Abstract: Some embodiments include a method of forming a pattern. A semiconductor substrate has first and second rows extending along a first direction, and which alternate with one another along a second direction. Each of the rows includes course regions that are to be included along patterned structures. The course regions within the first rows are staggered relative to the course regions within the second rows. The patterned structures comprise first segments which extend along a third direction, and comprise second segments which extend along a fourth direction different from the third direction. Patterned masking material is formed across the substrate to define a first pattern having the first segments of the patterned structures, and to define a second pattern having the second segments of the patterned structures. The patterned structures are formed within the first and second patterns defined by the patterned masking material. Some embodiments include apparatuses having finFETs.

Abstract: 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.

Abstract: Some embodiments include a floating body transistor which has a gate structure configured as a bracket having two upwardly-projecting sidewalls joined to a base. A region between the upwardly-projecting sidewalls is an interior region of the bracket. The interior region of the bracket has an interior surface along an upper surface of the base, and along inward surfaces of the upwardly-projecting sidewalls. The sidewalls are a first sidewall and a second sidewall. The first and second sidewalls have first and second notches, respectively, which extend downwardly into the first and second sidewalls. The first and second notches are horizontally aligned with one another. Dielectric material lines the interior surface of the bracket. A semiconductor material body is within the interior region of the bracket and along the dielectric material. The semiconductor material body has a third notch which is horizontally aligned with the first and second notches.

Abstract: Some embodiments include memory arrays having rows of fins. Each fin includes a first pedestal, a second pedestal and a trench 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 trench between the first and second pedestals. The rows are subdivided amongst deep-type (D) rows and shallow-type (S) rows, with the deep-type rows having deeper channel regions than the shallow-type rows. Some embodiments include rows of fins in which the channel regions along individual rows are subdivided amongst deep-type (D) channel regions and shallow-type (S) channel regions, with the deep-type channel regions being below the shallow-type channel regions.

Abstract: A semiconductor device is provided that includes a fin having a first upper gate on a sidewall of the fin in a first trench and a second upper gate formed on the opposite sidewall of the fin. The device also includes a first lower gate on the sidewall and a second lower gate on the opposite sidewall, wherein the first upper gate is formed above the first lower gate and the second upper gate is formed above the second lower gate. Methods of manufacturing and operating the device are also included. A method of operation may include biasing the first upper gate and second upper gate to preselect the transistors of a fin and then biasing the first lower gate and second lower gate to operate the transistors of the fin.

Abstract: A method used in fabrication of a recessed access device transistor gate has increased tolerance for mask misalignment. One embodiment of the invention comprises forming a vertical spacing layer over a semiconductor wafer, then etching the vertical spacing layer and the semiconductor wafer to form a recess in the wafer. A conductive transistor gate layer is then formed within the trench and over the vertical spacing layer. The transistor gate layer is etched, which exposes the vertical spacing layer. A spacer layer is formed over the etched conductive gate layer and over the vertical spacing layer, then the spacer layer and the vertical spacing layer are anisotropically etched. Subsequent to anisotropically etching the vertical spacing layer, a portion of the vertical spacing layer is interposed between the semiconductor wafer and the etched conductive transistor gate layer in a direction perpendicular to the plane of a major surface of the semiconductor wafer.

Abstract: A semiconductor device is provided that includes a fin having a first gate and a second gate formed on a first sidewall of the fin in a first trench, wherein the first gate is formed above the second gate. The device includes a third gate and a fourth gate formed on a second sidewall of the fin in a second trench, wherein the third gate is formed above the fourth gate. Methods of manufacturing and operating the device are also included. A method of operation may include biasing the first gate and the fourth gate to create a current path across the fin.

Abstract: A device may include a first transistor, a second transistor, and a data element. The first transistor may have a column gate and a channel, and the second transistor may include a row gate that crosses over the column gate, under the column gate, or both. The second transistor may also include another channel, a source disposed near a distal end of a first leg, and a drain disposed near a distal end of a second leg. The column gate may extend between the first leg and the second leg. The channel of the second transistor may be connected to the channel of the first transistor, and the data element may be connected to the source or the drain. Methods, systems, and other devices are contemplated.

Abstract: A method of equilibrating digit lines, a memory array, device, system and wafer for digit lines configured in an open digit line architecture. The digit lines are equilibrated by coupling a terminated end of a first digit line to an equilibration reference and coupling an unterminated end of a second digit line to the terminated end of the first digit line. The memory array is configured with the first and second digit lines arranged directly adjacent to each other.

Abstract: Disclosed are methods, systems and devices, including a method that includes the acts of forming a semiconductor fin, forming a sacrificial material adjacent the semiconductor fin, covering the sacrificial material with a dielectric material, forming a cavity by removing the sacrificial material from under the dielectric material, and forming a gate in the cavity.

Abstract: Methods and devices depicting fabrication of non-planar access devices having fins and narrow trenches, among which is a method that includes wet etching a conductor to form a recessed region and subsequently etching the conductor to form gates on the fins. The wet etching may include formation of recesses which are may be backfilled with a fill material to form spacers on the conductor. Portions of a plug may be removed during the wet etch to form overhanging spacers to provide further protection of the conductor during the dry etch.

Abstract: Disclosed are methods, systems and devices, including a system, having a memory device. In some embodiments, the memory device includes a plurality of fin field-effect transistors disposed in rows, a plurality of insulating fins each disposed between the rows, and a plurality of memory elements each coupled to a terminal of a fin field-effect transistor among the plurality of fin field-effect transistors.

Abstract: A method of forming an apparatus includes forming a plurality of deep trenches and a plurality of shallow trenches in a first region of a substrate. At least one of the shallow trenches is positioned between two deep trenches. The shallow trenches and the deep trenches are parallel to each other. A layer of conductive material is deposited over the first region and a second region of the substrate. The layer of conductive material is etched to define lines separated by gaps over the first region of the substrate, and active device elements over the second region of the substrate. The second region of the substrate is masked and the lines are removed from the first region of the substrate. Elongate trenches are etched where the lines were removed in the while the second region of the substrate is masked.

Abstract: A method is provided for forming SRAM cells with low energy implants. Embodiments include forming deep trenches in a silicon substrate; forming a deep n-well or deep p-well around a bottom of each deep trench; filling the deep trenches with oxide; forming a first or second shallow trench between each pair of adjacent deep trenches; forming a first p-well or first n-well, respectively, above each deep n-well or p-well; forming a second n-well at a bottom of each first shallow trench; forming a p+ region above each second n-well on each side of each first shallow trench; filling the first shallow trenches with oxide; forming a second p-well at a bottom of each second shallow trench; filling the second shallow trenches with oxide; forming a n+ region above each second p-well on each side of each second shallow trench.

Abstract: Disclosed are methods, systems and devices, including a method that includes the acts of etching an inter-row trench in a substrate, substantially or entirely filling the inter-row trench with a dielectric material, and forming a fin and a insulating projection at least in part by etching a gate trench in the substrate. In some embodiments, the insulating projection includes at least some of the dielectric material in the inter-row trench.

Abstract: Methods of isolating gates in a semiconductor structure. In one embodiment, isolation is achieved using a spacer material in combination with fins. In another embodiment, etch characteristics of various materials utilized in fabrication of the semiconductor structure are used to increase an effective gate length (“Leffective”) and a field gate oxide. Semiconductor structures formed by these methods are also disclosed.

Abstract: A method and device are provided for etching and replacing silicon fins in connection with a FinFET integration process. Embodiments include providing a first plurality and a second plurality of silicon fins on a silicon wafer with an oxide between adjacent silicon fins; forming a first nitride liner on an upper surface of the first plurality of silicon fins and the oxide therebetween; etching the second plurality of silicon fins, forming trenches; removing the first nitride liner; depositing a second nitride liner on an upper surface of the first plurality of silicon fins and the oxide therebetween and in the trenches; removing the second nitride liner down to the upper surface of the first plurality of silicon fins; and recessing the oxide.

Abstract: A method used in fabrication of a recessed access device transistor gate has increased tolerance for mask misalignment. One embodiment of the invention comprises forming a vertical spacing layer over a semiconductor wafer, then etching the vertical spacing layer and the semiconductor wafer to form a recess in the wafer. A conductive transistor gate layer is then formed within the trench and over the vertical spacing layer. The transistor gate layer is etched, which exposes the vertical spacing layer. A spacer layer is formed over the etched conductive gate layer and over the vertical spacing layer, then the spacer layer and the vertical spacing layer are anisotropically etched. Subsequent to anisotropically etching the vertical spacing layer, a portion of the vertical spacing layer is interposed between the semiconductor wafer and the etched conductive transistor gate layer in a direction perpendicular to the plane of a major surface of the semiconductor wafer.

Abstract: A device includes a plurality of trenches and fins defined in a substantially un-doped layer of semiconducting material, a gate insulation layer positioned on the fins and on the bottom of the trenches, a gate electrode and a device isolation structure. One method disclosed herein involves identifying a top width of each of a plurality of fins and a depth of a plurality of trenches to be formed in a substantially un-doped layer of semiconducting material, wherein, during operation, the device is adapted to operate in at least three distinguishable conditions depending upon a voltage applied to the device, performing at least one process operation to define the trenches and fins in the layer of semiconducting material, forming a gate insulation layer on the fins and on a bottom of the trenches and forming a gate electrode above the gate insulation layer.

Abstract: A method is provided for forming SRAM cells with low energy implants. Embodiments include forming deep trenches in a silicon substrate; forming a deep n-well or deep p-well around a bottom of each deep trench; filling the deep trenches with oxide; forming a first or second shallow trench between each pair of adjacent deep trenches; forming a first p-well or first n-well, respectively, above each deep n-well or p-well; forming a second n-well at a bottom of each first shallow trench; forming a p+ region above each second n-well on each side of each first shallow trench; filling the first shallow trenches with oxide; forming a second p-well at a bottom of each second shallow trench; filling the second shallow trenches with oxide; forming a p+ region above each second n-well on each side of each first shallow trench; and forming an n+ region above each second p-well.