Abstract: A semiconductor device includes a substrate having a cell area including a memory cell region and a dummy cell region, gate structures formed in the cell region, an insulating interlayer formed on the substrate to cover the gate structures, plugs formed through the insulating interlayer, bit lines contacting the plugs in the memory cell region, and dummy bit line structures contacting the plugs in the dummy cell region. The dummy bit line structure prevents a leakage current generated in a peripheral circuit area from flowing into a cell area.

Abstract: A semiconductor device includes a first semiconductor layer, a first interlayer insulation layer, a second semiconductor layer, and a gate pattern. The first interlayer insulation layer covers the first semiconductor layer. The second semiconductor layer is formed on the first interlayer insulation layer and includes source regions, drain regions, and a channel region interposed between the source region and the drain region. The gate pattern includes a gate insulation layer on the channel region of the second semiconductor layer. At least one of the source regions and the drain regions includes an elevated layer having a top surface higher than that of the channel region.

Abstract: A semiconductor device is formed with a normal, non-recessed, spacer structure in a cell region and a recessed spacer structure in a peripheral region. The recessed spacer structure is formed as by etch masking those in the cell region and exposing those in the peripheral region, then performing an etch process. The increased height of the cell region spacers is adapted to further prevent over-etching during gate interconnect formation which would otherwise result in etching through the spacer to the substrate and subsequent short circuit. Therefore, it is also possible to prevent bridge defects due to over-etching, which occurs because the barrier metal layer for a subsequent interconnection contact is accidentally connected to the underlying substrate. Also, since the recessed spacer structure is provided in the peripheral region, it is possible to remarkably enhance a resistance distribution of a cobalt silicide layer occurring in a gate line width of 100 nm or less.

Abstract: A semiconductor device includes a first semiconductor layer, a first interlayer insulation layer, a second semiconductor layer, and a gate pattern. The first interlayer insulation layer covers the first semiconductor layer. The second semiconductor layer is formed on the first interlayer insulation layer and includes source regions, drain regions, and a channel region interposed between the source region and the drain region. The gate pattern includes a gate insulation layer on the channel region of the second semiconductor layer. At least one of the source regions and the drain regions includes an elevated layer having a top surface higher than that of the channel region.

Abstract: A semiconductor device is formed with a normal, non-recessed, spacer structure in a cell region and a recessed spacer structure in a peripheral region. The recessed spacer structure is formed as by etch masking those in the cell region and exposing those in the peripheral region, then performing an etch process. The increased height of the cell region spacers is adapted to further prevent over-etching during gate interconnect formation which would otherwise result in etching through the spacer to the substrate and subsequent short circuit. Therefore, it is also possible to prevent bridge defects due to over-etching, which occurs because the barrier metal layer for a subsequent interconnection contact is accidentally connected to the underlying substrate. Also, since the recessed spacer structure is provided in the peripheral region, it is possible to remarkably enhance a resistance distribution of a cobalt silicide layer occurring in a gate line width of 100 nm or less.