Abstract: A memory device includes a memory array having a plurality of memory cells. Each of the plurality of memory cells includes a first word line to apply a first signal to select the each of the plurality of memory cells to read data from or write the data to the each of the plurality of memory cells, a second word line to apply a second signal to select the each of the plurality of memory cells to read the data from or write the data to the each of the plurality of memory cells, and a bit line to read the data from the each of the plurality of memory cells or provide the data to write to the each of the plurality of memory cells upon selecting the each of the plurality of memory cells by at least one of the first word line or the second word line.

Abstract: A multiple gate oxidation process is provided. The process comprises the steps of (a) providing a silicon substrate (203) having a sacrificial oxide layer (207) thereon; (b) depositing and patterning a first layer of photoresist (209) on the sacrificial oxide layer, thereby forming a first region in which the sacrificial oxide layer is exposed; (c) etching the exposed sacrificial oxide layer within the first region, thereby forming a first etched region; (d) growing a first oxide layer (211) within the first etched region; (e) depositing and patterning a second layer of photoresist (213) on the sacrificial oxide layer and first oxide layer, thereby forming a second region in which the sacrificial oxide layer is exposed; (f) etching the exposed sacrificial oxide layer within the second region, thereby forming a second etched region; and (g) growing a second oxide layer (215) within the second etched region.

Abstract: A semiconductor device has recesses formed in the substrate during removal of the anti-reflective coating (ARC) because these recess locations are exposed during the etching of the ARC. Although the etchant is chosen to be selective between the ARC material and the substrate material, this selectivity is limited so that recesses do occur. A problem associated with the formation of these recesses is that the source/drains have further to diffuse to become overlapped with the gate. The result is that the transistors may have reduced current drive. The problem is avoided by waiting to perform the ARC removal until at least after formation of a sidewall spacer around the gate. The consequent recess formation thus occurs further from the gate, which results in reducing or eliminating the impediment this recess can cause to the source/drain diffusion that desirably extends to overlap with the gate.

Abstract: A method in the manufacture of ultra-large scale integrated circuit semiconductor devices suppresses boron loss due to segregation into the screen oxide during the boron activation rapid thermal anneal. A nitridation of the screen oxide is used to incorporate nitrogen into the screen oxide layer prior to boron implantation for ultra-shallow, source and drain extension junctions. A second nitridation of a second screen oxide is used prior to boron implantation for deeper, source and drain junctions. This method significantly suppresses boron diffusion and segregation away from the silicon substrate which reduces series resistance of the complete source and drain junctions.