Abstract: Transistor structures may include a metal oxide contact buffer between a portion of a channel material and source or drain contact metallization. The contact buffer may improve control of transistor channel length by limiting reaction between contact metallization and the channel material. The channel material may be of a first composition and the contact buffer may be of a second composition.

Abstract: According to various embodiments, a quick connector assembly includes a tube-shaped outer case having a hollow portion therein and an airtight holding member is provided inside the hollow portion and coupled to an outer surface of a coupling case so that the outer case and the coupling case inserted into the hollow portion maintain airtightness each other. A fixing member is detachably fitting-coupled to the outside of the outer case and configured to elastically press and fix the outer surface of the coupling case inserted into the hollow portion.

Abstract: Described is a transistor which includes: a source region; a drain region; and a gate region between the source and drain regions, wherein the gate region comprises: high-K dielectric material between spacers such that the high-K dielectric material is recessed; and metal electrode on the recessed high-K dielectric material. The gate recessed gate dielectric allows for using thick gate dielectric even with much advanced process technology nodes (e.g., 7 nm and below).

Abstract: A gate stack structure is disclosed for inhibiting charge leakage in III-V transistor devices. The techniques are particularly well-suited for use in enhancement-mode MOSHEMTs but can also be used in other transistor designs susceptible to charge spillover and unintended channel formation in the gate stack. In an example embodiment, the techniques are realized in a transistor having a III-N gate stack over a gallium nitride (GaN) channel layer. The gate stack is configured with a relatively thick barrier structure and wide bandgap III-N materials to prevent or otherwise reduce channel charge spillover resulting from tunneling or thermionic processes at high gate voltages. The barrier structure is configured to manage lattice mismatch conditions, so as to provide a robust high-performance transistor design. In some cases, the gate stack is used in conjunction with an access region polarization layer to induce two-dimensional electron gas (2DEG) in the channel layer.

Abstract: Techniques are disclosed for forming group III material-nitride (III-N) microelectromechanical systems (MEMS) structures on a group IV substrate, such as a silicon, silicon germanium, or germanium substrate. In some cases, the techniques include forming a III-N layer on the substrate and optionally on shallow trench isolation (STI) material, and then releasing the III-N layer by etching to form a free portion of the III-N layer suspended over the substrate. The techniques may include, for example, using a wet etch process that selectively etches the substrate and/or STI material, but does not etch the III-N material (or etches the III-N material at a substantially slower rate). Piezoresistive elements can be formed on the III-N layer to, for example, detect vibrations or deflection in the free/suspended portion of the III-N layer. Accordingly, MEMS sensors can be formed using the techniques, such as accelerometers, gyroscopes, and pressure sensors, for example.

Abstract: Techniques are disclosed for transistor gate trench engineering to decrease capacitance and resistance. Sidewall spacers, sometimes referred to as gate spacers, or more generally, spacers, may be formed on either side of a transistor gate to help lower the gate-source/drain capacitance. Such spacers can define a gate trench after dummy gate materials are removed from between the spacers to form the gate trench region during a replacement gate process, for example. In some cases, to reduce resistance inside the gate trench region, techniques can be performed to form a multilayer gate or gate electrode, where the multilayer gate includes a first metal and a second metal above the first metal, where the second metal includes lower electrical resistivity properties than the first metal. In some cases, to reduce capacitance inside a transistor gate trench, techniques can be performed to form low-k dielectric material on the gate trench sidewalls.

Abstract: Integrated circuit transistor structures are disclosed that reduce n-type dopant diffusion, such as phosphorous or arsenic, from the source region and the drain region of a germanium n-MOS device into adjacent shallow trench isolation (STI) regions during fabrication. The n-MOS transistor device may include at least 75% germanium by atomic percentage. In an example embodiment, the STI is doped with an n-type impurity, in regions of the STI adjacent to the source and/or drain regions, to provide dopant diffusion reduction. In some embodiments, the STI region is doped with an n-type impurity including Phosphorous in a concentration between 1 and 10% by atomic percentage. In some embodiments, the thickness of the doped STI region may range between 10 and 100 nanometers.

Abstract: Nanowire transistors including embedded dielectric spacers to separate a gate electrode from source and drain regions of the transistor. Embedded spacers are disposed within interior sidewalls of a passage through which the gate electrode wraps around a semiconductor filament. The presence of these embedded spacers may dramatically reduce fringe capacitance, particularly as the number of wires/ribbons/filaments in the transistor increases and the number of interior gate electrode passages increases. In some advantageous embodiments, embedded dielectric spacers are fabricated by encapsulating external surfaces prior to those surfaces becoming embedded within the transistor.

Abstract: A gate stack structure is disclosed for inhibiting charge leakage in III-V transistor devices. The techniques are particularly well-suited for use in enhancement-mode MOSHEMTs, but can also be used in other transistor designs susceptible to charge spillover and unintended channel formation in the gate stack. In an example embodiment, the techniques are realized in a transistor having a III-N gate stack over a gallium nitride (GaN) channel layer. The gate stack is configured with a relatively thick barrier structure and wide bandgap III-N materials to prevent or otherwise reduce channel charge spillover resulting from tunneling or thermionic processes at high gate voltages. The barrier structure is configured to manage lattice mismatch conditions, so as to provide a robust high performance transistor design. In some cases, the gate stack is used in conjunction with an access region polarization layer to induce two-dimensional electron gas (2DEG) in the channel layer.

Abstract: Techniques are disclosed for producing integrated circuit structures that include one or more geometrically manipulated polarization layers. The disclosed structures can be formed, for instance, using spacer erosion methods in which more than one type of spacer material is deposited on a polarization layer, and the spacer materials and underlying regions of the polarization layer may then be selectively etched in sequence to provide a desired profile shape to the polarization layer. Geometrically manipulated polarization layers as disclosed herein may be formed to be thinner in regions closer to the gate than in other regions, in some embodiments. The disclosed structures may eliminate the need for a field plate and may also be configured with polarization layers that are shorter in lateral length than polarization layers of uniform thickness without sacrificing performance capability. Additionally, the disclosed techniques may provide increased voltage breakdown without sacrificing Ron.

Abstract: Embodiments herein describe techniques for a semiconductor device including a substrate and a FinFET transistor on the substrate. The FinFET transistor includes a fin structure having a channel area, a source area, and a drain area. The FinFET transistor further includes a gate dielectric area between spacers above the channel area of the fin structure and below a top surface of the spacers; spacers above the fin structure and around the gate dielectric area; and a metal gate conformally covering and in direct contact with sidewalls of the spacers. The gate dielectric area has a curved surface. The metal gate is in direct contact with the curved surface of the gate dielectric area. Other embodiments may be described and/or claimed.

Abstract: A capacitor is disclosed. The capacitor includes a first metal layer, a second metal layer on the first metal layer, a ferroelectric layer on the second metal layer, and a third metal layer on the ferroelectric layer. The second metal layer includes a first non-reactive barrier metal and the third metal layer includes a second non-reactive barrier metal. A fourth metal layer is on the third metal layer.

Abstract: Techniques and mechanisms for providing electrical insulation or other protection of an integrated circuit (IC) device with a spacer structure which comprises an (anti)ferromagnetic material. In an embodiment, a transistor comprises doped source or drain regions and a channel region which are each disposed in a fin structure, wherein a gate electrode and an underlying dielectric layer of the transistor each extend over the channel region. Insulation spacers are disposed on opposite sides of the gate electrode, where at least a portion of one such insulation spacer comprises an (anti)ferroelectric material. Another portion of the insulation spacer comprises a non-(anti)ferroelectric material. In another embodiment, the two portions of the spacer are offset vertically from one another, wherein the (anti)ferroelectric portion forms a bottom of the spacer.

Abstract: A capacitor is disclosed that includes a first metal layer and a seed layer on the first metal layer. The seed layer includes a polar phase crystalline structure. The capacitor also includes a ferroelectric layer on the seed layer and a second metal layer on the ferroelectric layer.

Abstract: Techniques and mechanisms to provide electrical insulation between a gate and a channel region of a non-planar circuit device. In an embodiment, the gate structure, and insulation spacers at opposite respective sides of the gate structure, each extend over a semiconductor fin structure. In a region between the insulation spacers, a first dielectric layer extends conformally over the fin, and a second dielectric layer adjoins and extends conformally over the first dielectric layer. A third dielectric layer, adjoining the second dielectric layer and the insulation spacers, extends under the gate structure. Of the first, second and third dielectric layers, the third dielectric layer is conformal to respective sidewalls of the insulation spacers. In another embodiment, the second dielectric layer is of dielectric constant which is greater than that of the first dielectric layer, and equal to or less than that of the third dielectric layer.

Abstract: Techniques are disclosed for transistor gate trench engineering to decrease capacitance and resistance. Sidewall spacers, sometimes referred to as gate spacers, or more generally, spacers, may be formed on either side of a transistor gate to help lower the gate-source/drain capacitance. Such spacers can define a gate trench after dummy gate materials are removed from between the spacers to form the gate trench region during a replacement gate process, for example. In some cases, to reduce resistance inside the gate trench region, techniques can be performed to form a multilayer gate or gate electrode, where the multilayer gate includes a first metal and a second metal above the first metal, where the second metal includes lower electrical resistivity properties than the first metal. In some cases, to reduce capacitance inside a transistor gate trench, techniques can be performed to form low-k dielectric material on the gate trench sidewalls.

Abstract: Described herein are apparatuses, systems, and methods associated with metal-assisted transistors. A single crystal semiconductor material may be seeded from a metal. The single crystal semiconductor material may form a channel region, a source, region, and/or a drain region of the transistor. The metal may form the source contact or drain contact, and the source region, channel region, and drain region may be stacked vertically on the source contact or drain contact. Alternatively, a metal-assisted semiconductor growth process may be used to form a single crystal semiconductor material on a dielectric material adjacent to the metal. The portion of the semiconductor material on the dielectric material may be used to form the transistor. Other embodiments may be described and claimed.

Abstract: Described is a ferroelectric based capacitor that reduces non-polar monoclinic phase and increases polar orthorhombic phase by epitaxial strain engineering in the oxide thin film and/or electrodes. As such, both memory window and reliability are improved. The capacitor comprises: a first structure comprising metal, wherein the first structure has a first lattice constant; a second structure comprising metal, wherein the second structure has a second lattice constant; and a third structure comprising ferroelectric material (e.g., oxide of Hf or Zr), wherein the third structure is between and adjacent to the first and second structures, wherein the third structure has a third lattice constant, and wherein the first and second lattice constants are smaller than the third lattice constant.

Abstract: A gate stack is described that uses anti-ferroelectric material (e.g., Si, La, N, Al, Zr, Ge, Y doped HfO2) or ferroelectric material (e.g., Si, La, N, Al, Zr, Ge, Y doped HfO2, perovskite ferroelectric such as NH4H2PO4, KH2PO4, LiNb03, LiTaO3, BaTiO3, PbTiO3, Pb (Zr,Ti) O3, (Pb,La)TiO3, and (Pb,La)(Zr,Ti)O3) which reduces write voltage, improves endurance, and increases retention. The gate stack of comprises strained anti-FE or FE material and depolarized anti-FE or FE. The endurance of the FE transistor is further improved by using a higher K (constant) dielectric (e.g., SiO2, Al2O3, HfO2, Ta2O3, La2O3) in the gate stack. High K effects may also be achieved by depolarizing the FE or FE oxide in the transistor gate stack.

Abstract: Described is a ferroelectric-based capacitor that improves reliability of a ferroelectric memory by using low-leakage insulating thin film. In one example, the low-leakage insulating thin film is positioned between a bottom electrode and a ferroelectric oxide. In another example, the low-leakage insulating thin film is positioned between a top electrode and ferroelectric oxide. In yet another example, the low-leakage insulating thin film is positioned in the middle of ferroelectric oxide to reduce the leakage current and improve reliability of the ferroelectric oxide.