The present application relates to a semiconductor device with an intervening layer and a method for fabricating the semiconductor device with the intervening layer. The semiconductor device includes a substrate, a bottom conductive plug positioned on the substrate, an intervening conductive layer positioned on the bottom conductive plug, and a top conductive plug positioned on the intervening conductive layer. A top surface of the intervening conductive layer is non-planar.

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.

A semiconductor structure and a method for forming the same are provided. The method includes: providing a base, a pattern transfer material layer being formed above the base; performing first ion implantation, to dope first ions into the pattern transfer material layer, to form first doped mask layers arranged in a first direction; forming first trenches in the pattern transfer material layer on two sides of the first doped mask layer in a second direction, to expose side walls of the first doped mask layer; forming mask spacers on side walls of the first trenches; performing second ion implantation, to dope second ions into some regions of the pattern transfer material layer that are exposed from the first doped mask layers and the first trenches, to form second doped mask layers; removing the remaining pattern transfer material layer, to form second trenches; and etching the base along the first trenches and the second trenches, to form a target pattern. The present disclosure improves the accuracy of pattern transfer.

A method of fabricating an integrated circuit includes etching trenches in a first surface of a semiconductor layer. A trench dielectric layer is formed over the first surface and over bottoms and sidewalls of the trenches and a doped polysilicon layer is formed over the trench dielectric layer and within the trenches. The doped polysilicon layer is patterned to form a polysilicon bridge that connects to the polysilicon within the filled trenches and a blanket implant of a first dopant is directed to the polysilicon bridge and to the first surface. The blanket implant forms a contact region extending from the first surface into the semiconductor layer.

An integrated circuit includes a dielectric isolation structure formed at a surface of a semiconductor substrate and a polysilicon resistor body formed on the dielectric isolation structure. The polysilicon resistor body includes an N-type dopant having an N-type dopant concentration, nitrogen having a nitrogen concentration, and carbon having a carbon concentration. The sheet resistance of the resistor body is greater than 5 kΩ/square.

In one embodiment, a power semiconductor device may include a semiconductor substrate, wherein the semiconductor substrate comprises an active device region and a junction termination region. The power semiconductor device may also include a polysilicon layer, disposed over the semiconductor substrate. The polysilicon layer may include an active device portion, disposed over the active device region, and defining at least one semiconductor device; and a junction termination portion, disposed over the junction termination region, the junction termination portion defining a ring structure.

A structure includes a semiconductor substrate, and a polycrystalline resistor region over the semiconductor substrate. The polycrystalline resistor region includes a semiconductor material in a polycrystalline morphology. A dopant-including polycrystalline region is between the polycrystalline resistor region and the semiconductor substrate.

Some embodiments include an integrated assembly with a semiconductor channel material having a boundary region where a more-heavily-doped region interfaces with a less-heavily-doped region. The more-heavily-doped region and the less-heavily-doped region have the same majority carriers. The integrated assembly includes a gating structure adjacent the semiconductor channel material and having a gating region and an interconnecting region of a common and continuous material. The gating region has a length extending along a segment of the more-heavily-doped region, a segment of the less-heavily-doped region, and the boundary region. The interconnecting region extends laterally outward from the gating region on a side opposite the semiconductor channel region, and is narrower than the length of the gating region. Some embodiments include methods of forming integrated assemblies.

Some embodiments include an integrated assembly with a semiconductor channel material having a boundary region where a more-heavily-doped region interfaces with a less-heavily-doped region. The more-heavily-doped region and the less-heavily-doped region have the same majority carriers. The integrated assembly includes a gating structure adjacent the semiconductor channel material and having a gating region and an interconnecting region of a common and continuous material. The gating region has a length extending along a segment of the more-heavily-doped region, a segment of the less-heavily-doped region, and the boundary region. The interconnecting region extends laterally outward from the gating region on a side opposite the semiconductor channel region, and is narrower than the length of the gating region. Some embodiments include methods of forming integrated assemblies.

Transistor devices and fabrication methods are provided. A transistor is formed by forming a dummy gate film on a substrate and doping an upper portion of the dummy gate film to form a modified film. The modified film and the remaining dummy gate film are etched to form a modified layer and a dummy gate layer on the substrate. Source/drain regions are formed in the substrate and on both sides of the dummy gate layer. A dielectric film is formed on each of the substrate, the source/drain regions, and the dummy gate layer. The dielectric film and the modified layer are planarized to provide a dielectric layer, and to remove the modified layer and expose the dummy gate layer. The dielectric film has a planarization rate lower than the modified layer, and the formed dielectric layer has a surface higher than the exposed dummy gate layer.