Abstract: A castellated-gate MOSFET I/O device capable of fully depleted operation is disclosed. The device includes a semiconductor substrate region having an upper portion with a top surface and a lower portion with a bottom surface. A source region and a drain region are formed in the semiconductor substrate region, and a channel-forming region is also disposed therein between the source and drain regions. Trench isolation insulator islands, having upper and lower surfaces, surround the source and drain regions as well as the channel-forming region. The channel-forming region includes a plurality of thin, spaced, vertically-orientated conductive channel elements that span longitudinally along the device between the source and drain regions. A gate structure is provided in the form of a plurality of spaced, castellated gate elements interposed between the channel elements, and a top gate member interconnects the gate elements at their upper vertical ends to cover the channel elements.

Abstract: A fully depleted castellated-gate MOSFET device is disclosed along with a method of making the same. The device has robust I/O applications, and includes a semiconductor substrate body having an upper portion with an upper end surface and a lower portion with a lower end surface. A source region, a drain region, and a channel-forming region between the source and drain regions are all formed in the semiconductor substrate body. trench isolation insulator islands surround the source and drain regions as well as the channel-forming region. The channel-forming region is made up of a plurality of thin, spaced, vertically-orientated conductive channel elements that span longitudinally along the device between the source and drain regions. A gate structure is also provided in the form of a plurality of spaced, castellated gate elements interposed between the channel elements.

Abstract: A Mixed-Signal Semiconductor Platform Incorporating Castellated-Gate MOSFET device(s) capable of Fully-Depleted operation is disclosed along with a method of making the same. The composite device/technology platform has robust I/O applications and includes a starting semiconductor substrate of a first conductivity type. One or more isolated regions of at least a first conductivity type is separated by trench isolation insulator islands. Within an isolated region designated for castellated-gate MOSFETs there exists a semiconductor body consisting of an upper portion with an upper surface, and a lower portion with a lower surface. Also within the castellated-gate MOSFET region, there exists a source region, a drain region, and a channel-forming region disposed between the source and drain regions, and are all formed within the semiconductor substrate body.

Abstract: A fully depleted castellated-gate MOSFET device is disclosed along with a method of making the same. The device has robust I/O applications, and includes a semiconductor substrate body having an upper portion with an upper end surface and a lower portion with a lower end surface. A source region, a drain region, and a channel-forming region between the source and drain regions are all formed in the semiconductor substrate body. trench isolation insulator islands surround the source and drain regions as well as the channel-forming region. The channel-forming region is made up of a plurality of thin, spaced, vertically-orientated conductive channel elements that span longitudinally along the device between the source and drain regions. A gate structure is also provided in the form of a plurality of spaced, castellated gate elements interposed between the channel elements.