Abstract: The present disclosure relates to a semiconductor device including a substrate and first and second spacers on the substrate. The semiconductor device also includes a gate stack between the first and second spacers. The gate stack includes a gate dielectric layer having a first portion formed on the substrate and a second portion formed on the first and second spacers; an internal gate formed on the first and second portions of the gate dielectric layer; a ferroelectric dielectric layer formed on the internal gate and in contact with the gate dielectric layer; and a gate electrode on the ferroelectric dielectric layer.

Abstract: A method for forming a semiconductor device structure is provided. The method includes depositing a gate dielectric layer over a substrate. The substrate has a base portion and a first fin portion over the base portion, and the gate dielectric layer is over the first fin portion. The method includes forming a gate electrode layer over the gate dielectric layer. The gate electrode layer includes fluorine. The method includes annealing the gate electrode layer and the gate dielectric layer so that fluorine from the gate electrode layer diffuses into the gate dielectric layer.

Abstract: A single light projection device providing illumination in two opposing directions includes a lens module and a light source module. The lens module includes a light-incident surface, a first light-emitting surface, and a second light-emitting surface. The light source module includes a light source configured for emitting light toward the light-incident surface. The first light-emitting surface and the second light-emitting surface introduce the light from the light source module outside of the light projection device in two different and opposing directions.

Abstract: A small-scale light projection device emitting structured light for better spot optimization includes a light emitting assembly, an optical path changing unit, and a diffractive optical element. The optical path changing unit of the device is arranged on a light path of the light emitting assembly and applies several changes to the direction of transmission of light within a small space. The diffractive optical element is arranged on a final light path of the optical path changing unit and opposite to the light emitting assembly and applies patterns to the light beam. The optical path changing unit comprises several reflection portions, enabling changes to be made to the light transmission direction.

Abstract: A CMP slurry composition and a method of polishing a metal layer are provided. In some embodiments, the CMP slurry composition includes about 0.1 to 10 parts by weight of a metal oxide, and about 0.1 to 10 parts by weight of a chelator. The chelator includes a thiol compound or a thiolether compound.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a substrate having adjacent first and second fins protruding from the substrate. The semiconductor device structure also includes an insulating structure that includes a first insulating layer formed between and separating from the first fin and the second fin, a second insulating layer embedded in the first insulating layer, a first capping layer formed in the first insulating layer to cover a top surface of the second insulating layer, and a second capping layer in the first capping layer.

Abstract: A heat transfer member reinforcement structure includes a main body. The main body has a first side, a second side and a reinforcement member. The reinforcement member is selectively disposed between the first and second sides or inlaid in a sink formed on the first side. The reinforcement member is connected with the main body to enhance the structural strength of the main body.

Abstract: A heat transfer component reinforcement structure includes a main body. The main body has a pair of first lateral sides and a pair of second lateral sides and a reinforcement member. The reinforcement member is correspondingly externally connected with the main body in at least one manner selected from the group consisting of that the reinforcement members are engaged, latched and connected with the first lateral sides and the second lateral sides of the main body and the reinforcement members are engaged, latched and connected with the junctions between the first and second lateral sides in four corners. The reinforcement member is connected with the main body to enhance the structural strength of the main body.

Abstract: The structure of a semiconductor device with different gate structures configured to provide ultra-low threshold voltages and a method of fabricating the semiconductor device are disclosed. The method includes forming first and second nanostructured channel regions in first and second nanostructured layers, respectively, and forming first and second gate-all-around (GAA) structures surrounding the first and second nanostructured channel regions, respectively. The forming the first and second GAA structures includes selectively forming an Al-based n-type work function metal layer and a Si-based capping layer on the first nanostructured channel regions, depositing a bi-layer of Al-free p-type work function metal layers on the first and second nanostructured channel regions, depositing a fluorine blocking layer on the bi-layer of Al-free p-type work function layers, and depositing a gate metal fill layer on the fluorine blocking layer.

Abstract: Examples of a method of forming an integrated circuit device with an interfacial layer disposed between a channel region and a gate dielectric are provided herein. In some examples, the method includes receiving a workpiece having a substrate and a fin having a channel region disposed on the substrate. An interfacial layer is formed on the channel region of the fin, and a gate dielectric layer is formed on the interfacial layer. A first capping layer is formed on the gate dielectric layer, and a second capping layer is formed on the first capping layer. An annealing process is performed on the workpiece configured to cause a first material to diffuse from the first capping layer into the gate dielectric layer. The forming of the first and second capping layers and the annealing process may be performed in the same chamber of a fabrication tool.

Abstract: A method for forming a semiconductor device structure is provided. The method includes forming a semiconductor layer on a semiconductor substrate, forming an interfacial layer on the semiconductor layer, forming a first gate dielectric layer on the interfacial layer, introducing fluorine on the first gate dielectric layer, annealing the first gate dielectric layer, forming a second gate dielectric layer on the first gate dielectric layer, introducing fluorine on the second gate dielectric layer, annealing the second gate dielectric layer, and forming a gate stack structure on the second gate dielectric layer.

Abstract: The present invention relates to a method and a system for processing building energy information. The method includes the following steps: inputting data of a building information model into building energy simulation software; automatically selecting a building category or manually selecting a building category from a group of building categories provided by the building energy simulation software; in response to the selected building category, inputting a plurality of parameters into a lookup table of the building energy simulation software in accordance with a database of the building energy simulation software; and generating an estimation of a building's energy consumption through a calculation by the building energy simulation software based on the parameters.

Abstract: The present disclosure describes a method that can eliminate or minimize the formation of an oxide on the metal gate layers of ferroelectric field effect transistors. In some embodiments, the method includes providing a substrate with fins thereon; depositing an interfacial layer on the fins; depositing a ferroelectric layer on the interfacial layer; depositing a metal gate layer on the ferroelectric layer; exposing the metal gate layer to a metal-halide gas; and performing a post metallization annealing, where the exposing the metal gate layer to the metal-halide gas and the performing the post metallization annealing occur without a vacuum break.

Abstract: A method includes providing a channel region and growing an oxide layer on the channel region. Growing the oxide layer includes introducing a first source gas providing oxygen and introducing a second source gas providing hydrogen. The second source gas being different than the first source gas. The growing the oxide layer is grown by bonding the oxygen to a semiconductor element of the channel region to form the oxide layer and bonding the hydrogen to the semiconductor element of the channel region to form a semiconductor hydride byproduct. A gate dielectric layer and electrode can be formed over the oxide layer.

Abstract: A semiconductor substrate has an exposed surface having a compositionally uniform metal, and an embedded surface having the metal and an oxide. The exposed surface is polished using a first slurry including a first abrasive and a first amine-based alkaline until the embedded surface is exposed. The embedded surface is polished using a second slurry including a second abrasive and a second amine-based alkaline. The second abrasive is different from the first abrasive. The second amine-based alkaline is different from the first amine-based alkaline. The metal and the oxide each has a first and a second removal rate in the first slurry, respectively, and a third and fourth removal rate in the second slurry, respectively. A ratio of the first removal rate to the second removal rate is greater than 30:1, and a ratio of the third removal rate to the fourth removal rate is about 1:0.5 to about 1:2.

Abstract: The present disclosure describes a semiconductor device that includes a semiconductor device that includes a first transistor having a first gate structure. The first gate structure includes a first gate dielectric layer doped with a first dopant at a first dopant concentration and a first work function layer on the first gate dielectric layer. The first gate structure also includes a first gate electrode on the first work function layer. The semiconductor device also includes a second transistor having a second gate structure, where the second gate structure includes a second gate dielectric layer doped with a second dopant at a second dopant concentration lower than the first dopant concentration. The second gate structure also includes a second work function layer on the second gate dielectric layer and a second gate electrode on the second work function layer.

Abstract: A wafer is polished by performing a chemical reaction to change a property of a first portion of a material layer on the wafer using a first chemical substance. A first rinse is performed to remove the first chemical substance and retard the chemical reaction. A mechanical polishing process is then performed to remove the first portion of the material layer.

Abstract: The present disclosure describes a method that can eliminate or minimize the formation of an oxide on the metal gate layers of ferroelectric field effect transistors. In some embodiments, the method includes providing a substrate with fins thereon; depositing an interfacial layer on the fins; depositing a ferroelectric layer on the interfacial layer; depositing a metal gate layer on the ferroelectric layer; exposing the metal gate layer to a metal-halide gas; and performing a post metallization annealing, where the exposing the metal gate layer to the metal-halide gas and the performing the post metallization annealing occur without a vacuum break.

Abstract: The present disclosure relates to methods for forming a semiconductor device. The method includes forming a substrate and forming first and second spacers on the substrate. The method includes depositing first and second self-assembly (SAM) layers respectively on sidewalls of the first and second spacers and depositing a layer stack on the substrate and between and in contact with the first and second SAM layers. Depositing the layer stack includes depositing a ferroelectric layer and removing the first and second SAM layers. The method further includes depositing a metal compound layer on the ferroelectric layer. Portions of the metal compound layer are deposited between the ferroelectric layer and the first or second spacers. The method also includes depositing a gate electrode on the metal compound layer and between the first and second spacers.

Abstract: The present invention relates to a method for processing building information modeling data including the following steps: inputting a building information model's data that includes two types of multiple objects; identifying the objects to generate results of identification; dividing the objects into a first category and a second category in accordance with the results of identification; removing the objects of the second category; readjusting the first category of objects in accordance with a predetermined rule of a building energy simulation software; and defining attributes of the objects of the first category.