Hydrogen plasma treatments for passivation of amorphous-crystalline silicon-heterojunctions on surfaces promoting epitaxy
Abstract
The impact of post-deposition hydrogen plasma treatment (HPT) on passivation in amorphous/crystalline silicon (a-Si:H/c-Si) interfaces is investigated. Combining low temperature a-Si:H deposition and successive HPT, a high minority carrier lifetime >8 ms is achieved on c-Si <100>, which is otherwise prone to epitaxial growth and thus inferior passivation. It is shown that the passivation improvement stems from diffusion of hydrogen atoms to the heterointerface and subsequent dangling bond passivation. Concomitantly, the a-Si:H hydrogen density increases, leading to band gap widening and void formation, while the film disorder is not increased. Thus, HPT allows for a-Si:H band gap and a-Si:H/c-Si band offset engineering.
- Publication:
-
Applied Physics Letters
- Pub Date:
- March 2013
- DOI:
- 10.1063/1.4798292
- Bibcode:
- 2013ApPhL.102l2106M
- Keywords:
-
- amorphous semiconductors;
- carrier lifetime;
- dangling bonds;
- elemental semiconductors;
- energy gap;
- hydrogen;
- minority carriers;
- passivation;
- plasma deposition;
- semiconductor epitaxial layers;
- semiconductor heterojunctions;
- silicon;
- surface states;
- vapour phase epitaxial growth;
- voids (solid);
- 81.65.Rv;
- 68.55.ag;
- 52.77.Dq;
- 68.47.Fg;
- 73.40.Lq;
- 73.50.Gr;
- Passivation;
- Semiconductors;
- Plasma-based ion implantation and deposition;
- Semiconductor surfaces;
- Other semiconductor-to-semiconductor contacts p-n junctions and heterojunctions;
- Charge carriers: generation recombination lifetime trapping mean free paths