Abstract: A package includes a substrate having a conductive layer, and the conductive layer comprises an exposed portion. A die stack is disposed over the substrate and electrically connected to the conductive layer. A high thermal conductivity material is disposed over the substrate and contacting the exposed portion of the conductive layer. The package further includes a contour ring over and contacting the high thermal conductivity material.

Abstract: A method for performing a programming operation to a first memory bit and a second memory bit of a device is described. The method includes applying a pulse train voltage to a metal gate of the device and grounding a substrate of the device. By floating/grounding a drain of the device and/or by floating/grounding the source of the device, the first memory and the second memory bit are programmed. The pulse train voltage includes 10 to 1000 pulses. One pulse includes a peak voltage and a base voltage. The peak voltage ranges from 0.5 V to 10 V. A duration of the peak voltage ranges from 1 nanosecond to 1 millisecond. The base voltage is 0 V. A duration of the base voltage ranges from 1 nanosecond to 1 millisecond.

Abstract: The present disclosure provides a method and system for characterizing a pattern loading effect. A method may include performing a reflectivity measurement on a semiconductor wafer and determining an anneal process technique based on the reflectivity measurement. The determining the anneal process technique may include determining a spatial distance for a reflectivity change using a reflectivity map generated using the reflectivity measurement. This spatial distance is compared with the thermal diffusion length associated with each of the plurality of anneal process techniques. In an embodiment, a thermal profile map and/or a device performance map may be provided.

Abstract: The present disclosure provides a device includes a first gate structure segment and a collinear second gate structure segment, as well as a third gate structure segment and a collinear fourth gate structure segment. An interconnection extends from the first gate structure segment to the fourth gate structure segment. The interconnection is disposed above the first gate structure segment and the fourth gate structure segment. The interconnection may be formed on or co-planar with a contact layer of the semiconductor device.

Abstract: Photosensitive materials and method of forming a pattern that include providing a composition of a component of a photosensitive material that is operable to float to a top region of a layer formed from the photosensitive material. In an example, a photosensitive layer includes a first component having a fluorine atom (e.g., alkyl fluoride group). After forming the photosensitive layer, the first component floats to a top surface of the photosensitive layer. Thereafter, the photosensitive layer is patterned.

Abstract: A method and device including a substrate having a fin. A metal gate structure is formed on the fin. The metal gate structure includes a stress metal layer formed on the fin such that the stress metal layer extends to a first height from an STI feature, the first height being greater than the fin height. A conduction metal layer is formed on the stress metal layer.

Abstract: A method is described including forming a first photoresist feature and a second photoresist feature on a semiconductor substrate. A chemical material coating is formed on the semiconductor substrate. The chemical material coating interposes the first and second photoresist features. The semiconductor substrate is then rinsed; the rinsing removes the chemical material coating from the semiconductor substrate. The chemical material may mix with a residue disposed on the substrate between the first and second photoresist features. Removing the chemical material coating from the substrate may also remove the residue.

Abstract: A method of semiconductor device fabrication including providing a substrate having a gate dielectric layer such as a high-k dielectric disposed thereon. A tri-layer element is formed on the gate dielectric layer. The tri-layer element includes a first capping layer, a second capping layer, and a metal gate layer interposing the first and second capping layer. One of an nFET and a pFET gate structure are formed using the tri-layer element, for example, the second capping layer and the metal gate layer may form a work function layer for one of an nFET and a pFET device. The first capping layer may be a sacrificial layer used to pattern the metal gate layer.

Abstract: Methods and materials directed to solubility of photosensitive material in negative tone developer are described. The photosensitive material may include greater than 50% acid labile groups as branches to a polymer chain. In another embodiment, a photosensitive material, after exposure or irradiation, is treated. Exemplary treatments include applying a base to the photosensitive material.

Abstract: Provided is a method and device that includes providing for a plurality of differently configured gate structures on a substrate. For example, a first gate structure associated with a transistor of a first type and including a first dielectric layer and a first metal layer; a second gate structure associated with a transistor of a second type and including a second dielectric layer, a second metal layer, a polysilicon layer, the second dielectric layer and the first metal layer; and a dummy gate structure including the first dielectric layer and the first metal layer.

Abstract: A method of fabricating a semiconductor device includes providing a substrate having a fin disposed thereon. A gate structure is formed on the fin. The gate structure interfaces at least two sides of the fin. A stress film is formed on the substrate including on the fin. The substrate including the stress film is annealed. The annealing provides a tensile strain in a channel region of the fin. For example, a compressive strain in the stress film may be transferred to form a tensile stress in the channel region of the fin.

Abstract: A semiconductor device and method of fabricating thereof is described that includes a substrate having a fin with a top surface and a first and second lateral sidewall. A hard mask layer may be formed on the top surface of the fin (e.g., providing a dual-gate device). A gate dielectric layer and work function metal layer are formed on the first and second lateral sidewalls of the fin. A silicide layer is formed on the work function metal layer on the first and the second lateral sidewalls of the fin. The silicide layer may be a fully-silicided layer and may provide a stress to the channel region of the device disposed in the fin.

Abstract: The present disclosure provides devices and methods which provide for strained epitaxial regions. A method of semiconductor fabrication is provided that includes forming a gate structure over a fin of a semiconductor substrate and forming a recess in the fin adjacent the gate structure. A sidewall of the recess is then altered. Exemplary alterations include having an altered profile, treating the sidewall, and forming a layer on the sidewall. An epitaxial region is then grown in the recess. The epitaxial region interfaces the altered sidewall of the recess and is a strained epitaxial region.

Abstract: A method that includes forming a masking element on a semiconductor substrate and overlying a defined space. A first feature and a second feature are each formed on the semiconductor substrate. The space interposes the first and second features and extends from a first end of the first feature to a first end of the second feature. A third feature is then formed adjacent and substantially parallel the first and second features. The third feature extends at least from the first end of the first feature to the first end of the second feature.

Abstract: The present disclosure provides a method of semiconductor fabrication including forming an inter-layer dielectric (ILD) layer on a semiconductor substrate. The ILD layer has an opening defined by sidewalls of the ILD layer. A spacer element is formed on the sidewalls of the ILD layer. A gate structure is formed in the opening adjacent the spacer element. In an embodiment, the sidewall spacer also for a decrease in the dimensions (e.g., length) of the gate structure formed in the opening.

Abstract: A method of fabricating a semiconductor device includes forming a plurality of line element on a provided substrate. The plurality of line elements includes a first line element having a first region having a first width and a biased region having a second width. The second width different than the first width. Spacer elements are then formed abutting sidewalls of each of the plurality of line elements including the biased region where the spacer elements may be shifted. After forming the spacer elements, the plurality of line elements from the substrate are removed from the substrate. An underlying layer is etched using the spacer elements after removing the plurality of line elements.

Abstract: A described method includes providing a semiconductor substrate. A first gate structure is formed on the semiconductor substrate and a sacrificial gate structure formed adjacent the first gate structure. The sacrificial gate structure may be used to form a metal gate structure using a replacement gate methodology. A dielectric layer is formed overlying the first gate structure and the sacrificial gate structure. The dielectric layer has a first thickness above a top surface of the first gate structure and a second thickness, less than the first thickness, above a top surface of the sacrificial gate structure. (See, e.g., FIGS. 5, 15, 26). Thus, a subsequent planarization process of the dielectric layer may not contact the first gate structure.

Abstract: The present disclosure provides a method including providing a semiconductor substrate and forming a first layer and a second layer on the semiconductor substrate. The first layer is patterned to provide a first element, a second element, and a space interposing the first and second elements. Spacer elements are then formed on the sidewalls on the first and second elements of the first layer. Subsequently, the second layer is etched using the spacer elements and the first and second elements as a masking element.

Abstract: The present disclosure provides methods of semiconductor device fabrication for 3D devices. One method includes provide a substrate having a recess and forming a doping layer on the substrate and in the recess. The substrate is then annealed. The annealing drives dopants of a first type from the doping layer into the substrate. This can form a doped region that may be the source/drain extension of the 3D device. An epitaxial region is then grown in the recess. The epitaxial region can form the source/drain region of the 3D device.

Abstract: The present disclosure provides a bio-field effect transistor (BioFET) and a method of fabricating a BioFET device. The method includes forming a BioFET using one or more process steps compatible with or typical to a complementary metal-oxide-semiconductor (CMOS) process. The BioFET device may include a substrate; a gate structure disposed on a first surface of the substrate and an interface layer formed on the second surface of the substrate. The interface layer may allow for a receptor to be placed on the interface layer to detect the presence of a biomolecule or bio-entity.