Adhesion Energy of Phosphorene on Different Pristine and Oxidized Metallic Substrates

TL;DR

This study uses density functional theory to analyze how pristine and oxidized phosphorene adhere to various metallic substrates and oxides, revealing substrate-dependent adhesion properties relevant for lubrication applications.

Contribution

It provides the first computational quantification of phosphorene's adhesion to different metals and oxides, linking electronic structure to tribological performance.

Findings

Oxidized phosphorene shows higher adhesion than pristine.

Adhesion is stronger on metals than oxides, especially chromium and iron.

Interfacial bonding varies with substrate, affecting electronic properties.

Abstract

Black phosphorus and its single-layer constituent, phosphorene, have emerged as promising two-dimensional materials with remarkable tribological properties. However, recent experimental investigations revealed that the their lubricating capabilities can change with the substrate. The present computational study employs density functional theory calculations to quantify the adhesion energy of both pristine and oxidized phosphorene monolayers on various metallic substrates (aluminum, copper, iron, and chromium) and their corresponding oxides ($\mathrm{Al_2O_3}$, $\mathrm{Cu_2O}$, $\mathrm{Fe_2O_3}$, and $\mathrm{Cr_2O_3}$), correlating these interfacial property with experimentally observed tribological performance. Results demonstrate that oxidized phosphorene presents higher adhesion to all substrates with respect to pristine phosphorene, attributed to favorable interactions between oxygen non-bonding states and substrate empty states. Adhesion is systematically more favorable on pristine metals than on their corresponding oxides, with chromium and iron showing particularly strong interactions due to partially filled 3d orbitals. This result is consistent with the coefficient of friction decrease observed in tribological experiments after scratching the iron substrate, thus removing the outermost oxide layer. Charge redistribution correlates with the adhesion and electronic structure analyses reveal system-dependent interfacial bonding characteristics, with some configurations inducing metallic character in phosphorene. These findings provide fundamental insights into substrate-dependent lubricating properties of black phosphorus, highlighting the key role of layer-substrate adhesion.