An electrical isolation device including a support with thickness E including two faces facing one another, referred to, respectively, as the two faces having a length L, a width l; on each face of the support, a plurality of voltage dividers is positioned extending over the length, each voltage divider including electrical components that are connected in series and arranged according to a first and a second stage, each first stage including a row of even components and a row of odd components, the rows being parallel, and adjacent, and the second stage corresponding to a linear arrangement of components.

Semiconductor devices and methods of forming the same are provided. The methods may implanting dopants into a substrate to form a preliminary impurity region and heating the substrate to convert the preliminary impurity region into an impurity region. Heating the substrate may be performed at an ambient temperature of from about 800° C. to about 950° C. for from about 20 min to about 50 min. The method may also include forming first and second trenches in the impurity region to define an active fin and forming a first isolation layer and a second isolation layer in the first and second trenches, respectively. The first and second isolation layers may expose opposing sides of the active fin. The method may further include forming a gate insulation layer extending on the opposing sides and an upper surface of the active fin and forming a gate electrode traversing the active fin.

A carrier wafer, a structure, and a method are disclosed. The carrier wafer includes a wafer layer having a first surface and a second surface opposite the first surface, a first antireflective coating (ARC) layer positioned on the first surface of the wafer layer, a second ARC layer positioned on a surface of the first ARC layer opposite the wafer layer, and a thin release layer positioned on a surface of the second ARC layer opposite the first ARC layer. The structure includes the carrier wafer and a semiconductor device substrate positioned over the thin release layer of the carrier wafer. The method includes obtaining a wafer layer, forming an ARC layer on a surface of the wafer layer, forming a second ARC layer on a surface of the first ARC layer opposite the wafer layer, and forming a thin release layer on the second ARC layer.

Embodiments are directed to a method of forming a dielectric region of a fin-type field effect transistor (FinFET). The method includes forming at least one fin, and forming a dielectric region adjacent a lower portion of the at least one fin, wherein the dielectric region includes a top surface. The method further includes forming a blocking layer on the top surface of the dielectric region, wherein the blocking layer is configured to prevent at least one subsequent FinFET fabrication operation from impacting the top surface of the dielectric region.

A method used in forming integrated circuitry comprises forming a stack comprising vertically-alternating first tiers and second tiers. A stair-step structure is formed into the stack. A first liquid is applied onto the stair-step structure. The first liquid comprises insulative physical objects that individually have at least one of a maximum submicron dimension or a minimum submicron dimension. The first liquid is removed to leave the insulative physical objects touching one another and to have void-spaces among the touching insulative physical objects. A second liquid that is different from the first liquid is applied into the void-spaces. The second liquid is changed into a solid insulative material in the void-spaces. Other embodiments, including structure, are disclosed.

A semiconductor structure is provided. The semiconductor structure includes a staircase structure including a first stair layer and a second stair layer on the first stair layer. The first stair layer includes a first conductive film. The semiconductor structure includes a first landing pad disposed on the first conductive film. The first landing pad has a first pad sidewall facing toward the second stair layer, and a second pad sidewall opposite to the first pad sidewall. The second pad sidewall includes an inclined sidewall portion.

A method used in forming integrated circuitry comprises forming a stack comprising vertically-alternating first tiers and second tiers. A stair-step structure is formed into the stack. A first liquid is applied onto the stair-step structure. The first liquid comprises insulative physical objects that individually have at least one of a maximum submicron dimension or a minimum submicron dimension. The first liquid is removed to leave the insulative physical objects touching one another and to have void-spaces among the touching insulative physical objects. A second liquid that is different from the first liquid is applied into the void-spaces. The second liquid is changed into a solid insulative material in the void-spaces. Other embodiments, including structure, are disclosed.

A semiconductor component includes a semiconductor substrate, a first oxide layer, an oxide, a first polysilicon layer, a first metal layer, a first mask on the first metal layer, and a bitline. The semiconductor substrate includes an array region, a periphery region and a boundary open region. The boundary open region isolates the array region from the periphery region. The first oxide layer is deposited on the array region. The first polysilicon layer is deposited on the periphery region. The first metal layer is deposited on the first polysilicon layer. A trench is formed on the array region and passes through the first oxide layer. The bitline includes a second polysilicon layer filling in the trench and a second metal layer on the second polysilicon layer. A second mask is formed on the second metal layer. The second polysilicon layer is flush with the first oxide layer.

The present application provides a method of fabricating a conductive feature. The method of fabricating the conductive feature includes steps of depositing an insulative layer on a substrate, forming a trench in the insulative layer, performing a cyclic process comprising a sequence of a deposition step and a removal step to deposit a conductive material in the trench until the deposition step has been performed is equal to a first preset number of times and a number of the times the removal step has been performed is equal to a second preset number of times, and filling the trench with the conductive material after the cyclic process.

A method used in forming integrated circuitry comprises forming a stack comprising vertically-alternating first tiers and second tiers. A stair-step structure is formed into the stack. A first liquid is applied onto the stair-step structure. The first liquid comprises insulative physical objects that individually have at least one of a maximum submicron dimension or a minimum submicron dimension. The first liquid is removed to leave the insulative physical objects touching one another and to have void-spaces among the touching insulative physical objects. A second liquid that is different from the first liquid is applied into the void-spaces. The second liquid is changed into a solid insulative material in the void-spaces. Other embodiments, including structure, are disclosed.