Process-induced defects in solar cell silicon
- 1 July 1985
- journal article
- Published by AIP Publishing in Journal of Applied Physics
- Vol. 58 (1) , 223-229
- https://doi.org/10.1063/1.335716
Abstract
The microstructure of as-grown and processed, edge-defined film-fed grown, silicon ribbons was studied in order to identify the basic mechanisms responsible for the change of the as-grown defect structure during processing at elevated temperatures. The short heat treatment required to diffuse the p-n junction was sufficient to cause heterogeneous precipitation of impurity atoms, particularly transition metals. In addition, an elastic recovery of the ribbon occurred by dislocation glide, resulting in the formation of a polygonizationlike structure of sub boundaries in the base. Mechanism are suggested by which twin boundaries, acting as dislocation obstacles, can concentrate the relatively low average dislocation densities typical of edge-defined film-fed grown ribbons (104 cm−2 to 108 cm−2) to values which are sufficient to induce the formation of subgrainlike boundary structures.This publication has 8 references indexed in Scilit:
- Recovery of edge-defined film-fed grown silicon Dislocation/twin boundary interaction and mechanisms for twin-induced grain boundary formationPhilosophical Magazine A, 1985
- Phosphorus gettering and intrinsic gettering of nickel in siliconApplied Physics Letters, 1984
- Charge collection scanning electron microscopyJournal of Applied Physics, 1982
- High speed EFG of wide silicon ribbonJournal of Crystal Growth, 1980
- Structural and electrical charaterization of crystallographic defects in silicon ribbonsJournal of Crystal Growth, 1980
- Interstitial Supersaturation And Climb Of Misfit Dislocations In Phosphorus‐Diffused SiliconJournal of Microscopy, 1980
- TEM observations on grain boundaries in sintered siliconPhilosophical Magazine A, 1979
- The effect of creep deformation on the structure of twin boundariesPhilosophical Magazine A, 1978