Abstract: The various described embodiments provide a transistor with a negative capacitance, and a method of creating the same. The transistor includes a gate structure having a ferroelectric layer. The ferroelectric layer is formed by forming a thick ferroelectric film, annealing the ferroelectric film to have a desired phase, and thinning the ferroelectric film to a desired thickness of the ferroelectric layer. This process ensures that the ferroelectric layer will have ferroelectric properties regardless of its thickness.

Abstract: A semiconductor test device for measuring a contact resistance includes: first fin structures, upper portions of the first fin structures protruding from an isolation insulating layer; epitaxial layers formed on the upper portions of the first fin structures, respectively; first conductive layers formed on the epitaxial layers, respectively; a first contact layer disposed on the first conductive layers at a first point; a second contact layer disposed on the first conductive layers at a second point apart from the first point; a first pad coupled to the first contact layer via a first wiring; and a second pad coupled to the second contact layer via a second wiring. The semiconductor test device is configured to measure the contact resistance between the first contact layer and the first fin structures by applying a current between the first pad and the second pad.

Abstract: The various described embodiments provide a transistor with a negative capacitance, and a method of creating the same. The transistor includes a gate structure having a ferroelectric layer. The ferroelectric layer is formed by forming a thick ferroelectric film, annealing the ferroelectric film to have a desired phase, and thinning the ferroelectric film to a desired thickness of the ferroelectric layer. This process ensures that the ferroelectric layer will have ferroelectric properties regardless of its thickness.

Abstract: A semiconductor test device for measuring a contact resistance includes: first fin structures, upper portions of the first fin structures protruding from an isolation insulating layer; epitaxial layers formed on the upper portions of the first fin structures, respectively; first conductive layers formed on the epitaxial layers, respectively; a first contact layer disposed on the first conductive layers at a first point; a second contact layer disposed on the first conductive layers at a second point apart from the first point; a first pad coupled to the first contact layer via a first wiring; and a second pad coupled to the second contact layer via a second wiring. The semiconductor test device is configured to measure the contact resistance between the first contact layer and the first fin structures by applying a current between the first pad and the second pad.

Abstract: The various described embodiments provide a transistor with a negative capacitance, and a method of creating the same. The transistor includes a gate structure having a ferroelectric layer. The ferroelectric layer is formed by forming a thick ferroelectric film, annealing the ferroelectric film to have a desired phase, and thinning the ferroelectric film to a desired thickness of the ferroelectric layer. This process ensures that the ferroelectric layer will have ferroelectric properties regardless of its thickness.

Abstract: A method for manufacturing a semiconductor device includes forming a fin structure over a substrate and forming a first gate structure over a first portion of the fin structure. A first nitride layer is formed over a second portion of the fin structure. The first nitride layer is exposed to ultraviolet radiation. Source/drain regions are formed at the second portion of the fin structure.

Abstract: A semiconductor device includes a plurality of fins on a substrate. A fin liner is formed on an end surface of each of the plurality of fins. An insulating layer is formed on the plurality of fins. A plurality of polycrystalline silicon layers are formed on the insulating layer. A source/drain epitaxial layer is formed in a source/drain space in each of the plurality of fins. One of the polycrystalline silicon layers is formed on a region spaced-apart from the fins.

Abstract: A semiconductor device includes a first fin and a second fin in a first direction and aligned in the first direction over a substrate, an isolation insulating layer disposed around lower portions of the first and second fins, a first gate electrode extending in a second direction crossing the first direction and a spacer dummy gate layer, and a source/drain epitaxial layer in a source/drain space in the first fin. The source/drain epitaxial layer is adjacent to the first gate electrode and the spacer dummy gate layer with gate sidewall spacers disposed therebetween, and the spacer dummy gate layer includes one selected from the group consisting of silicon nitride, silicon oxynitride, silicon carbon nitride, and silicon carbon oxynitride.

Abstract: A semiconductor test device for measuring a contact resistance includes: first fin structures, upper portions of the first fin structures protruding from an isolation insulating layer; epitaxial layers formed on the upper portions of the first fin structures, respectively; first conductive layers formed on the epitaxial layers, respectively; a first contact layer disposed on the first conductive layers at a first point; a second contact layer disposed on the first conductive layers at a second point apart from the first point; a first pad coupled to the first contact layer via a first wiring; and a second pad coupled to the second contact layer via a second wiring. The semiconductor test device is configured to measure the contact resistance between the first contact layer and the first fin structures by applying a current between the first pad and the second pad.

Abstract: A method for manufacturing a semiconductor device comprises forming a first fin and a second fin on a first active region and a second active region of a semiconductor substrate, respectively. A first dummy gate is formed over the first fin and a second dummy gate is formed over the second fin, wherein the first dummy gate has a first gate width along a lengthwise direction of the first fin, the second dummy gate has a second gate width along the lengthwise direction of the second fin, the first gate width is different from the second gate width. At least one of the first dummy gate and the second dummy gate is removed. A ferroelectric layer is then formed over the semiconductor substrate, in which the first dummy gate and/or the second dummy gate is removed. At least one metal gate electrode is formed on the ferroelectric layer.

Abstract: A method for manufacturing a semiconductor device includes forming a fin structure over a substrate and forming a first gate structure over a first portion of the fin structure. A first nitride layer is formed over a second portion of the fin structure. The first nitride layer is exposed to ultraviolet radiation. Source/drain regions are formed at the second portion of the fin structure.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a gate structure disposed over a substrate between a source region and a drain region. A first inter-level dielectric (ILD) layer is disposed over the substrate and the gate structure and a second ILD layer is disposed over the first ILD layer. A field plate etch stop structure is between the first ILD layer and the second ILD layer. A field plate extends from an uppermost surface of the second ILD layer to the field plate etch stop structure. A plurality of conductive contacts extend from the uppermost surface of the second ILD layer to the source region and the drain region.

Abstract: A method of forming a semiconductor device is disclosed. The method includes providing a device having a substrate and a hard mask layer over the substrate; forming a mandrel over the hard mask layer; depositing a material layer on sidewalls of the mandrel; implanting a dopant into the material layer; performing an etching process on the hard mask layer using the mandrel and the material layer as an etching mask, thereby forming a patterned hard mask layer, wherein the etching process concurrently produces a dielectric layer deposited on sidewalls of the patterned hard mask layer, the dielectric layer containing the dopant; and forming a fin by etching the substrate using the patterned hard mask layer and the dielectric layer collectively as an etching mask.

Abstract: A method for testing a semiconductor structure includes forming a dielectric layer over a test region of a substrate. A cap layer is formed over the dielectric layer. The dielectric layer and the cap layer are annealed. The annealed cap layer is removed. A ferroelectricity of the annealed dielectric layer is in-line tested.

Abstract: A method for manufacturing a semiconductor device comprises forming a first fin and a second fin on a first active region and a second active region of a semiconductor substrate, respectively. A first dummy gate is formed over the first fin and a second dummy gate is formed over the second fin, wherein the first dummy gate has a first gate width along a lengthwise direction of the first fin, the second dummy gate has a second gate width along the lengthwise direction of the second fin, the first gate width is different from the second gate width. At least one of the first dummy gate and the second dummy gate is removed. A ferroelectric layer is then formed over the semiconductor substrate, in which the first dummy gate and/or the second dummy gate is removed. At least one metal gate electrode is formed on the ferroelectric layer.

Abstract: A method of forming a semiconductor device is disclosed. The method includes providing a device having a substrate and a hard mask layer over the substrate; forming a mandrel over the hard mask layer; depositing a material layer on sidewalls of the mandrel; implanting a dopant into the material layer; performing an etching process on the hard mask layer using the mandrel and the material layer as an etching mask, thereby forming a patterned hard mask layer, wherein the etching process concurrently produces a dielectric layer deposited on sidewalls of the patterned hard mask layer, the dielectric layer containing the dopant; and forming a fin by etching the substrate using the patterned hard mask layer and the dielectric layer collectively as an etching mask.

Abstract: A semiconductor test device for measuring a contact resistance includes: first fin structures, upper portions of the first fin structures protruding from an isolation insulating layer; epitaxial layers formed on the upper portions of the first fin structures, respectively; first conductive layers formed on the epitaxial layers, respectively; a first contact layer disposed on the first conductive layers at a first point; a second contact layer disposed on the first conductive layers at a second point apart from the first point; a first pad coupled to the first contact layer via a first wiring; and a second pad coupled to the second contact layer via a second wiring. The semiconductor test device is configured to measure the contact resistance between the first contact layer and the first fin structures by applying a current between the first pad and the second pad.

Abstract: A method of fabricating a semiconductor device includes forming a plurality of isolation features on a semiconductor substrate, thereby defining a first set of semiconductor features, performing an etching process on the first set of semiconductor features such that larger semiconductor features are etched deeper than smaller semiconductor features, after the etching process, forming anti-punch-through features on surfaces of the exposed features of the first set of semiconductor features, forming a semiconductor layer over the anti-punch-through features, and forming transistors on the semiconductor layer of each of the features of the first set of semiconductor features.

Abstract: A method includes providing a plurality of semiconductor fins parallel to each other, and includes two edge fins and a center fin between the two edge fins. A middle portion of each of the two edge fins is etched, and the center fin is not etched. A gate dielectric is formed on a top surface and sidewalls of the center fin. A gate electrode is formed over the gate dielectric. The end portions of the two edge fins and end portions of the center fin are recessed. An epitaxy is performed to form an epitaxy region, wherein an epitaxy material grown from spaces left by the end portions of the two edge fins are merged with an epitaxy material grown from a space left by the end portions of the center fin to form the epitaxy region. A source/drain region is formed in the epitaxy region.

Abstract: Methods of forming semiconductor devices and structures thereof are disclosed. In some embodiments, a semiconductor device includes a substrate that includes fins. Gates are disposed over the fins, the gates being substantially perpendicular to the fins. A source/drain region is disposed on each of fins between two of the gates. A contact is coupled to the source/drain region between the two of the gates. The source/drain region comprises a first width, and the contact comprises a second width. The second width is substantially the same as the first width.