A semiconductor device includes: a semiconductor substrate, a gate oxide layer, and a polysilicon field plate. The semiconductor substrate includes a drift region and a well region. An end of the drift region is arranged with a drain region, and an end of the well region is arranged with a source region. The gate oxide layer is arranged on the semiconductor substrate and disposed between the source region and the drain region. The polysilicon field plate is arranged on the gate oxide layer. At least a portion of the polysilicon field plate is projected onto the drift region and includes at least two field-plate regions. While the semiconductor device is operating, in a direction from an end of the drift region near the well region approaching the drain region, an equivalent electrical thickness of an insulating layer between the polysilicon field plate and the drift region gradually increases.

The present application discloses a semiconductor device with a programmable unit and a method for fabricating the semiconductor device. The semiconductor device including a substrate, a bottom conductive layer positioned in the substrate, a first gate structure including a first gate dielectric layer positioned on the bottom conductive layer, a first work function layer positioned on the first gate dielectric layer, and a first filler layer positioned on the first work function layer, a second gate structure including a second gate dielectric layer positioned on the bottom conductive layer and spaced apart from the first gate dielectric layer, a second work function layer positioned on the second gate dielectric layer, and a second filler layer positioned on the second work function layer, a conductive plug electrically coupled to the bottom conductive layer, and a top conductive layer electrically coupled to the first gate structure and the second gate structure.

The present application discloses a semiconductor device with a programmable unit and a method for fabricating the semiconductor device. The semiconductor device including a substrate, a bottom conductive layer positioned in the substrate, a first gate structure including a first gate dielectric layer positioned on the bottom conductive layer, a first work function layer positioned on the first gate dielectric layer, and a first filler layer positioned on the first work function layer, a second gate structure including a second gate dielectric layer positioned on the bottom conductive layer and spaced apart from the first gate dielectric layer, a second work function layer positioned on the second gate dielectric layer, and a second filler layer positioned on the second work function layer, a conductive plug electrically coupled to the bottom conductive layer, and a top conductive layer electrically coupled to the first gate structure and the second gate structure.

There is provided a technique that includes selectively doping a metal film with a dopant by performing: supplying a dopant-containing gas containing the dopant to a substrate in which the metal film and a film other than the metal film are formed on a film in which the dopant is doped; and removing the dopant-containing gas from above the substrate.

Embodiments disclosed herein generally relate to methods of depositing a plurality of layers. A doped copper seed layer is deposited in a plurality of feature definitions in a device structure. A first copper seed layer is deposited and then the first copper seed layer is doped to form a doped copper seed layer, or a doped copper seed layer is deposited directly. The doped copper seed layer leads to increased flowability, reducing poor step coverage, overhang, and voids in the copper layer.

Embodiments disclosed herein generally relate to methods of depositing a plurality of layers. A doped copper seed layer is deposited in a plurality of feature definitions in a device structure. A first copper seed layer is deposited and then the first copper seed layer is doped to form a doped copper seed layer, or a doped copper seed layer is deposited directly. The doped copper seed layer leads to increased flowability, reducing poor step coverage, overhang, and voids in the copper layer.

A transistor structure is disclosed. The transistor structure includes a dielectric layer that has a thinner portion over a first doped well and a second doped well, and a thicker portion adjacent the thinner portion and over the second doped well. The thicker portion has a height greater than the thinner portion above the doped wells. The transistor includes a first gate structure on the thinner portion and a second gate structure on the thicker portion of the dielectric layer. The transistor may include a third gate structure on the thicker portion.

A transistor structure is disclosed. The transistor structure includes a dielectric layer that has a thinner portion over a first doped well and a second doped well, and a thicker portion adjacent the thinner portion and over the second doped well. The thicker portion has a height greater than the thinner portion above the doped wells. The transistor includes a first gate structure on the thinner portion and a second gate structure on the thicker portion of the dielectric layer. The transistor may include a third gate structure on the thicker portion.

Integrated circuitry interconnect structures comprising a first metal and a graphene cap over a top surface of the first metal. Within the interconnect structure an amount of a second metal, nitrogen, or silicon is greater proximal to an interface of the graphene cap. The presence of the second metal, nitrogen, or silicon may improve adhesion of the graphene to the first metal and/or otherwise improve electromigration resistance of a graphene capped interconnect structure. The second metal, nitrogen, or silicon may be introduced into the first metal during deposition of the first metal, or during a post-deposition treatment of the first metal. The second metal, nitrogen, or silicon may be introduced prior to, or after, capping the first metal with graphene.

Integrated circuitry interconnect structures comprising a first metal and a graphene cap over a top surface of the first metal. Within the interconnect structure an amount of a second metal, nitrogen, or silicon is greater proximal to an interface of the graphene cap. The presence of the second metal, nitrogen, or silicon may improve adhesion of the graphene to the first metal and/or otherwise improve electromigration resistance of a graphene capped interconnect structure. The second metal, nitrogen, or silicon may be introduced into the first metal during deposition of the first metal, or during a post-deposition treatment of the first metal. The second metal, nitrogen, or silicon may be introduced prior to, or after, capping the first metal with graphene.