Title :
Characterization of polysilicon-encapsulated local oxidation
Author :
Roth, Scott S. ; Ray, Wayne J. ; Mazure, Carlos ; Cooper, Kent ; Kirsch, Howard C. ; Gunderson, Craig D. ; Ko, Judy
Author_Institution :
Motorola Inc., Austin, TX, USA
fDate :
5/1/1992 12:00:00 AM
Abstract :
Device isolation has been most commonly achieved through the use of local oxidation of silicon (LOCOS) or LOCOS derivatives. LOCOS is a highly dependable, low-defect isolation technique, which explains its continued extensive use. Unfortunately, the inherently large oxide encroachment associated with LOCOS is not compatible with 0.8-μm design rules. Many alternative isolation techniques designed to reduce oxide encroachment have been proposed. These alternatives often result in an increase in defectivity and/or process complexity. Polysilicon-encapsulated local oxidation (PELOX) utilizes a polysilicon-filled cavity self-aligned to the nitride edge to achieve oxide encroachment reduction. The physical (scanning electron and transmission electron micrographs) and electrical (electrical channel width, diode leakage, and gate oxide integrity) characterization of PELOX isolation are reported
Keywords :
integrated circuit technology; oxidation; scanning electron microscope examination of materials; silicon; transmission electron microscope examination of materials; 0.8 micron; LOCOS; PELOX isolation; alternative isolation techniques; defectivity; device isolation; diode leakage; electrical channel width; electrical characterisation; encroachment reduction; gate oxide integrity; low-defect isolation technique; nitride edge; oxide encroachment; physical characterisation; polycrystalline Si; polysilicon encapsulation local oxidation; polysilicon-filled cavity; process complexity; scanning electron micrography; submicron design rules; transmission electron micrographs; Buffer layers; Dry etching; Electrons; Hafnium; Laboratories; Oxidation; Research and development; Semiconductor diodes; Silicon; Surface topography;
Journal_Title :
Electron Devices, IEEE Transactions on
