A method of forming a thin-film transistor includes providing a substrate having a top surface and a recess in the top surface. An electrically conductive gate is provided within the recess. A conformal insulating material layer and a conformal semiconductor material layer are formed in the recess, with the semiconductor material layer extending over the top surface of the substrate outside of the recess. Source and drain electrodes are formed by adding a deposition inhibitor material on a portion of the substrate including within the recess; and depositing a thin-film of electrically conductive material, wherein the deposition inhibitor material inhibits the deposition of the electrically conductive material such that the electrically conductive material is patterned by the deposition inhibitor material during deposition, wherein the patterned electrically conductive material provides the source electrode on a first side of the recess and the drain electrode on a second side of the recess.

Methods are provided for fabricating self-aligned, low resistance metal interconnect structures, as well as semiconductor devices comprising such metal interconnect structures. A first metal line is formed in a first insulating layer. An etch stop layer is formed by selectively depositing dielectric material on the first insulating layer. A second insulating layer is formed over the etch stop layer and the first metal line, and an opening is etched in the second insulating layer selective to the etch stop layer to prevent etching of the first insulating layer. The opening is filled with a metallic material to form a second metal line in contact with the first metal line. The first and second metal lines are formed with aspect ratios that are less than 2.5 to minimize resistivity of the metal lines. The first and second metal lines collectively form a single metal line of an interconnect structure.

A semiconductor structure and a manufacturing method of the same are provided. The semiconductor structure includes a stack structure, an etching stop layer, and a conductive structure. The stack structure includes a plurality of conductive layers and a plurality of insulating layers stacked interlacedly. The etching stop layer is formed on a sidewall of the stack structure. An energy gap of the etching stop layer is larger than 6 eV. The conductive structure is electrically connected to at least one of the conductive layers.

A semiconductor package which is free of metal debris from backside metallization (BSM) is disclosed. The semiconductor package is singulated by performing a saw street open process from the frontside of the wafer and then includes a singulation process using a plasma etch from the backside of the wafer with BSM. The singulation process results in metal debris free packages.

Various methods and devices that involve EMI shields for radio frequency layer transferred devices are disclosed. One method comprises forming a radio frequency field effect transistor in an active layer of a semiconductor on insulator wafer. The semiconductor on insulator wafer has a buried insulator side and an active layer side. The method further comprises bonding a second wafer to the active layer side of the semiconductor on insulator wafer. The method further comprises forming a shield layer for the semiconductor device. The shield layer comprises an electrically conductive material. The method further comprises coupling the radio frequency field effect transistor to a circuit comprising a radio frequency component. The method further comprises singulating the radio frequency field effect transistor, radio frequency component, and the shield layer into a die. The shield layer is located between a substrate of the radio frequency component and the radio frequency field effect transistor.

Some embodiments include a memory device and methods of forming the memory device. One such memory device includes a first group of memory cells, each of the memory cells of the first group being formed in a cavity of a first control gate located in one device level of the memory device. The memory device also includes a second group of memory cells, each of the memory cells of the second group being formed in a cavity of a second control gate located in another device level of the memory device. Additional apparatus and methods are described.

A device, structure, and method are provided whereby an insert layer is utilized to provide additional support for surrounding dielectric layers. The insert layer may be applied between two dielectric layers. Once formed, trenches and vias are formed within the composite layers, and the insert layer will help to provide support that will limit or eliminate undesired bending or other structural motions that could hamper subsequent process steps, such as filling the trenches and vias with conductive material.

A method for forming a semiconductor device comprises forming an insulation trench structure comprising insulation material extending into the semiconductor substrate from a surface of the semiconductor substrate. The insulation trench structure laterally surrounds a portion of the semiconductor substrate. The method further comprises modifying the laterally surrounded portion of the semiconductor substrate to form a vertical electrically conductive structure comprising an alloy material. The alloy material is an alloy of the semiconductor substrate material and at least one metal.

A semiconductor memory device includes a substrate having a memory region and a peripheral region that are adjacent to each other, and a plurality of insulating layers and a plurality of wiring layers that are alternately formed on the memory region and the peripheral region of the substrate. On the memory region, the insulating layers and the wiring layers are alternately formed along a thickness direction of the memory device. On the peripheral region, first portions of the insulating layers and first portions of the wiring layers are alternately formed along the thickness direction and second portions of the insulating layers and second portions of the wiring layers are alternately formed along a lateral direction. A width of the second portion of each of the wiring layers in the lateral direction is greater than a thickness of the first portion of the wiring layer.

An integrated circuit, including: at least three integrated circuit portions mutually spaced on a single electrically insulating die, the integrated circuit portions being mutually galvanically isolated; and signal coupling structures on the die to allow communication of signals between the integrated circuit portions while maintaining the galvanic isolation therebetween.