The present application provides a semiconductor structure manufacturing method and two semiconductor structures. The manufacturing method includes: providing a substrate and a silicon layer, the substrate exposing a top surface of the silicon layer; performing deposition to form an alloy layer on the silicon layer, the deposition being performed in a nitrogen-containing atmosphere, and a concentration of nitrogen atoms in the nitrogen-containing atmosphere increasing with an increase in deposition time; and annealing the alloy layer and the silicon layer. In embodiments of the present application, an increase in the concentration of nitrogen atoms can control a silicification reaction of the alloy layer, thereby preventing a line width effect and reducing the resistance of the semiconductor structure.

A vertical-conduction MOSFET device formed in a body of silicon carbide having a first and a second face and a peripheral zone. A drain region, of a first conductivity type, extends in the body between the two faces. A body region, of a second conductivity type, extends in the body from the first face, and a source region, having the first conductivity type, extends to the inside of the body region from the first face of the body. An insulated gate region extends on the first face of the body and comprises a gate conductive region. An annular connection region, of conductive material, is formed within a surface edge structure extending on the first face of the body, in the peripheral zone. The gate conductive region and the annular connection region are formed by a silicon layer and by a metal silicide layer overlying the silicon layer.

Methods of forming backside vias connected to source/drain regions of long-channel semiconductor devices and short-channel semiconductor devices and semiconductor devices formed by the same are disclosed. In an embodiment, a semiconductor device includes a first transistor structure; a second transistor structure adjacent the first transistor structure; a first interconnect structure on a front-side of the first transistor structure and the second transistor structure; and a second interconnect structure on a backside of the first transistor structure and the second transistor structure, the second interconnect structure including a first dielectric layer on the backside of the first transistor structure; a second dielectric layer on the backside of the second transistor structure; a first contact extending through the first dielectric layer and electrically coupled to a first source/drain region of the first transistor structure; and a second contact extending through the second dielectric layer and electrically coupled to a second source/drain region of the second transistor structure, the second contact having a second length less than a first length of the first contact.

A semiconductor device includes a multi-silicide structure comprising at least two conformal silicide layers. The multi-silicide structure may include a first conformal silicide layer on a source/drain, a second conformal silicide layer on the first conformal silicide layer, and a capping layer over the second conformal silicide layer. The semiconductor device includes a contact structure on the multi-silicide structure. The semiconductor device includes a dielectric material around the contact structure. In some implementations, a controller may determine etch process parameters to be used by an etch tool to perform an iteration of an atomic layer etch (ALE) process on the semiconductor device.

A semiconductor structure for facilitating an integration of power devices on a common substrate includes a first insulating layer formed on the substrate and an active region having a first conductivity type formed on at least a portion of the first insulating layer. A first terminal is formed on an upper surface of the structure and electrically connects with at least one other region having the first conductivity type formed in the active region. A buried well having a second conductivity type is formed in the active region and is coupled with a second terminal formed on the upper surface of the structure. The buried well and the active region form a clamping diode which positions a breakdown avalanche region between the buried well and the first terminal. A breakdown voltage of at least one of the power devices is a function of characteristics of the buried well.

The present disclosure relates to a method for fabricating a semiconductor structure. The method includes providing a substrate with a gate structure, an insulating structure over the gate structure, and a S/D region; depositing a titanium silicide layer over the S/D region with a first chemical vapor deposition (CVD) process. The first CVD process includes a first hydrogen gas flow. The method also includes depositing a titanium nitride layer over the insulating structure with a second CVD process. The second CVD process includes a second hydrogen gas flow. The first and second CVD processes are performed in a single reaction chamber and a flow rate of the first hydrogen gas flow is higher than a flow rate of the second hydrogen gas flow.

A semiconductor structure includes a semiconductor channel of a first conductivity type located between a first and second active regions having a doping of a second conductivity type that is opposite of the first conductivity type, a gate stack structure that overlies the semiconductor channel, and includes a gate dielectric and a gate electrode, a first metal-semiconductor alloy portion embedded in the first active region, and a first composite contact via structure in contact with the first active region and the first metal-semiconductor alloy portion, and contains a first tubular liner spacer including a first annular bottom surface, a first metallic nitride liner contacting an inner sidewall of the first tubular liner spacer and having a bottom surface that is located above a horizontal plane including bottom surface of the first tubular liner spacer, and a first metallic fill material portion embedded in the first metallic nitride liner.

A method is provided for producing a plurality of transistors on a substrate comprising at least two adjacent active areas separated by at least one electrically-isolating area, each transistor of the plurality of transistors including a gate having a silicided portion, and first and second spacers on either side of the gate, the first spacers being located on sides of the gate and the second spacers being located on sides of the first spacers. The method includes forming the gates of the transistors, forming the first spacers, forming the second spacers siliciding the gates so as to form the silicided portions of the gates, and removing the second spacers. The removal of the second spacers takes place during the silicidation of the gates and before the silicided portions are fully formed.

An embodiment relates to a n-type planar gate DMOSFET comprising a Silicon Carbide (SiC) substrate. The SiC substrate includes a N+ substrate, a N− drift layer, a P-well region and a first N+ source region within each P-well region. A second N+ source region is formed between the P-well region and a source metal via a silicide layer. During third quadrant operation of the DMOSFET, the second N+ source region starts depleting when a source terminal is positively biased with respect to a drain terminal. The second N+ source region impacts turn-on voltage of body diode regions of the DMOSFET by establishing short-circuitry between the P-well region and the source metal when the second N+ source region is completely depleted.

An embodiment relates to a n-type planar gate DMOSFET comprising a Silicon Carbide (SiC) substrate. The SiC substrate includes a N+ substrate, a N− drift layer, a P-well region and a first N+ source region within each P-well region. A second N+ source region is formed between the P-well region and a source metal via a silicide layer. During third quadrant operation of the DMOSFET, the second N+ source region starts depleting when a source terminal is positively biased with respect to a drain terminal. The second N+ source region impacts turn-on voltage of body diode regions of the DMOSFET by establishing short-circuitry between the P-well region and the source metal when the second N+ source region is completely depleted.