Abstract: A chip includes a first circuit, a second circuit, a first interconnect, and a least one protection circuit. The first circuit has a first node, a first operational voltage node, and a first reference voltage node. The second circuit has a second node, a second operational voltage node, and a second reference voltage node. The first interconnect is configured to electrically connect the first node and the second node to form a 2.5D or a 3D integrated circuit. The at least one protection circuit is located at one or various locations of the chip.

Abstract: The present disclosure provides a three dimensional integrated circuit having a plurality of dies. Each die includes a trigger line common to the other dies, the trigger line controlling the power of a power clamp in each respective die, a dedicated electrostatic discharge (ESD) line for each respective die, and an ESD detection circuit connected to the dedicated ESD line and to a first power line common to the other dies. When an input signal is received by the ESD detection circuit of one of the plural dies, the ESD detection circuit generates an output signal to the common trigger line to supply power to the power clamp in each of the plural dies to clamp ESD voltage or current to the common first power line or a second power line.

Abstract: Fast turn on silicon controlled rectifiers for ESD protection. A semiconductor device includes a semiconductor substrate of a first conductivity type; a first well of a second conductivity type; a second well of the second conductivity type; a first diffused region of the first conductivity type and coupled to a first terminal; a first diffused region of the second conductivity type; a second diffused region of the first conductivity type; a second diffused region of the second conductivity type in the second well; wherein the first diffused region of the first conductivity type and the first diffused region of the second conductivity type form a first diode, and the second diffused region of the first conductivity type and the second diffused region of the second conductivity type form a second diode, and the first and second diodes are series coupled between the first terminal and the second terminal.

Abstract: A semiconductor device and method for fabricating a semiconductor device is disclosed. An exemplary semiconductor device includes a substrate including a metal oxide device. The metal oxide device includes first and second doped regions disposed within the substrate and interfacing in a channel region. The first and second doped regions are doped with a first type dopant. The first doped region has a different concentration of dopant than the second doped region. The metal oxide device further includes a gate structure traversing the channel region and the interface of the first and second doped regions and separating source and drain regions. The source region is formed within the first doped region and the drain region is formed within the second doped region. The source and drain regions are doped with a second type dopant. The second type dopant is opposite of the first type dopant.

Abstract: A P-type Metal-Oxide-Semiconductor Field Effect Transistor (PMOSFET) includes a gate, a first source/drain region connected to the gate, and a second source/drain region on an opposite side of the gate than the first source/drain region. A first Schottky diode includes a first anode connected to the first source/drain region, and a first cathode connected to a body of the PMOSFET. A second Schottky diode includes a second anode connected to the second source/drain region, and a second cathode connected to the body of the PMOSFET.

Abstract: A method includes removing a first portion of a gate layer of a structure. The structure includes a drain region, a source region, and a gate stack, and the gate stack includes a gate dielectric layer, a gate conductive layer directly on the gate dielectric layer, and the gate layer directly on the gate conductive layer. A drain contact region is formed on the drain region, and a source contact region is formed on the source region. A conductive region is formed directly on the gate conductive layer and adjacent to a second portion of the gate layer. A gate contact terminal is formed in contact with the conductive region.

Abstract: Methods and apparatus are disclosed for manufacturing metal-insulator-metal (MIM) capacitors. The MIM capacitors may comprise an electrode, which may be a top or bottom electrode, which has a bottle neck. The MIM capacitors may comprise an electrode, which may be a top or bottom electrode, in contact with a sidewall of a via. The sidewall contact or the bottle neck of the electrode may burn out to form a high impedance path when the leakage current exceeds a specification, while the sidewall contact or the bottle neck of the electrode has no impact for normal MIM operations. The MIM capacitors may be used as decoupling capacitors.

Abstract: Fast turn on silicon controlled rectifiers for ESD protection. A semiconductor device includes a semiconductor substrate of a first conductivity type; a first well of a second conductivity type; a second well of the second conductivity type; a first diffused region of the first conductivity type and coupled to a first terminal; a first diffused region of the second conductivity type; a second diffused region of the first conductivity type; a second diffused region of the second conductivity type in the second well; wherein the first diffused region of the first conductivity type and the first diffused region of the second conductivity type form a first diode, and the second diffused region of the first conductivity type and the second diffused region of the second conductivity type form a second diode, and the first and second diodes are series coupled between the first terminal and the second terminal.

Abstract: Methods and apparatus for increased holding voltage SCRs. A semiconductor device includes a semiconductor substrate of a first conductivity type; a first well of the first conductivity type; a second well of a second conductivity type adjacent to the first well, an intersection of the first well and the second well forming a p-n junction; a first diffused region of the first conductivity type formed at the first well and coupled to a ground terminal; a first diffused region of the second conductivity type formed at the first well; a second diffused region of the first conductivity type formed at the second well and coupled to a pad terminal; a second diffused region of the second conductivity type formed in the second well; and a Schottky junction formed adjacent to the first diffused region of the second conductivity type coupled to a ground terminal. Methods for forming devices are disclosed.

Abstract: A semiconductor device and method for fabricating a semiconductor device is disclosed. An exemplary semiconductor device includes a substrate including a metal oxide device. The metal oxide device includes first and second doped regions disposed within the substrate and interfacing in a channel region. The first and second doped regions are doped with a first type dopant. The first doped region has a different concentration of dopant than the second doped region. The metal oxide device further includes a gate structure traversing the channel region and the interface of the first and second doped regions and separating source and drain regions. The source region is formed within the first doped region and the drain region is formed within the second doped region. The source and drain regions are doped with a second type dopant. The second type dopant is opposite of the first type dopant.

Abstract: A semiconductor device and method for fabricating a semiconductor device is disclosed. An exemplary semiconductor device includes a substrate including a metal oxide device. The metal oxide device includes first and second doped regions disposed within the substrate and interfacing in a channel region. The first and second doped regions are doped with a first type dopant. The first doped region has a different concentration of dopant than the second doped region. The metal oxide device further includes a gate structure traversing the channel region and the interface of the first and second doped regions and separating source and drain regions. The source region is formed within the first doped region and the drain region is formed within the second doped region. The source and drain regions are doped with a second type dopant. The second type dopant is opposite of the first type dopant.

Abstract: A device includes a drain, a source, and a gate stack. The gate stack has a gate dielectric layer, a gate conductive layer immediately on top of the gate dielectric layer, and first gate and a second gate layer that are immediately on top of the gate conductive layer. The first gate layer has a first resistance higher than a second resistance of the second gate layer. The second gate layer is conductive, is electrically coupled with the gate conductive layer, and has a contact terminal configured to serve as a gate contact terminal for the device. Fabrication methods of the gate stack are also disclosed.

Abstract: A representative electrostatic discharge (ESD) protection circuit includes a silicon-controlled rectifier (SCR) that is electrically coupled to the output of a power amplifier; an ESD detection circuit that triggers the SCR responsive to detect an electrostatic discharge on an ESD bus; and an ESD clamp circuit that is coupled to the first voltage line.

Abstract: A chip includes a first circuit, a second circuit, a first interconnect, and a least one protection circuit. The first circuit has a first node, a first operational voltage node, and a first reference voltage node. The second circuit has a second node, a second operational voltage node, and a second reference voltage node. The first interconnect is configured to electrically connect the first node and the second node to form a 2.5D or a 3D integrated circuit. The at least one protection circuit is located at one or various locations of the chip.

Abstract: Circuit and method for RC power clamp triggered dual SCR ESD protection. In an integrated circuit, a protected pad is coupled to an upper SCR circuit and a lower SCR circuit; and both are coupled to the RC power clamp circuit, which is coupled between the positive voltage supply and the ground voltage supply. A structure for ESD protection is disclosed having a first well of a first conductivity type adjacent to a second well of a second conductivity type, the boundary forming a p-n junction, and a pad contact diffusion region in each well electrically coupled to a pad terminal; additional diffusions are provided proximate to and electrically isolated from the pad contact diffusion regions, the diffusion regions and first and second wells form two SCR devices. These SCR devices are triggered, during an ESD event, by current injected into the respective wells by an RC power clamp circuit.

Abstract: An ESD protection circuit includes a pad of an IC, circuitry coupled to the pad for buffering data, an RC power clamp on the IC, and first and second silicon controlled rectifier (SCR) circuits. The RC power clamp is coupled between a positive power supply terminal and a ground terminal. The first SCR circuit is coupled between the pad and the positive power supply terminal. The first SCR circuit has a first trigger input coupled to the RC power clamp circuit. The second SCR circuit is coupled between the pad and the ground terminal. The second SCR circuit has a second trigger input coupled to the RC power clamp circuit. At least one of the SCR circuits includes a gated diode configured to selectively provide a short or relatively conductive electrical path between the pad and one of the positive power supply terminal and the ground terminal.

Abstract: An electrostatic discharge (ESD) protection circuit structure includes a dual directional silicon controlled rectifier (SCR) formed in a substrate. The SCR includes first and second P-wells laterally interposed by an N-well. A deep N-well is disposed underneath the P-wells and the N-well. First and second N-type regions are disposed in the first and second P-wells, respectively, and are coupled to a pair of pads. First and second P-type regions are disposed in the first and second P-wells, respectively, are coupled to the pads, and are disposed closer to the N-well than the first and second N-type regions, respectively.

Abstract: A device includes a drain, a source, and a gate stack. The gate stack has a gate dielectric layer, a gate conductive layer immediately on top of the gate dielectric layer, and first gate and a second gate layer that are immediately on top of the gate conductive layer. The first gate layer has a first resistance higher than a second resistance of the second gate layer. The second gate layer is conductive, is electrically coupled with the gate conductive layer, and has a contact terminal configured to serve as a gate contact terminal for the device. Fabrication methods of the gate stack are also disclosed.

Abstract: A representative electrostatic discharge (ESD) protection circuit includes a silicon-controlled rectifier (SCR) that is electrically coupled to the output of a power amplifier; an ESD detection circuit that triggers the SCR responsive to detect an electrostatic discharge on an ESD bus; and an ESD clamp circuit that is coupled to the first voltage line.

Abstract: Circuit and method for RC power clamp triggered dual SCR ESD protection. In an integrated circuit, a protected pad is coupled to an upper SCR circuit and a lower SCR circuit; and both are coupled to the RC power clamp circuit, which is coupled between the positive voltage supply and the ground voltage supply. A structure for ESD protection is disclosed having a first well of a first conductivity type adjacent to a second well of a second conductivity type, the boundary forming a p-n junction, and a pad contact diffusion region in each well electrically coupled to a pad terminal; additional diffusions are provided proximate to and electrically isolated from the pad contact diffusion regions, the diffusion regions and first and second wells form two SCR devices. These SCR devices are triggered, during an ESD event, by current injected into the respective wells by an RC power clamp circuit.