Abstract: A one-time programmable memory device includes a well of a first polarity in a semiconductor substrate. A lightly-doped drain (LDD) region is above one portion of the well. The LDD region has a first doping concentration and a second polarity that is opposite the first polarity. A source region or a drain region of the second polarity is above another portion of the well. The source region or the drain region has a second doping concentration that is higher than the first doping concentration. A first breakdown voltage between the LDD region and the well region is higher than a second breakdown voltage between the source region or the drain region and the well region. A select device is positioned at least partially above a portion of the source region or the drain region. The select device is configured to form a channel between the source region or the drain region and the LDD region. An anti-fuse device is positioned at least partially above a portion of the LDD region.

Abstract: An OTP memory device includes a first and a second doped region of the same polarity in a semiconductor substrate. The second doped region has a higher doping concentration than the first doped region. A source region and a drain region of an opposite polarity are also in the semiconductor substrate. The source is positioned over the lower doped region, and the drain is positioned over the higher doped region. A plurality of anti-fuse devices, separated from each other by a portion of the lower doped region, are each positioned at least partially above a respective portion of the source region (and, in turn, above the lower doped region). A first metal line is coupled to a first subset of the anti-fuse devices, and a second metal line is coupled to a different, second subset of the anti-fuse devices arranged between the anti-fuses in the first subset.

Abstract: A one-time programmable memory device includes a well of a first polarity in a semiconductor substrate. A lightly-doped drain (LDD) region is above one portion of the well. The LDD region has a first doping concentration and a second polarity that is opposite the first polarity. A source region or a drain region of the second polarity is above another portion of the well. The source region or the drain region has a second doping concentration that is higher than the first doping concentration. A first breakdown voltage between the LDD region and the well region is higher than a second breakdown voltage between the source region or the drain region and the well region. A select device is positioned at least partially above a portion of the source region or the drain region. The select device is configured to form a channel between the source region or the drain region and the LDD region. An anti-fuse device is positioned at least partially above a portion of the LDD region.

Abstract: An OTP memory device includes a first and a second doped region of the same polarity in a semiconductor substrate. The second doped region has a higher doping concentration than the first doped region. A source region and a drain region of an opposite polarity are also in the semiconductor substrate. The source is positioned over the lower doped region, and the drain is positioned over the higher doped region. A plurality of anti-fuse devices, separated from each other by a portion of the lower doped region, are each positioned at least partially above a respective portion of the source region (and, in turn, above the lower doped region). A first metal line is coupled to a first subset of the anti-fuse devices, and a second metal line is coupled to a different, second subset of the anti-fuse devices arranged between the anti-fuses in the first subset.

Abstract: A method of forming an NMOS device with reduced device degradation, generated during a constant current stress, has been developed. The reduced device degradation is attributed to the use of a high temperature oxide (HTO), layer, used as an underlying component of composite insulator spacers, formed on the sides of the NMOS gate structures. After definition of an insulator capped polycide gate structure a thin, (140 to 160 Angstrom), HTO layer is deposited at a temperature between about 700 to 800° C., followed by the deposition of a silicon nitride layer. Definition of the composite insulator layer, comprised with the underlying, HTO, results in NMOS devices with reduced drain current and reduced transconductance values, when compared to counterparts fabricated with composite insulator spacers formed without the thin, HTO layer featured in this invention.