Young-Seop Rah

Highly cost effective and high performance 65nm S/sup 3/ (stacked single-crystal Si) SRAM technology with 25F/sup 2/, 0.16um/sup 2/ cell and doubly stacked SSTFT cell transistors for ultra high density and high speed applications

In order to meet the great demands for higher density SRAM in all area of SRAM applications, the 25F/sup 2/S/sup 3/ (stacked single-crystal Si ) SRAM cell, which is a truly 3-dimensional device by stacking the load PMOS and the pass NMOS Tr. on the planar pull-down Tr., respectively in different levels, was developed and was reported in our previous study for low power applications. The previous reported S3 technology could not provide the high performance because it was developed for low power applications without salicide and high performance transistors. For the high performance transistor, the low thermal and low resistance processes are essential. In this study, the high performance CMOS transistors with 65nm gate length and l.6nm gate oxide, low resistance CVD Co for the small contact holes, and selectively formed CoSix in the peripheral area are added to the smallest 25F/sup 2/ double stacked S/sup 3/ SRAM cell for ultra high speed applications with the highest density such as 288M bits.

65nm high performance SRAM technology with 25F2 0.16/spl mu/m/sup 2/ S/sup 3/ (stacked single-crystal Si) SRAM cell, and stacked peripheral SSTFT for ultra high density and high speed applications

For the first time, the 65nm high performance transistor technology and the highly compacted double stacked S/sup 3/ SRAM cell with a size of 25F/sup 2/, and 0.16/spl mu/m/sup 2/ has been combined for providing the high density and high density solutions which can make the breakthrough in the field of the cache memory products and the network memory products. The SSTFT (single-crystal silicon thin film transistor) is used not only for cell transistors but also for peripheral transistors. The selective Co silicidation techniques is developed for low resistance. By utilizing this technology, the high performance 288Mb synchronous SRAM product will be fabricated.

A novel 0.79 /spl mu/m/sup 2/ SRAM cell by KrF lithography and high performance 90 nm CMOS technology for ultra high speed SRAM

The smallest SRAM cell, 0.79 /spl mu/m/sup 2/, was realized by a revolutionary cell layout, fine tuned OPC technique to overcome the 248 nm KrF lithography limitation, instead of using 193 nm ArF lithography. Sub-100 nm CMOS technology was indispensable to achieve the cell size as well as the performance. The high performance transistors were made with 80 nm gate length including 15 /spl Aring/ nitrided gate oxide layer, indium channel and halo implantation processes. The novel cell exhibits excellent neutron SER immunity, compared with ones of the SRAM cell by previous generation technologies.