O and Cu4O3 phases and delayed the transition to CuO at higher oxygen partial pressure. In the highly B-doped Cu-O films, Cu4O3 was stabilized even under oxygen-rich conditions along with the CuO phase, suggesting that boron significantly altered the oxidation pathway. The formation of B-O and possible B-O-Cu configurations altered the local oxygen chemistry and promoted mixed-valence copper oxide phases. Electrical measurements revealed that highly B-doped Cu-O films exhibited a delayed transition from a high-resistivity low-p ox regime to a low-resistivity mixed-valence regime, ultimately reaching approximately 0.06 Ω cm, among the lowest reported resistivities for a CuO-like material. These findings demonstrate that boron doping is an effective approach for tailoring the phase stability, defect chemistry, and electrical characteristics of Cu-O thin films for optoelectronic and photovoltaic applications.