External control of GaN band bending using phosphonate self-assembled monolayers

TL;DR

This study demonstrates how phosphonate self-assembled monolayers can modulate the surface band bending and optoelectronic properties of GaN, with implications for sensing and device applications.

Contribution

It provides new insights into controlling GaN surface electronic properties through phosphonate chemistry, highlighting the role of acid electronegativity and surface orientation.

Findings

GaN work function is significantly altered by phosphonic acid grafting.

Both acids impact GaN surface band bending regardless of orientation.

External quantum efficiency is affected by surface functionalization, especially in nanowires.

Abstract

We report on the optoelectronic properties of GaN$(0001)$ and $(1\bar{1}00)$ surfaces after their functionalization with phosphonic acid derivatives. To analyze the possible correlation between the acid's electronegativity and the GaN surface band bending, two types of phosphonic acids, n-octylphosphonic acid (OPA) and 1H,1H,2H,2H-perfluorooctanephosphonic acid (PFOPA), are grafted on oxidized GaN$(0001)$ and GaN$(1\bar{1}00)$ layers as well as on GaN nanowires. The resulting hybrid inorganic/organic heterostructures are investigated by X-ray photoemission and photoluminescence spectroscopy. The GaN work function is changed significantly by the grafting of phosphonic acids, evidencing the formation of dense self-assembled monolayers. Regardless of the GaN surface orientation, both types of phosphonic acids significantly impact the GaN surface band bending. A dependence on the acids' electronegativity is, however, only observed for the oxidized GaN$(1\bar{1}00)$ surface, indicating a relatively low density of surface states and a favorable band alignment between the surface oxide and acids' electronic states. Regarding the optical properties, the covalent bonding of PFOPA and OPA on oxidized GaN layers and nanowires significantly affect their external quantum efficiency, especially in the nanowire case due to the large surface-to-volume ratio. The variation in the external quantum efficiency is related to the modication of both the internal electric fields and surface states. These results demonstrate the potential of phosphonate chemistry for the surface functionalization of GaN, which could be exploited for selective sensing applications.