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Simultaneous Etching and Deposition Processes during the Etching of Silicon with a Cl 2 /O 2 /Ar Inductively Coupled Plasma
Author(s) -
Tinck Stefan,
Bogaerts Annemie,
Shamiryan Denis
Publication year - 2011
Publication title -
plasma processes and polymers
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.644
H-Index - 74
eISSN - 1612-8869
pISSN - 1612-8850
DOI - 10.1002/ppap.201000189
Subject(s) - etching (microfabrication) , wafer , dry etching , oxide , buffered oxide etch , analytical chemistry (journal) , silicon , reactive ion etching , deposition (geology) , oxygen , layer (electronics) , plasma etching , chemistry , inductively coupled plasma , materials science , plasma , nanotechnology , metallurgy , chromatography , paleontology , physics , organic chemistry , quantum mechanics , sediment , biology
Abstract In this article, surface processes occurring during the etching of Si with a Cl 2 /O 2 /Ar plasma are investigated by means of experiments and modeling. Cl 2 ‐based plasmas are commonly used to etch silicon, while a small fraction of O 2 is added to protect the sidewalls from lateral etching during the shallow trench isolation process. When the oxygen fraction exceeds a critical value, the wafer surface process changes from an etching regime to a deposition regime, drastically reducing the etch rate. This effect is commonly referred to as the etch stop phenomenon. To gain better understanding of this mechanism, the oxygen fraction is varied in the gas mixture and special attention is paid to the effects of oxygen and of the redeposition of non‐volatile etched species on the overall etch/deposition process. It is found that, when the O 2 flow is increased, the etch process changes from successful etching to the formation of a rough surface, and eventually to the actual growth of an oxide layer which completely blocks the etching of the underlying Si. The size of this etch stop island was found to increase as a function of oxygen flow, while its thickness was dependent on the amount of Si etched. This suggests that the growth of the oxide layer mainly depends on the redeposition of non‐volatile etch products. The abrupt change in the etch rate as a function of oxygen fraction was not found back in the oxygen content of the plasma, suggesting the competitive nature between oxidation and chlorination at the wafer. Finally, the wafer and reactor wall compositions were investigated by modeling and it was found that the surface rapidly consisted mainly of SiO 2 when the O 2 flow was increased above about 15 sccm.