A field effect transistor (FET) structure and method for making the same is disclosed. In an aspect, a method of fabricating a semiconductor structure comprises providing a FET structure disposed above a substrate, the FET structure comprising a vertical metal gate structure disposed between a pair of source/drain (S/D) epitaxial (EPI) structures and having a set of vertically-stacked, horizontal nanosheets extending through the vertical metal gate structure in the first horizontal direction to electrically connect the S/D EPI structures to each other. The method further comprises removing the substrate, removing the portion of vertical metal gate structure below the bottom-most nanosheet, removing at least enough of the bottom-most nanosheet to sever the its electrical conducting path between the S/D EPI structures, and filling the void created by the removed gate metal and nanosheet with a dielectric material that also covers the bottom surfaces of the S/D EPI structures.

Gate-all-around integrated circuit structures having depopulated channel structures, and methods of fabricating gate-all-around integrated circuit structures having depopulated channel structures using a bottom-up approach, are described. For example, integrated circuit structure includes a first vertical arrangement of nanowires and a second vertical arrangement of nanowires above a substrate. The first vertical arrangement of nanowires has a greater number of nanowires than the second vertical arrangement of nanowires. The first vertical arrangement of nanowires has an uppermost nanowire co-planar with an uppermost nanowire of the second vertical arrangement of nanowires. The first vertical arrangement of nanowires has a bottommost nanowire below a bottommost nanowire of the second vertical arrangement of nanowires. A first gate stack is over the first vertical arrangement of nanowires. A second gate stack is over the second vertical arrangement of nanowires.

A method includes providing a substrate having an epitaxial stack of layers including a plurality of semiconductor channel layers interposed by a plurality of dummy layers. The substrate includes a first device region and a second device region. An etch process is performed to remove a first portion of the epitaxial stack of layers from the second device region to form a trench in the second device region. The removed first portion of the epitaxial stack of layers includes at least one semiconductor channel layer of the plurality of semiconductor channel layers. An epitaxial layer is formed within the trench in the second device region and over the second portion of the epitaxial stack of layers. A top surface of the epitaxial layer in the second device region is substantially level with a top surface of the epitaxial stack of layers in the first device region.

Nanowire devices and fin devices are formed in a first region and a second region of a substrate. To form the devices, alternating layers of a first material and a second material are formed, inner spacers are formed adjacent to the layers of the first material, and then the layers of the first material are removed to form nanowires without removing the layers of the first material within the second region. Gate structures of gate dielectrics and gate electrodes are formed within the first region and the second region in order to form the nanowire devices in the first region and the fin devices in the second region.

Methods of manufacturing electronic devices are described. Embodiments of the present disclosure advantageously provide methods of manufacturing electronic devices, e.g., complementary field-effect transistors (CFETs) that have improved negative bias temperature (NBTI) and boosted performance of the PMOS transistor due to the presence of a silicon germanium (SiGe) channel in the PMOS transistor. Specifically, a plurality of nanosheet release layers is removed from the N-channel metal-oxide-semiconductor (NMOS) transistor to form a plurality of openings adjacent the corresponding plurality of nanosheet channel layers, and a plurality of oxide layers are deposited in each of the plurality of openings.

The present disclosure relates to a manufacturing method for a power semiconductor device (1, 40), comprising: forming multiple growth templates on a carrier substrate (2), comprising at least a first plurality of hollow growth templates (18) and a second plurality of hollow growth templates (28); selectively growing a first sequence of differently doped wide bandgap semiconductor materials in each one of the first hollow growth templates (18), thereby forming a corresponding plurality of first semiconductor structures (5) of a first type, in particular n+/p/n/n+ structures; and selectively growing a second sequence of differently doped wide bandgap semiconductor materials in each one of the second hollow growth templates (28), thereby forming a corresponding plurality of second semiconductor structures (6) of a second type, in particular n+/n/p/n+ structures. The disclosure further relates to a power semiconductor device (1, 40) comprising a carrier substrate (2), at least one dielectric layer (4, 27, 31), a plurality of first semiconductor structures (5) of a first type, and a plurality of second semiconductor structures (6) of a second type formed within the at least one dielectric layer (4, 27, 31).

A microelectronic device is disclosed, comprising a base structure comprising: active regions individually comprising semiconductor material; and isolation regions horizontally alternating with the active regions and individually comprising insulative material; a transistor structure comprising: a channel within one of the active regions of the base structure and horizontally interposed between two of the isolation regions; a gate dielectric structure including a high-k material above the channel; a gate electrode stack on the gate dielectric structure and comprising: diffusion prevention material on the gate dielectric structure and partially horizontally overlapping the channel, an opening in the diffusion prevention material horizontally centered about a horizontal centerline of the channel and having a smaller horizontal dimension than the channel; a conductive material comprising lanthanum on the diffusion prevention material and substantially filling the opening.

A semiconductor device includes a substrate; and a plurality of sub-word line drivers, each of the sub-word line drivers including a plurality of transistors, wherein at least one of the plurality of transistors has a buried gate structure positioned in the substrate.

A monolithic 3D complementary field-effect transistor (FET) (CFET) circuit includes a first CFET structure and a second CFET structure in a logic circuit within a device layer. A first interconnect layer disposed on the device layer provides first and second input contacts and an output contact of a logic circuit. Each CFET structure includes an upper FET having a first type (e.g., P-type or N-type) on a lower FET having a second type (e.g., N-type or P-type). The FETs in the monolithic 3D CFET circuit may be interconnected to form a two-input NOR circuit or a two-input NAND circuit. Vertical access interconnects (vias) may be formed within the device layer to interconnect the FETs externally and to each other. The FETs may be formed as bulk-type transistors or SOI transistors.

A semiconductor device includes channel members vertically stacked, a gate dielectric layer wrapping around each of the channel members, a first work function (WF) layer disposed over the gate dielectric layer and wrapping around each of the channel members, a first WF isolation layer disposed over the first WF layer, a second WF layer disposed over the first WF isolation layer, a second WF isolation layer disposed over the second WF layer, and a metal fill layer disposed over the second WF isolation layer. The first WF layer has a uniform thickness. The second WF isolation layer is a nitride-containing layer.