Semiconductor devices are provided including a first fin-shaped pattern having first and second sidewalls facing one another and a field insulating film contacting at least a portion of the first fin-shaped pattern. The first fin-shaped pattern includes a lower portion of the first fin-shaped pattern contacting the field insulating film; an upper portion of the first fin-shaped pattern not contacting the field insulating film; a first boundary between the lower portion of the first fin-shaped pattern and the upper portion of the first fin-shaped pattern; and a first fin center line perpendicular to the first boundary and meeting the top of the upper portion of the first fin-shaped pattern. The first sidewall of the upper portion of the first fin-shaped pattern and the second sidewall of the upper portion of the first fin-shaped pattern are asymmetric with respect to the first fin center line.

A semiconductor device having a structure which can prevent a decrease in electrical characteristics due to miniaturization is provided. The semiconductor device includes, over an insulating surface, a stack in which a first oxide semiconductor layer and a second oxide semiconductor layer are sequentially formed, and a third oxide semiconductor layer covering part of a surface of the stack. The third oxide semiconductor layer includes a first layer in contact with the stack and a second layer over the first layer. The first layer includes a microcrystalline layer, and the second layer includes a crystalline layer in which c-axes are aligned in a direction perpendicular to a surface of the first layer.

A method includes oxidizing a semiconductor fin to form an oxide layer on opposite sidewalls of the semiconductor fin. The semiconductor fin is over a top surface of an isolation region. After the oxidizing, a tilt implantation is performed to implant an impurity into the semiconductor fin. The oxide layer is removed after the tilt implantation.

The present disclosure relates to a semiconductor device that controls a strain on a channel region by forming a dielectric material in recesses, adjacent to a channel region, in order to provide control over a volume and shape of a strain inducing material of epitaxial source/drain regions formed within the recesses. In some embodiments, the semiconductor device has epitaxial source/drain regions arranged in recesses within an upper surface of a semiconductor body on opposing sides of a channel region. A gate structure is arranged over the channel region, and a dielectric material is arranged laterally between the epitaxial source/drain regions and the channel region. The dielectric material consumes some volume of the recesses, thereby reducing a volume of strain inducing material in epitaxial source/drain regions formed in the recesses.

A semiconductor device includes an isolation layer defining an active region formed in a semiconductor substrate. A first recessing process is performed on the isolation layer to expose edge portions of the active region. A first rounding process is performed to round the edge portions of the active region. A second recessing process is performed on the isolation layer. A second rounding process is performed to round the edge portions of the active region.

A method for forming FinFETs having a capping layer for reducing punch through leakage includes providing an intermediate semiconductor structure having a semiconductor substrate and a fin disposed on the semiconductor substrate. A capping layer is disposed over the fin, and an isolation fill is disposed over the capping layer. A portion of the isolation fill and the capping layer is removed to expose an upper surface portion of the fin. Tapping layer and a lower portion of the fin define an interface dipole layer barrier, a portion of the capping layer operable to provide an increased negative charge or an increased positive charge adjacent to the fin, to reduce punch-through leakage compared to a fin without the capping layer.

A semiconductor device that operates at high speed. A semiconductor device with favorable switching characteristics. A highly integrated semiconductor device. A miniaturized semiconductor device. The semiconductor device is formed by: forming a semiconductor film including an opening, on an insulating surface; forming a conductive film over the semiconductor film and in the opening, and removing the conductive film over the semiconductor film to form a conductive pillar in the opening; forming an island-shaped mask over the conductive pillar and the semiconductor film; etching the conductive pillar and the semiconductor film using the mask to form a first electrode and a first semiconductor; forming a gate insulating film on a top surface and a side surface of the first semiconductor; and forming a gate electrode that is in contact with a top surface of the gate insulating film and faces the top surface and the side surface of the first semiconductor.

A fin-type field effect transistor includes a semiconductor body formed on a substrate, the semiconductor body having a top surface and a pair of laterally opposite sidewalls, and a gate electrode formed above the sidewalls and the top surface of the semiconductor body. The semiconductor body further includes a source region formed on an end portion of the semiconductor body, a drain region formed on another end portion of the semiconductor body, and a channel region formed between the source region and the drain region and surrounded by the gate electrode, wherein a doping concentration of the channel region decreases with increasing distance from the top surface and the sidewalls.

One illustrative method disclosed herein includes, among other things, forming a sacrificial fin structure above a semiconductor substrate, forming a layer of insulating material around the sacrificial fin structure, removing the sacrificial fin structure so as to define a replacement fin cavity in the layer of insulating material that exposes an upper surface of the substrate, forming a replacement fin in the replacement fin cavity on the exposed upper surface of the substrate, recessing the layer of insulating material, and forming a gate structure around at least a portion of the replacement fin exposed above the recessed layer of insulating material.

A method includes forming an opening in a dielectric to reveal a protruding semiconductor fin, forming a gate dielectric on sidewalls and a top surface of the protruding semiconductor fin, and forming a conductive diffusion barrier layer over the gate dielectric. The conductive diffusion barrier layer extends into the opening. The method further includes forming a silicon layer over the conductive diffusion barrier layer and extending into the opening, and performing a dry etch on the silicon layer to remove horizontal portions and vertical portions of the silicon layer. After the dry etch, a conductive layer is formed over the conductive diffusion barrier layer and extending into the opening.