Abstract: A semiconductor structure. The semiconductor structure includes: a substrate having a metal wiring level within the substrate; a capping layer on and above a top surface of the substrate; an insulative layer on and above a top surface of the capping layer; an inductor comprising a first portion in and above the insulative layer and a second portion only above the insulative layer; and a wire bond pad within the insulative layer, wherein the first portion the inductor has a height in a first direction greater than a height of the wire bond pad in the first direction, wherein the first direction is perpendicularly directed from the top surface of substrate toward the insulative layer.

Abstract: A method of a semiconductor device. A substrate is provided. At least one metal wiring level is within the substrate. An insulative layer is deposited on a surface of the substrate. An inductor is formed within the insulative layer using a patterned plate process. A wire bond pad is formed within the insulative layer, wherein at least a portion of the wire bond pad is substantially co-planar with the inductor.

Abstract: A method of forming a semiconductor substrate. A substrate is provided. At least one metal wiring level is within the substrate. A first insulative layer is deposited on a surface of the substrate. A portion of a wire bond pad is formed within the first insulative layer. A second insulative layer is deposited on the first insulative layer. An inductor is within the second insulative layer using a patterned plate process. A remaining portion of the wire bond pad is formed within the second insulative layer, wherein at least a portion of the wire bond pad is substantially co-planar with the inductor.

Abstract: A semiconductor structure and a method for forming the same. The structure includes (i) a dielectric layer, (ii) a bottom capacitor plate and an electrically conductive line on the dielectric layer, (iii) a top capacitor plate on top of the bottom capacitor plate, (iv) a gap region, and (v) a solder ball on the dielectric layer. The dielectric layer includes a top surface that defines a reference direction perpendicular to the top surface. The top capacitor plate overlaps the bottom capacitor plate in the reference direction. The gap region is sandwiched between the bottom capacitor plate and the top capacitor plate. The gap region does not include any liquid or solid material. The solder ball is electrically connected to the electrically conductive line. The top capacitor plate is disposed between the dielectric layer and the solder ball.

Abstract: A semiconductor structure. The structure includes (i) a semiconductor substrate which includes a channel region, (ii) first and second source/drain regions on the semiconductor substrate, (iii) a gate dielectric region, and (iv) a gate electrode region, (v) a plurality of interconnect layers on the gate electrode region, and (vi) first and second spaces. The gate dielectric region is disposed between and in direct physical contact with the channel region and the gate electrode region. The gate electrode region is disposed between and in direct physical contact with the gate dielectric region and the interconnect layers. The first and second spaces are in direct physical contact with the gate electrode region. The first space is disposed between the first source/drain region and the gate electrode region. The second space is disposed between the second source/drain region and the gate electrode region.

Abstract: A semiconductor structure fabrication method. First, a semiconductor structure is provided including (a) a semiconductor block having a first semiconductor material doped with a first doping polarity and having a first lattice orientation, and (b) a semiconductor region on the semiconductor block, wherein the semiconductor region is physically isolated from the semiconductor block by a dielectric region, and wherein the semiconductor region includes a second semiconductor material (i) doped with a second doping polarity opposite to the first doping polarity and (ii) having a second lattice orientation different from the first lattice orientation. Next, first and second gate stacks are formed on the semiconductor block and the semiconductor region, respectively. Then, (i) first and second S/D regions are simultaneously formed in the semiconductor block on opposing sides of the first gate stack and (ii) first and second discharge prevention semiconductor regions in the semiconductor block.

Abstract: A semiconductor structure and method of fabricating the structure. The method includes removing the backside silicon from two silicon-on-insulator wafers having devices fabricated therein and bonding them back to back utilizing the buried oxide layers. Contacts are then formed in the upper wafer to devices in the lower wafer and wiring levels are formed on the upper wafer. The lower wafer may include wiring levels. The lower wafer may include landing pads for the contacts. Contacts to the silicon layer of the lower wafer may be silicided.

Abstract: A semiconductor structure and method of fabricating the structure. The method includes removing the backside silicon from two silicon-on-insulator wafers having devices fabricated therein and bonding them back to back utilizing the buried oxide layers. Contacts are then formed in the upper wafer to devices in the lower wafer and wiring levels are formed on the upper wafer. The lower wafer may include wiring levels. The lower wafer may include landing pads for the contacts. Contacts to the silicon layer of the lower wafer may be silicided.

Abstract: A semiconductor structure and a method for forming the same. The structure includes (i) a semiconductor substrate which includes a channel region, (ii) first and second source/drain regions on the semiconductor substrate, (iii) a gate dielectric region, and (iv) a gate electrode region, (v) a plurality of interconnect layers on the gate electrode region, and (vi) first and second spaces. The gate dielectric region is disposed between and in direct physical contact with the channel region and the gate electrode region. The gate electrode region is disposed between and in direct physical contact with the gate dielectric region and the interconnect layers. The first and second spaces are in direct physical contact with the gate electrode region. The first space is disposed between the first source/drain region and the gate electrode region. The second space is disposed between the second source/drain region and the gate electrode region.

Abstract: A structure and a method. The method includes: forming a dielectric layer on a substrate; forming electrically conductive first and second wires in the dielectric layer, top surfaces of the first and second wires coplanar with a top surface of the dielectric layer; and either (i) forming an electrically conductive third wire on the top surface of the dielectric layer, and over the top surfaces of the first and second wires, the third wire electrically contacting each of the first and second wires, the third wire not detectable by optical microscopy or (ii) forming an electrically conductive third wire between the top surface of the dielectric layer and the substrate, the third wire electrically contacting each of the first and second wires, the third wire not detectable by optical microscopy.

Abstract: A structure and a method for forming the same. The structure includes a first dielectric layer, an electrically conductive bond pad on the first dielectric layer, and a second dielectric layer on top of the first dielectric layer and the electrically conductive bond pad. The electrically conductive bond pad is sandwiched between the first and second dielectric layers. The second dielectric layer includes N separate final via openings such that a top surface of the electrically conductive bond pad is exposed to a surrounding ambient through each final via opening of the N separate final via openings. N is a positive integer greater than 1.

Abstract: A semiconductor structure and a method for forming the same. The semiconductor structure includes (i) a semiconductor substrate which includes a channel region, (ii) first and second source/drain regions on the semiconductor substrate, (iii) a final gate dielectric region, (iv) a final gate electrode region, and (v) a first gate dielectric corner region. The final gate dielectric region (i) includes a first dielectric material, and (ii) is disposed between and in direct physical contact with the channel region and the final gate electrode region. The first gate dielectric corner region (i) includes a second dielectric material that is different from the first dielectric material, (ii) is disposed between and in direct physical contact with the first source/drain region and the final gate dielectric region, (iii) is not in direct physical contact with the final gate electrode region, and (iv) overlaps the final gate electrode region in a reference direction.

Abstract: A semiconductor structure and a method for forming the same. The structure includes (i) a dielectric layer, (ii) a bottom capacitor plate and an electrically conductive line on the dielectric layer, (iii) a top capacitor plate on top of the bottom capacitor plate, (iv) a gap region, and (v) a solder ball on the dielectric layer. The dielectric layer includes a top surface that defines a reference direction perpendicular to the top surface. The top capacitor plate overlaps the bottom capacitor plate in the reference direction. The gap region is sandwiched between the bottom capacitor plate and the top capacitor plate. The gap region does not include any liquid or solid material. The solder ball is electrically connected to the electrically conductive line. The top capacitor plate is disposed between the dielectric layer and the solder ball.

Abstract: A semiconductor structure. The semiconductor structure includes: a substrate having a metal wiring level within the substrate; a capping layer on and above the substrate; an insulative layer on and above the capping layer; a first layer of photo-imagable material on and above the insulative layer; a layer of oxide on and above the first layer of photo-imagable material; a second layer of photo-imagable material on and above the layer of oxide; an inductor; and a wire bond pad. A first portion of the inductor is in the second layer of photo-imagable material, the layer of oxide, the first layer of photo-imagable material, the insulative layer, and the capping layer. A second portion of the inductor is in only the second layer of photo-imagable material. The wire bond pad in only the first layer of photo-imagable material, the insulative layer, and the capping layer.

Abstract: A semiconductor structure and a method for forming the same. The structure includes (i) a semiconductor substrate which includes a channel region, (ii) first and second source/drain regions on the semiconductor substrate, (iii) a gate dielectric region, and (iv) a gate electrode region, (v) a plurality of interconnect layers on the gate electrode region, and (vi) first and second spaces. The gate dielectric region is disposed between and in direct physical contact with the channel region and the gate electrode region. The gate electrode region is disposed between and in direct physical contact with the gate dielectric region and the interconnect layers. The first and second spaces are in direct physical contact with the gate electrode region. The first space is disposed between the first source/drain region and the gate electrode region. The second space is disposed between the second source/drain region and the gate electrode region.

Abstract: A structure and method of forming the structure. At least one copper wire is formed within a first dielectric layer of a substrate. The top surface of each copper wire and of the first dielectric layer are essentially coplanar. A recess is formed in the first dielectric layer from the top surface of each copper wire to a recess depth less than a thickness of each copper wire within the first dielectric layer such that the recess surrounds a perimeter surface of each copper wire. A capping layer, which is a copper diffusion barrier, is formed in the recess and on the top surface of each copper wire and on the first dielectric layer. A second dielectric layer is formed on the capping layer. The recess depth has a magnitude sufficient to prevent a lateral fail of the capping layer during packaging and/or operation of the substrate.

Abstract: A structure and method for forming the same. The semiconductor structure includes a first semiconductor chip and N solder bumps in direct physical contact with the first semiconductor chip, wherein N is a positive integer. The semiconductor structure also includes a first solder wall on a perimeter of the first semiconductor chip such that the first solder wall forms a closed loop surrounding the N solder bumps.

Abstract: An electrical structure and method of forming. The method comprises providing a substrate structure. A first layer comprising a first photosensitive material having a first polarity is formed over and in contact with the substrate structure. A second layer comprising photosensitive material having a second polarity is formed over and in contact with the first layer. The first polarity comprises an opposite polarity as the second polarity. Portions of the first and second layers are simultaneously exposed to a photo exposure light source. The portions of the first and second layers are developed such that structures are formed.

Abstract: An electrical structure and method of forming. The electrical structure includes a semiconductor substrate comprising a deep trench, an oxide liner layer is formed over an exterior surface of the deep trench, and a field effect transistor (FET) formed within the semiconductor substrate. The first FET includes a source structure, a drain structure, and a gate structure. The gate structure includes a gate contact connected to a polysilicon fill structure. The polysilicon fill structure is formed over the oxide liner layer and within the deep trench. The polysilicon fill structure is configured to flow current laterally across the polysilicon fill structure such that the current will flow parallel to a top surface of the semiconductor substrate.

Abstract: A double-sided integrated circuit chips, methods of fabricating the double-sided integrated circuit chips and design structures for double-sided integrated circuit chips. The method includes removing the backside silicon from two silicon-on-insulator wafers having devices fabricated therein and bonding them back to back utilizing the buried oxide layers. Contacts are then formed in the upper wafer to devices in the lower wafer and wiring levels are formed on the upper wafer. The lower wafer may include wiring levels. The lower wafer may include landing pads for the contacts. Contacts to the silicon layer of the lower wafer may be silicided.