A method for forming a semiconductor device structure is provided. The method includes forming an epitaxial structure over a semiconductor substrate. The method also includes generating and applying plasma on an entire exposed surface of the epitaxial structure to form a modified region in the epitaxial structure. The plasma is directly applied on the source/drain structure without being filtered out, and the plasma includes ions with different charges. The method further includes forming a metal layer on the modified region and heating the metal layer and the modified region to form a metal-semiconductor compound region.

A memory structure including a substrate, a memory cell, and a transistor is provided. The substrate includes a memory cell region and a peripheral circuit region. The memory cell is located in the memory cell region. The transistor is located in the peripheral circuit region. The transistor includes a gate, a first doped region, a second doped region, a first nickel silicide layer, and a second nickel silicide layer. The gate is located on the substrate and is insulated from the substrate. The first doped region and the second doped region are located in the substrate on two sides of the gate. The first nickel silicide layer is located on an entire top surface of the first doped region, and the second nickel silicide layer is located on an entire top surface of the second doped region.

A method of manufacturing a semiconductor device includes providing a semiconductor substrate having opposing first and second main surfaces and first and second dopants. A covalent atomic radius of a material of the substrate is i) larger than a covalent atomic radius of the first dopant and smaller than that of the second dopant, or ii) smaller than the covalent atomic radius of the first dopant and larger than that of the second dopant. A vertical extension of the first dopant into the substrate from the first main surface ends at a bottom of a substrate portion at a first vertical distance to the first main surface. The method further includes forming a semiconductor layer on the first main surface, forming semiconductor device elements in the semiconductor layer, and reducing a thickness of the substrate by removing material from the second main surface at least up to the substrate portion.

A method of splitting a semiconductor wafer includes: forming one or more epitaxial layers on the semiconductor wafer; forming a plurality of device structures in the one or more epitaxial layers; forming a metallization layer and/or a passivation layer over the plurality of device structures; attaching a carrier to the semiconductor wafer with the one or more epitaxial layers, the carrier protecting the plurality of device structures and mechanically stabilizing the semiconductor wafer; forming a separation region within the semiconductor wafer, the separation region having at least one altered physical property which increases thermo-mechanical stress within the separation region relative to the remainder of the semiconductor wafer; and applying an external force to the semiconductor wafer such that at least one crack propagates along the separation region and the semiconductor wafer splits into two separate pieces, one of the pieces retaining the plurality of device structures.

An apparatus may include a main chamber, a substrate holder, disposed in a lower region of the main chamber, and defining a substrate region, as well as an RF applicator, disposed adjacent an upper region of the main chamber, to generate an upper plasma within the upper region. The apparatus may further include a central chamber structure, disposed in a central portion of the main chamber, where the central chamber structure is disposed to shield at least a portion of the substrate position from the upper plasma. The apparatus may include a bias source, electrically coupled between the central chamber structure and the substrate holder, to generate a glow discharge plasma in the central portion of the main chamber, wherein the substrate region faces the glow discharge region.

A method of processing and passivating an implanted workpiece is disclosed, wherein, after passivation, the fugitive emissions of the workpiece are reduced to acceptably low levels. This may be especially beneficial when phosphorus, arsine, germane or another toxic species is the dopant being implanted into the workpiece. In one embodiment, a sputtering process is performed after the implantation process. This sputtering process is used to sputter the dopant at the surface of the workpiece, effectively lowering the dopant concentration at the top surface of the workpiece. In another embodiment, a chemical etching process is performed to lower the dopant concentration at the top surface. After this sputtering or chemical etching process, a traditional passivation process can be performed.

A semiconductor device includes a first source/drain region on an upper surface of a semiconductor substrate that extends along a first direction to define a length and a second direction opposite the first direction to define a width. A channel region extends vertically in a direction perpendicular to the first and second directions from a first end contacting the first source/drain region to an opposing second end contacting a second source/drain region. A gate surrounds a channel portion of the channel region, and a first doped source/drain extension region is located between the first source/drain region and the channel portion. The first doped source/drain extension region has a thickness extending along the vertical direction. A second doped source/drain extension region is located between the second source/drain region and the channel portion. The second doped source/drain extension region has a thickness extending along the vertical direction that matches the first thickness.

A semiconductor device includes a substrate, at least one source drain feature, a gate structure, and at least one gate spacer. The source/drain feature is present at least partially in the substrate. The gate structure is present on the substrate. The gate spacer is present on at least one sidewall of the gate structure. At least a bottom portion of the gate spacer has a plurality of dopants therein.

A method for forming an overlap transistor includes forming a gate structure over a III-V material, wet cleaning the III-V material on side regions adjacent to the gate structure and plasma cleaning the III-V material on the side regions adjacent to the gate structure. The III-V material is plasma doped on the side regions adjacent to the gate structure to form plasma doped extension regions that partially extend below the gate structure.

A thin film transistor and a manufacturing method thereof, an array substrate and a display device are provided. The thin film transistor is formed on a substrate and includes: an active layer on the substrate, the active layer including a source region, a drain region, and a channel region between the source region and the drain region; a first gate electrode on a side of the active layer away from the substrate; and a second gate electrode on a side of the first gate electrode away from the substrate, wherein a thickness of the first gate electrode is smaller than a thickness of the second gate electrode.