Title :
Heating effects of clock drivers in bulk, SOI, and 3-D CMOS
Author :
Liu, C.C. ; Jifeng Zhang ; Datta, A.K. ; Tiwari, S.
Author_Institution :
Sch. of Electr. & Comput. Eng., Cornell Univ., Ithaca, NY, USA
Abstract :
Steady-state and transient thermal behavior of the highest power density element in systems and chips-the clock driver-in bulk, silicon-on-insulator (SOI), and three-dimensional (3-D) CMOS is examined. Despite significant metal wiring, a majority of the heat conducts through the buried oxide (BOX) in SOI and the buried interconnect layer in 3-D CMOS. 3-D CMOS has the potential to improve substantially over SOI CMOS in thermal behavior by increasing the wiring density directly beneath the clock driver. Temperature mismatch (important for analog applications) between device planes in 3-D CMOS occurs within a characteristic length, which is as large as 13 μm for clock drivers. These results suggest advantages and architectural options for the design of high-power devices in 3-D integration.
Keywords :
CMOS integrated circuits; circuit simulation; driver circuits; finite element analysis; high-speed integrated circuits; integrated circuit interconnections; integrated circuit modelling; integrated circuit packaging; integrated circuit reliability; microprocessor chips; silicon-on-insulator; thermal resistance; 1-D thermal resistance; 3-D CMOS; 3-D integration; 3-D thermal resistance; SOI CMOS; architectural options; bulk CMOS; buried interconnect layer; buried oxide; characteristic length; clock drivers; heat conduction; heat dissipation; heating effects; high power density element; high-power devices; metal wiring; microprocessor; reliability; steady-state thermal behavior; temperature mismatch; three-dimensional FEM simulation; transient thermal behavior; wiring density; CMOS technology; Clocks; Driver circuits; Heating; Integrated circuit interconnections; Semiconductor device modeling; Silicon on insulator technology; Temperature; Thermal conductivity; Wiring;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2002.805755
