A method is described. The method includes forming bit line structures above bitline contact structures, forming a first material on top surfaces and sidewall surfaces of the bit line structures to establish step structures for via formation, and forming a second material on the top surface of the first material. Capacitor landing structures are formed by patterning the second material.

Methods of forming high voltage (111) silicon nano-structures are described. Those methods and structures may include forming a III-V device layer on (111) surface of a silicon fin structure, forming a 2DEG inducing polarization layer on the III-V device layer, forming a source/drain material on a portion of the III-V device layer on terminal ends of the silicon fin. A middle portion of the silicon fin structure between the source and drain regions may be removed, and backfilled with a dielectric material, and then a gate dielectric and a gate material may be formed on the III-V device layer.

Some embodiments include a memory array which has rows of fins. Each fin has a first pedestal, a second pedestal and a trough between the first and second pedestals. A first source/drain region is within the first pedestal, a second source/drain region is within the second pedestal, and a channel region is along the trough between the first and second pedestals. Digit lines are electrically coupled with the first source/drain regions. Ferroelectric capacitors are electrically coupled with the second source/drain regions. Wordlines are along the rows of fins and overlap the channel regions. Conductive isolation lines are under the wordlines along the rows of fins.

A method of fabricating a semiconductor device. The method includes forming a dummy structure over a substrate, forming conductive features on opposite sides of the dummy gate structure, removing the dummy structure and a portion of the substrate beneath the dummy gate structure to form a trench, and filling the trench with a dielectric material.

Some embodiments include a transistor having a semiconductor material with a trench extending downwardly therein. The semiconductor material has a first post region on one side of the trench and a second post region on an opposing side of the trench. The semiconductor material has a narrow fin region along the bottom of the trench and extending between the first and second post regions. Each of the first and second post regions has a first thickness and the narrow fin region has a second thickness, with the second thickness being less than the first thickness. Gate dielectric material is along sidewalls of the first and second post regions, along a top of the narrow fin region, and along side surfaces of the narrow fin region. Gate material is over the gate dielectric material. First and second source/drain regions are within the first and second post regions.

A method of manufacturing a semiconductor device includes forming a first semiconductor layer on a substrate, forming a stack of semiconductor layer structures on the first semiconductor layer, and etching the stack to form a fin structure. Each of the semiconductor layer structures includes a first insulator layer and a second semiconductor layer on the first insulator layer. The first and second semiconductor layers have the same semiconductor compound. The fin structure according to the novel method includes one or more insulator layers to achieve a higher on current/off current ratio, thereby improving the device performance relative to conventional fin structures without the insulator layers.

A semiconductor device, the device comprising: a plurality of transistors, wherein at least one of said plurality of transistors comprises a first single crystal source, channel, and drain, wherein at least one of said plurality of transistors comprises a second single crystal source, channel, and drain, wherein said second single crystal source, channel, and drain is disposed above said first single crystal source, channel, and drain, wherein at least one of said plurality of transistors comprises a third single crystal source, channel, and drain, wherein said third single crystal source, channel, and drain is disposed above said second single crystal source, channel, and drain, wherein at least one of said plurality of transistors comprises a fourth single crystal source, channel, and drain, and wherein said third single crystal channel is self-aligned to said fourth single crystal channel being processed following the same lithography step.

A method for fabricating a semiconductor device includes: preparing a substrate; forming an isolation layer defining an active region in the substrate; forming a first insulation structure over the substrate, the first insulation structure defining a line-type opening that exposes the isolation layer and the active region; forming a plug pad through a Selective Epitaxial Growth (SEG) process over the exposed active regions; forming a second insulation structure inside the line-type opening, the second insulation structure defining a contact hole landing on the plug pad; and filling the contact hole with a contact plug.

A semiconductor structure includes an array of fins extending horizontally across a substrate. A plurality of transistors are embedded in the fins. The transistors include a 1.sup.st S/D region and a 2.sup.nd S/D region defining a channel region therebetween. The transistors have a gate structure disposed over the channel region and extending perpendicular to the fins. An ILD layer is disposed over the structure. The ILD layer includes a plurality of TS trenches disposed over the 1.sup.st and 2.sup.nd S/D regions. The TS tranches extend parallel to the gate structures. A plurality of storage capacitors are disposed within the TS trenches. The storage capacitors include a 1.sup.st metal terminal electrically connected to one of the 1.sup.st and 2.sup.nd S/D regions, a 2.sup.nd metal terminal and a capacitor dielectric disposed therebetween. Each transistor is electrically connected to a single storage capacitor to form an eDRAM cell.

The disclosure relates to a highly integrated memory device and a method for manufacturing the same. According to the disclosure, a memory device comprises a lower structure, an active layer horizontally oriented parallel to a surface of the lower structure, a bit line connected to a first end of the active layer and vertically oriented from the surface of the lower structure, a capacitor connected to a second end of the active layer, a word line horizontally oriented to be parallel with the active layer along a side surface of the active layer, and a fin channel layer horizontally extending from one side surface of the active layer, wherein the word line includes a protrusion covering the fin channel layer.