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Dislocations as channels for the fabrication of sub-surface porous GaN by electrochemical etching

Fabien Massabuau, Peter Griffin, Helen Springbett, Yingjun Liu, Rupesh Kumar, Tongtong Zhu, Rachel A. Oliver

2020APL Materials43 citationsDOIOpen Access PDF

Abstract

Porosification of nitride semiconductors provides a new paradigm for advanced engineering of the properties of optoelectronic materials. Electrochemical etching creates porosity in doped layers while leaving undoped layers undamaged, allowing the realization of complex three-dimensional porous nanostructures, potentially offering a wide range of functionalities, such as in-distributed Bragg reflectors. Porous/non-porous multilayers can be formed by etching the whole, as-grown wafers uniformly in one simple process, without any additional processing steps. The etch penetrates from the top down through the undoped layers, leaving them almost untouched. Here, atomic-resolution electron microscopy is used to show that the etchant accesses the doped layers via nanometer-scale channels that form at dislocation cores and transport the etchant and etch products to and from the doped layer, respectively. Results on AlGaN and non-polar GaN multilayers indicate that the same mechanism is operating, suggesting that this approach may be applicable in a range of materials.

Topics & Concepts

Materials scienceEtching (microfabrication)WaferOptoelectronicsPorosityDislocationNanotechnologyDopingSemiconductorLayer (electronics)FabricationNanometreComposite materialPathologyAlternative medicineMedicineGaN-based semiconductor devices and materialsZnO doping and propertiesGa2O3 and related materials
Dislocations as channels for the fabrication of sub-surface porous GaN by electrochemical etching | Litcius