The present disclosure relates to a semiconductor device, a solid-state imaging device, and a method for manufacturing a semiconductor device capable of improving the voltage dependency of a gate capacitance type. Provided is a semiconductor device having a laminated structure in which a compound layer formed on a surface of a semiconductor layer and formed by the semiconductor layer reacting with metal, an insulating film layer in contact with the compound layer, and an electrode layer formed on the insulating film layer are laminated. The present technology can be applied, for example, to an analog-to-digital (AD) conversion part included in the solid-state imaging device.

Disclosed is a method for the fabrication of a correlated electron material (CEM) switching device, the method comprising: forming a layer of a conductive substrate; forming a layer of a correlated electron material on the conductive substrate; forming a layer of a conductive overlay on the layer of correlated electron material; and patterning the layers whereby to form a stack comprising a conductive substrate, a CEM layer and a conductive overlay, wherein the patterning comprises the following steps: forming a hard mask on the layer of the conductive overlay; dry etching the layer of conductive overlay and the layer of correlated electron material whereby to form a partially formed stack; depositing a coating of a protective polymer over at least sidewalls of the partially formed stack; and dry etching the layer of conductive substrate.

Disclosed is a method for the fabrication of a correlated electron material (CEM) switching device, the method comprising: forming a layer of a conductive substrate; forming a layer of a correlated electron material on the conductive substrate; forming a layer of a conductive overlay on the layer of correlated electron material; and patterning the layers whereby to form a stack comprising a conductive substrate, a CEM layer and a conductive overlay, wherein the patterning comprises the following steps: forming a hard mask on the layer of the conductive overlay; dry etching the layer of conductive overlay and the layer of correlated electron material whereby to form a partially formed stack; depositing a coating of a protective polymer over at least sidewalls of the partially formed stack; and dry etching the layer of conductive substrate.

A memory cell of a magnetic random access memory includes multiple layers disposed between a first metal layer and a second metal layer. At least one of the multiple layers include one selected from the group consisting of an iridium layer, a bilayer structure of an iridium layer and an iridium oxide layer, an iridium-titanium nitride layer, a bilayer structure of an iridium layer and a tantalum layer, and a binary alloy layer of iridium and tantalum.

A semiconductor device includes: a substrate having a first region and a second region; a first fin-shaped structure on the first region and a second fin-shaped structure on the second region; a first bump on the first region; a first doped layer on the first fin-shaped structure and the bump; and a gate structure covering the bump.

A semiconductor structure containing at least two metal resistor structures having different resistivities is provided and includes a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first nitridized dielectric surface layer portion having a first nitrogen content, a first metal layer portion and a first nitridized metal surface layer. A second metal resistor structure is located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second nitridized dielectric surface layer portion having a second nitrogen content, a second metal layer portion and a second nitridized metal surface layer. The second nitrogen content of the second nitridized dielectric surface layer portion differs from the first nitrogen content of the first nitridized dielectric surface layer portion.

A semiconductor structure containing at least two metal resistor structures having different resistivities is provided and includes a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first nitridized dielectric surface layer portion having a first nitrogen content, a first metal layer portion and a first nitridized metal surface layer. A second metal resistor structure is located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second nitridized dielectric surface layer portion having a second nitrogen content, a second metal layer portion and a second nitridized metal surface layer. The second nitrogen content of the second nitridized dielectric surface layer portion differs from the first nitrogen content of the first nitridized dielectric surface layer portion.

A semiconductor structure is provided that includes a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first nitridized dielectric surface layer portion having a first nitrogen content, a first metal portion, and a first dielectric capping layer portion. The semiconductor structure of the present application further includes a second metal resistor structure located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second nitridized dielectric surface layer portion having a second nitrogen content that differs from the first nitrogen content, a second metal portion, and a second dielectric capping layer portion.

A semiconductor structure is provided that includes a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first nitridized dielectric surface layer portion having a first nitrogen content, a first metal portion, and a first dielectric capping layer portion. The semiconductor structure of the present application further includes a second metal resistor structure located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second nitridized dielectric surface layer portion having a second nitrogen content that differs from the first nitrogen content, a second metal portion, and a second dielectric capping layer portion.

A semiconductor structure containing at least two metal resistor structures having different amounts of nitrogen on the resistor surface is provided. The resulted resistances (and hence resistivity) of the two metal resistors can be either the same or different. The semiconductor structure may include a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first metal layer portion and a first nitridized metal surface layer having a first nitrogen content. The semiconductor structure further includes a second metal resistor structure located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second metal layer portion and a second nitridized metal surface layer having a second nitrogen content that differs from the first nitrogen content.