Abstract: A method of forming a semiconductor device includes: forming a metal gate structure over a fin that protrudes above a substrate, the metal gate structure being surrounded by an interlayer dielectric (ILD) layer; recessing the metal gate structure below an upper surface of the ILD layer distal from the substrate; after the recessing, forming a first dielectric layer over the recessed metal gate structure; forming an etch stop layer (ESL) over the first dielectric layer and the ILD layer; forming a second dielectric layer over the ESL; performing a first dry etch process to form an opening that extends through the second dielectric layer, through the ESL, and into the first dielectric layer; after the first dry etch process, performing a wet etch process to clean the opening; and after the wet etch process, performing a second dry etch process to extend the opening through the first dielectric layer.

Abstract: A method of forming a semiconductor device includes: forming a metal gate structure over a fin that protrudes above a substrate, the metal gate structure being surrounded by an interlayer dielectric (ILD) layer; recessing the metal gate structure below an upper surface of the ILD layer distal from the substrate; after the recessing, forming a first dielectric layer over the recessed metal gate structure; forming an etch stop layer (ESL) over the first dielectric layer and the ILD layer; forming a second dielectric layer over the ESL; performing a first dry etch process to form an opening that extends through the second dielectric layer, through the ESL, and into the first dielectric layer; after the first dry etch process, performing a wet etch process to clean the opening; and after the wet etch process, performing a second dry etch process to extend the opening through the first dielectric layer.

Abstract: A semiconductor substrate includes semi-insulating portions beneath openings in a patterned hardmask film formed over a semiconductor substructure to a thickness sufficient to prevent charged particles from passing through the hardmask. The semi-insulating portions include charged particles and may extend deep into the semiconductor substrate and electrically insulate devices formed on opposed sides of the semi-insulating portions. The charged particles may advantageously be protons and further substrate portions covered by the patterned hardmask film are substantially free of the charged particles.

Abstract: A semiconductor capacitor device. A dielectric layer is on a substrate. A stack capacitor structure is disposed in the dielectric layer and comprises first and overlying second MIM capacitors electrically connected in parallel. The first and second MIM capacitors have individual upper and lower electrode plates and different compositions of capacitor dielectric layers.

Abstract: A semiconductor structure includes a substrate; an isolation structure in the substrate, wherein the isolation structure defines a region therein; a first semiconductor region having at least a portion in the region defined by the isolation structure, wherein the first semiconductor region is of a first conductivity type; a second semiconductor region on the first semiconductor region, wherein the second semiconductor region is of a second conductivity type opposite the first conductivity type; and a third semiconductor region of the first conductivity type on the second semiconductor region, wherein the third semiconductor region has at least a portion higher than a top surface of the isolation structure.

Abstract: A semiconductor substrate includes semi-insulating portions beneath openings in a patterned hardmask film formed over a semiconductor substructure to a thickness sufficient to prevent charged particles from passing through the hardmask. The semi-insulating portions include charged particles and may extend deep into the semiconductor substrate and electrically insulate devices formed on opposed sides of the semi-insulating portions. The charged particles may advantageously be protons and further substrate portions covered by the patterned hardmask film are substantially free of the charged particles.

Abstract: A method for forming semi-insulating portions in a semiconductor substrate provides depositing a hardmask film over a semiconductor substructure to a thickness sufficient to prevent charged particles from passing through the hardmask. The hardmask is patterned creating openings through which charged particles pass and enter the substrate during an implantation process. The semi-insulating portions may extend deep into the semiconductor substrate and electrically insulate devices formed on opposed sides of the semi-insulating portions. The charged particles may advantageously be protons and further substrate portions covered by the patterned hardmask film are substantially free of the charged particles.

Abstract: An electrostatic discharge (ESD) structure connected to a bonding pad in an integrated circuit comprising: a P-type substrate with one or more first P+ regions connected to a low voltage supply (GND), a first Nwell formed in the P-type substrate, one or more second P+ regions disposed inside the first Nwell and connected to the bonding pad, at least one first N+ region disposed outside the first Nwell but in the P-type substrate and connected to the GND, at least one second N+ region disposed outside the first Nwell but in the P-type substrate and connected to the bonding pad, wherein the second N+ region is farther away from the first Nwell than the first N+ region, and at least one conductive material disposed above the P-type substrate between the first and second N+ regions and coupled to the GND, wherein the first N+ region, the second N+ region and the conductive material form the source, drain and gate of an NMOS transistor, respectively, and the first P+ region is farther away from the first Nwell tha

Abstract: A high-frequency noise isolation structure and a method for forming the same are provided. The noise isolation structure isolates a first device region and a second device region over a semiconductor substrate. The noise isolation structure preferably includes a sinker region substantially encircling a first device region, a buried layer underlying the first device region and joining the sinker region, a deep guard ring substantially encircling the sinker region, and a deep trench oxide region substantially encircling the sinker region. The isolation structure further includes a wide guard ring between the first and the second device regions. The sinker region and the buried region preferably have a high impurity concentration. Integrated circuits to be noise decoupled are preferably formed in the respective first and second device regions.

Abstract: An electrostatic discharge (ESD) structure connected to a bonding pad in an integrated circuit comprising: a P-type substrate with one or more first P+ regions connected to a low voltage supply (GND), a first Nwell formed in the P-type substrate, one or more second P+ regions disposed inside the first Nwell and connected to the bonding pad, at least one first N+ region disposed outside the first Nwell but in the P-type substrate and connected to the GND, at least one second N+ region disposed outside the first Nwell but in the P-type substrate and connected to the bonding pad, wherein the second N+ region is farther away from the first Nwell than the first N+ region, and at least one conductive material disposed above the P-type substrate between the first and second N+ regions and coupled to the GND, wherein the first N+ region, the second N+ region and the conductive material form the source, drain and gate of an NMOS transistor, respectively, and the first P+ region is farther away from the first Nwell tha

Abstract: A semiconductor structure includes a substrate; an isolation structure in the substrate, wherein the isolation structure defines a region therein; a first semiconductor region having at least a portion in the region defined by the isolation structure, wherein the first semiconductor region is of a first conductivity type; a second semiconductor region on the first semiconductor region, wherein the second semiconductor region is of a second conductivity type opposite the first conductivity type; and a third semiconductor region of the first conductivity type on the second semiconductor region, wherein the third semiconductor region has at least a portion higher than a top surface of the isolation structure.

Abstract: A stacked integrated circuit (IC) MIM capacitor structure and method for forming the same the MIM capacitor structure including a first MIM capacitor structure formed in a first IMD layer comprising an first upper and first lower electrode portions; at least a second MIM capacitor structure arranged in stacked relationship in an overlying IMD layer comprising a second upper electrode and second lower electrode to form an MIM capacitor stack; wherein, the first lower electrode is arranged in common electrical signal communication comprising metal filled vias with the second upper electrode and the first upper electrode is arranged in common electrical signal communication with the second lower electrode.

Abstract: A semiconductor capacitor device. A dielectric layer is on a substrate. A stack capacitor structure is disposed in the dielectric layer and comprises first and overlying second MIM capacitors electrically connected in parallel. The first and second MIM capacitors have individual upper and lower electrode plates and different compositions of capacitor dielectric layers.

Abstract: A semiconductor layout structure for an electrostatic discharge (ESD) protection circuit is disclosed. The semiconductor layout structure includes a first area, in which one or more devices are constructed for functioning as a silicon controlled rectifier, and a second area, in which at least one device is constructed for functioning as a trigger source that provides a triggering current to trigger the silicon controlled rectifier for dissipating ESD charges during an ESD event. The first area and the second area are placed adjacent to one another without having a resistance area physically interposed or electrically connected therebetween, such that the triggering current received by the silicon controlled rectifier is increased during the ESD event.

Abstract: A high-frequency noise isolation structure and a method for forming the same are provided. The noise isolation structure isolates a first device region and a second device region over a semiconductor substrate. The noise isolation structure preferably includes a sinker region substantially encircling a first device region, a buried layer underlying the first device region and joining the sinker region, a deep guard ring substantially encircling the sinker region, and a deep trench oxide region substantially encircling the sinker region. The isolation structure further includes a wide guard ring between the first and the second device regions. The sinker region and the buried region preferably have a high impurity concentration. Integrated circuits to be noise decoupled are preferably formed in the respective first and second device regions.

Abstract: A method for forming semi-insulating portions in a semiconductor substrate provides depositing a hardmask film over a semiconductor substructure to a thickness sufficient to prevent charged particles from passing through the hardmask. The hardmask is patterned creating openings through which charged particles pass and enter the substrate during an implantation process. The semi-insulating portions may extend deep into the semiconductor substrate and electrically insulate devices formed on opposed sides of the semi-insulating portions. The charged particles may advantageously be protons and further substrate portions covered by the patterned hardmask film are substantially free of the charged particles.

Abstract: A semiconductor layout structure for an electrostatic discharge (ESD) protection circuit is disclosed. The semiconductor layout structure includes a first area, in which one or more devices are constructed for functioning as a silicon controlled rectifier, and a second area, in which at least one device is constructed for functioning as a trigger source that provides a triggering current to trigger the silicon controlled rectifier for dissipating ESD charges during an ESD event. The first area and the second area are placed adjacent to one another without having a resistance area physically interposed or electrically connected therebetween, such that the triggering current received by the silicon controlled rectifier is increased during the ESD event.

Abstract: A stacked integrated circuit (IC) MIM capacitor structure and method for forming the same the MIM capacitor structure including a first MIM capacitor structure formed in a first IMD layer comprising an first upper and first lower electrode portions; at least a second MIM capacitor structure arranged in stacked relationship in an overlying IMD layer comprising a second upper electrode and second lower electrode to form an MIM capacitor stack; wherein, the first lower electrode is arranged in common electrical signal communication comprising metal filled vias with the second upper electrode and the first upper electrode is arranged in common electrical signal communication with the second lower electrode.