Title :
Converting a bulk radiation-hardened BiCMOS technology into a dielectrically-isolated process
Author :
DeLaus, M. ; Emily, D. ; Mappes, B. ; Pease, R.
Author_Institution :
Analog Devices Semiconductor, Wilmington, MA, USA
fDate :
12/1/1993 12:00:00 AM
Abstract :
A radiation-hardened dielectrically isolated BiCMOS process has been developed by retrofitting dielectric isolation to an existing radiation-hardened JI (junction-isolated) process. The process is fabricated on a bonded-wafer silicon-on-insulator (SOI) substrate and employs deep trenches for lateral device isolation. The isolation technique employed is similar to that used on advanced commercial complementary-bipolar processes. Trench/substrate induced defects are sensitive to the device layout and process flow. Optimization of the trench and posttrench processing and the device layouts has reduced the defect densities to acceptable levels. The defect density levels obtained are consistent with the economic manufacture of VLSI circuits. The dose-rate performance of the process has been improved without compromising the total-dose hardness
Keywords :
BiCMOS integrated circuits; integrated circuit technology; integrated circuit testing; radiation hardening (electronics); semiconductor-insulator boundaries; BiCMOS technology; VLSI circuits; bonded wafer SOI substrate; deep trenches; defect density levels; device layout; dielectrically-isolated process; dose-rate performance; electrical testing; junction isolated process; lateral device isolation; posttrench processing; process flow; radiation hardened technology; total-dose hardness; trench processing optimization; trench/substrate induced defects; BiCMOS integrated circuits; Bonding; CMOS process; Circuit testing; Cranes; Crystallography; Dielectric devices; Dielectric substrates; MOS devices; Silicon;
Journal_Title :
Nuclear Science, IEEE Transactions on
