Semiconductor lithography processes technology

1 nm 2 nm 3 nm 5 nm 7 nm 10 nm 14 nm 16 nm 20 nm 22 nm 28 nm 32 nm 40 nm 45 nm 55 nm 65 nm 80 nm 90 nm 110 nm 130 nm 150 nm 180 nm 220 nm 240 nm 250 nm 280 nm 350 nm 500 nm 600 nm 650 nm 700 nm 750 nm 800 nm 1 µm 1.2 µm 1.3 µm 1.5 µm 2 µm 2.5 µm 3 µm 3.5 µm 5 µm 6 µm 7 µm 8 µm 10 µm 16 µm 20 µm 50 µm

v · d · e

The 280 nanometer (280 nm) lithography process is was semiconductor manufacturing process following the 350 nm process. Commercial integrated circuit manufacturing using 280 nm process began in late 1990s. 280 nm and was phased out and later replaced by 250 nm, 220 nm, and 180 nm processes.

Industry

Around 1996 Intel introduced a stopgap shrink between 0.35 µm and 0.25 µm. Unlike 0.35 µm which used BiCMOS process for their Pentium and Pentium Pro processors, the 0.28 µm process was a standard CMOS process. Featuring a smaller transistor gate pitch, the process shared similar metal layer sizes to the 0.35 µm (this is why some Intel documents refer to it as "0.35µm"). The process was used in Intel's P55C (MMX) and P6 Klamath core-based and models. The semi-shrink which resulted in smaller transistors and improved switching speed was done to compensate for the return to CMOS (i.e., lack of fast bipolar transistors).

280 nm Microprocessors

This list is incomplete; you can help by expanding it.

280 nm Microarchitectures

• Intel P6

This list is incomplete; you can help by expanding it.