GaN nanowires prepared by Cu-assisted photoelectron-chemical etching

A novel Cu-assisted photoelectron-chemical etching is proposed to fabricate GaN nanowires. The functional mechanism of assisted metals, etchant concentrations, and the addition of H2O2 was investigated based on theoretical analysis and experiments. The low-cost metal-assisted etchant (CuSO4) proved more favorable than the conventional noble one (AgNO3) for the preparation of GaN nanowires in this work. The formed Ag dendrite blocked the etching when adopting the Ag-assisted etchant, while the Cu-assisted one did not. Moreover, the etchant consisting of 0.01 M CuSO4 and 5 M HF was demonstrated to realize a relatively good surface morphology and fast etching rate. In addition, the common oxidant H2O2 introduced a quasi-stable configuration between the Cu deposition and dissolution, slowing down the formation of the GaN nanowires. The proposed Cu-assisted photoelectron-chemical etching with the advantages of low cost, room temperature, and controllability could offer a new way to fabricate GaN nano-devices.

Automated summary

A novel Cu-assisted photoelectron-chemical etching method was proposed for the fabrication of GaN nanowires. The influence of assisted metals, etchant concentrations, and the addition of H2O2 was investigated through theoretical analysis and experiments. The low-cost CuSO4-assisted etchant was found to be more favorable than the conventional noble AgNO3-assisted etchant. The addition of H2O2 resulted in a quasi-stable configuration, slowing down the formation of GaN nanowires. The proposed method offers a new way to fabricate GaN nano-devices with the advantages of low cost, room temperature, and controllability.