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Photoluminescent or Blackened Silicon Surfaces Synthesized with Copper-assisted Chemical Etching: For Energy Applications

Ken-Hua Kuo, Wei-Hao Ku, T. -H. Lee

2020ECS Journal of Solid State Science and Technology10 citationsDOIOpen Access PDF

Abstract

The metal-assisted chemical etching (MACE) of silicon-based substrates can fabricate nanostructures for various energy applications. The drawback of using copper as a replacement for noble metals in MACE (i.e. Cu-ACE) is the self-dissolution of Cu during processing. However, the implementation of two-step processing, including electroless metal deposition and oxidant (H 2 O 2 )–assisted hydrofluoric etching, solves the issue. Here, we determined that when p ++ -type silicon was applied in the Cu-ACE process, a photoluminescent silicon layer appeared on the etched surface. This result was surprising because photoluminescent silicon is fairly difficult to achieve with regular MACE processing and p ++ -type silicon is also unsuitable for MACE processing, even when used as an ‘etch-stop’ substrate. On the other hand, when using ultraviolet (UV) irradiation with Cu-ACE, a blackened silicon surface, rather than photoluminescent silicon, developed. Here, we demonstrate a technique for either producing a photoluminescent silicon surface or blackening the silicon surface by single Cu-ACE processing. Cu-ACE processing can be developed into a cost-efficient production technology for silicon-based energy applications, such as silicon photonics and silicon solar cells.

Topics & Concepts

SiliconMaterials scienceIsotropic etchingEtching (microfabrication)PhotoluminescenceOptoelectronicsNanotechnologyCopperMetallurgyLayer (electronics)Nanowire Synthesis and ApplicationsSilicon Nanostructures and PhotoluminescenceSemiconductor materials and devices
Photoluminescent or Blackened Silicon Surfaces Synthesized with Copper-assisted Chemical Etching: For Energy Applications | Litcius