Advanced damage-free neutral beam etching technology to texture Si wafer with honeycomb pattern for broadband light trapping in photovoltaics

Halubai Sekhar*, Tetsuo Fukuda, Tomohiro Kubota, Mohammad Maksudur Rahman, Hidetaka Takato, Michio Kondo, Seiji Samukawa

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

1 Scopus citations

Abstract

We introduce a new innovative damage-free neutral beam etching (NBE) technique to transfer a honeycomb resist pattern to silicon (Si) wafer (thickness of 180 µm). Front-surface texturing of Si helps to reduce surface reflection and increase light absorption for solar cell applications. NBE was performed with Cl2 and Cl2/ SF6 gases chemistries, and the influence of the etching time on the etching profiles, surface reflection and potential short-circuit densities (p-JSC) was studied. The Si etching rate with pure Cl2 was ~ 5 nm/min and resulted in anisotropic etch profiles and a minimum surface reflection of 15% at 1000 nm, which is too high for practical use. With the introduction of 5% of SF6, the etching rate increased to 30 nm/min, the etching became isotropic (anisotropy of ~ 1), and sloped sidewalls appeared. NBE with Cl2 (95%)/SF6 (5%) produced a sample with an average surface reflection of 3.7% over the wavelength range 300–1000 nm without any antireflection coating. The minimum surface reflection in this case was ~ 1% at 1030 nm and p-JSC was 40.63 mA/cm2. This type of surface pattern is well suited for low-consumption-material (thin), high-efficiency Si solar cells.

Original languageEnglish
Pages (from-to)27449-27461
Number of pages13
JournalJournal of Materials Science: Materials in Electronics
Volume32
Issue number23
DOIs
StatePublished - Dec 2021

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