Abstract: Two trenches having different widths are formed in a semiconductor-on-insulator (SOI) substrate. An oxygen-impermeable layer and a fill material layer are formed in the trenches. The fill material layer and the oxygen-impermeable layer are removed from within a first trench. A thermal oxidation is performed to convert semiconductor materials underneath sidewalls of the first trench into an upper thermal oxide portion and a lower thermal oxide portion, while the remaining oxygen-impermeable layer on sidewalls of a second trench prevents oxidation of the semiconductor materials. After formation of a node dielectric on sidewalls of the second trench, a conductive material is deposited to fill the trenches, thereby forming a conductive trench fill portion and an inner electrode, respectively. The upper and lower thermal oxide portions function as components of dielectric material portions that electrically isolate two device regions.

Abstract: A semiconductor structure is provided that includes a semiconductor oxide layer having features. The semiconductor oxide layer having the features is located between an active semiconductor layer and a handle substrate. The semiconductor structure includes a planarized top surface of the active semiconductor layer such that the semiconductor oxide layer is beneath the planarized top surface. The features within the semiconductor oxide layer are mated with a surface of the active semiconductor layer.

Abstract: A high-k dielectric metal trench capacitor and improved isolation and methods of manufacturing the same is provided. The method includes forming at least one deep trench in a substrate, and filling the deep trench with sacrificial fill material and a poly material. The method further includes continuing with CMOS processes, comprising forming at least one transistor and back end of line (BEOL) layer. The method further includes removing the sacrificial fill material from the deep trenches to expose sidewalls, and forming a capacitor plate on the exposed sidewalls of the deep trench. The method further includes lining the capacitor plate with a high-k dielectric material and filling remaining portions of the deep trench with a metal material, over the high-k dielectric material. The method further includes providing a passivation layer on the deep trench filled with the metal material and the high-k dielectric material.

Abstract: An electrical structure is provided that includes a dielectric layer present on a semiconductor substrate and a via opening present through the dielectric layer. An interconnect is present within the via opening. A metal semiconductor alloy contact is present in the semiconductor substrate. The metal semiconductor alloy contact has a perimeter defined by a convex curvature relative to a centerline of the via opening. The endpoints for the convex curvature that defines the metal semiconductor alloy contact are aligned to an interface between a sidewall of the via opening, a sidewall of the interconnect and an upper surface of the semiconductor substrate.

Abstract: Arbitrarily and continuously scalable on-currents can be provided for fin field effect transistors by providing two independent variables for physical dimensions for semiconductor fins that are employed for the fin field effect transistors. A recessed region is formed on a semiconductor layer over a buried insulator layer. A dielectric cap layer is formed over the semiconductor layer. Disposable mandrel structures are formed over the dielectric cap layer and spacer structures are formed around the disposable mandrel structures. Selected spacer structures can be structurally damaged during a masked ion implantation. An etch is employed to remove structurally damaged spacer structures at a greater etch rate than undamaged spacer structures. After removal of the disposable mandrel structures, the semiconductor layer is patterned into a plurality of semiconductor fins having different heights and/or different width. Fin field effect transistors having different widths and/or heights can be subsequently formed.

Abstract: Device structures and design structures that include a silicon controlled rectifier, as well as fabrication methods for such device structures. A well is formed in the device layer of a silicon-on-insulator substrate. A silicon controlled rectifier is formed that includes an anode in the well. A deep trench capacitor is formed that includes a plate coupled with the well. The plate of the deep trench capacitor extends from the device layer through a buried insulator layer of the silicon-on-insulator substrate and into a handle wafer of the silicon-on-insulator substrate.

Abstract: A semiconductor device is provided that includes a gate structure on a channel region of a substrate. A source region and a drain region are present on opposing sides of the channel region. A first metal semiconductor alloy is present on an upper surface of at least one of the source and drain regions. The first metal semiconductor alloy extends to a sidewall of the gate structure. A dielectric layer is present over the gate structure and the first metal semiconductor alloy. An opening is present through the dielectric layer to a portion of the first metal semiconductor alloy that is separated from the gate structure. A second metal semiconductor alloy is present in the opening, is in direct contact with the first metal semiconductor alloy, and has an upper surface that is vertically offset and is located above the upper surface of the first metal semiconductor alloy.

Abstract: Methods of forming an electrically programmable fuse (e-fuse) structure and the e-fuse structure are disclosed. One embodiment of an e-fuse structure includes: a silicon structure; a pair of silicide contact regions overlying the silicon structure; and a silicide link overlying the silicon structure and connecting the pair of silicide regions, the silicide link having a depth less than a depth of each of the pair of silicide contact regions.

Abstract: A memory device, and a method of forming a memory device, is provided that includes a capacitor with a lower electrode of a metal semiconductor alloy. In one embodiment, the memory device includes a trench present in a semiconductor substrate including a semiconductor on insulating (SOI) layer on top of a buried dielectric layer, wherein the buried dielectric layer is on top of a base semiconductor layer. A capacitor is present in the trench, wherein the capacitor includes a lower electrode of a metal semiconductor alloy having an upper edge that is self-aligned to the upper surface of the base semiconductor layer, a high-k dielectric node layer, and an upper electrode of a metal. The memory device further includes a pass transistor in electrical communication with the capacitor.

Abstract: An electrical fuse has an anode contact on a surface of a semiconductor substrate. The electrical fuse has a cathode contact on the surface of the semiconductor substrate spaced from the anode contact. The electrical fuse has a link within the substrate electrically interconnecting the anode contact and the cathode contact. The link comprises a semiconductor layer and a silicide layer. The silicide layer extends beyond the anode contact. An opposite end of the silicide layer extends beyond the cathode contact. A silicon germanium region is embedded in the semiconductor layer under the silicide layer, between the anode contact and the cathode contact.

Abstract: An electrical fuse has an anode contact on a surface of a semiconductor substrate. The electrical fuse has a cathode contact on the surface of the semiconductor substrate spaced from the anode contact. The electrical fuse has a link within the substrate electrically interconnecting the anode contact and the cathode contact. The link comprises a semiconductor layer and a silicide layer. The silicide layer extends beyond the anode contact. An opposite end of the silicide layer extends beyond the cathode contact. A silicon germanium region is embedded in the semiconductor layer under the silicide layer, between the anode contact and the cathode contact.

Abstract: A dielectric template layer is deposited on a substrate. Line trenches are formed within the dielectric template layer by an anisotropic etch that employs a patterned mask layer. The patterned mask layer can be a patterned photoresist layer, or a patterned hard mask layer that is formed by other image transfer methods. A lower portion of each line trench is filled with an epitaxial rare-earth oxide material by a selective rare-earth oxide epitaxy process. An upper portion of each line trench is filled with an epitaxial semiconductor material by a selective semiconductor epitaxy process. The dielectric template layer is recessed to form a dielectric material layer that provides lateral electrical isolation among fin structures, each of which includes a stack of a rare-earth oxide fin portion and a semiconductor fin portion.

Abstract: A high-k dielectric metal trench capacitor and improved isolation and methods of manufacturing the same is provided. The method includes forming at least one deep trench in a substrate, and filling the deep trench with sacrificial fill material and a poly material. The method further includes continuing with CMOS processes, comprising forming at least one transistor and back end of line (BEOL) layer. The method further includes removing the sacrificial fill material from the deep trenches to expose sidewalls, and forming a capacitor plate on the exposed sidewalls of the deep trench. The method further includes lining the capacitor plate with a high-k dielectric material and filling remaining portions of the deep trench with a metal material, over the high-k dielectric material. The method further includes providing a passivation layer on the deep trench filled with the metal material and the high-k dielectric material.

Abstract: Device structures and design structures that include a silicon controlled rectifier, as well as fabrication methods for such device structures. A well is formed in the device layer of a silicon-on-insulator substrate. A silicon controlled rectifier is formed that includes an anode in the well. A deep trench capacitor is formed that includes a plate coupled with the well. The plate of the deep trench capacitor extends from the device layer through a buried insulator layer of the silicon-on-insulator substrate and into a handle wafer of the silicon-on-insulator substrate.

Abstract: Shallow trench isolation structures are formed within a semiconductor layer of a substrate to define an active area. The active area is recessed relative to a top surface of the shallow trench isolation structure. A shallow trench isolation (STI) spacer is formed on sidewalls of the shallow trench isolation structure around the periphery of the active area. After formation of a gate stack structure and a gate spacer, trenches are formed such that sidewalls of the trenches are vertically coincident with sidewalls of the gate spacer and the STI spacer. Epitaxial semiconductor material can be deposited into the trenches by selective epitaxy to form an embedded source region and an embedded drain region. Because all surfaces of the trenches are semiconductor surfaces, the entire trenches can be filled with the epitaxial semiconductor material, thereby enabling lateral confinement of stress within a channel region of a field effect transistor.

Abstract: A structural alternative to retro doping to reduce transistor leakage is provided by providing a liner in a trench, undercutting a conduction channel region in an active semiconductor layer, etching a side, corner and/or bottom of the conduction channel where the undercut exposes semiconductor material in the active layer and replacing the removed portion of the conduction channel with insulator. This shaping of the conduction channel increases the distance to adjacent circuit elements which, if charged, could otherwise induce a voltage and cause a change in back-channel threshold in regions of the conduction channel and narrows and reduces cross-sectional area of the channel where the conduction in the channel is not well-controlled; both of which effects significantly reduce leakage of the transistor.

Abstract: A structure and method to fabricate a body contact on a transistor is disclosed. The method comprises forming a semiconductor structure with a transistor on a handle wafer. The structure is then inverted, and the handle wafer is removed. A silicided body contact is then formed on the transistor in the inverted position. The body contact may be connected to neighboring vias to connect the body contact to other structures or levels to form an integrated circuit.

Abstract: In a vertical dynamic memory cell, monocrystalline semiconductor material of improved quality is provided for the channel of an access transistor by lateral epitaxial growth over an insulator material (which complements the capacitor dielectric in completely surrounding the storage node except at a contact connection structure, preferably of metal, from the access transistor to the storage node electrode) and etching away a region of the lateral epitaxial growth including a location where crystal lattice dislocations are most likely to occur; both of which features serve to reduce or avoid leakage of charge from the storage node. An isolation structure can be provided in the etched region such that space is provided for connections to various portions of a memory cell array.

Abstract: A method of forming a field effect transistor (FET) device includes forming a gate structure over a substrate, the gate structure including a wide bottom portion and a narrow portion formed on top of the bottom portion; the wide bottom portion comprising a metal material and having a first width that corresponds substantially to a transistor channel length, and the narrow portion also including a metal material having a second width smaller than the first width.

Abstract: A field effect transistor (FET) structure on a semiconductor substrate which includes a gate structure having a spacer on a semiconductor substrate; an extension implant underneath the gate structure; a recessed source and a recessed drain filled with a doped epitaxial material; halo implanted regions adjacent a bottom of the recessed source and drain and being underneath the gate stack. In an exemplary embodiment, there is implanted junction butting underneath the bottom of each of the recessed source and drain, the junction butting being separate and distinct from the halo implanted regions. In another exemplary embodiment, the doped epitaxial material is graded from a lower dopant concentration at a side of the recessed source and drain to a higher dopant concentration at a center of the recessed source and drain. In a further exemplary embodiment, the semiconductor substrate is a semiconductor on insulator substrate.