Abstract: Electrostatic discharge (ESD) protection device is provided. An ESD device includes a substrate having an input region; a plurality of fins on the substrate in the input region; a well region, doped with first-type ions, in the plurality of fins and in the substrate; an epitaxial layer on each fin in the input region; a drain region, doped with second-type ions, in a top portion of each fin and in the epitaxial layer; an extended drain region, doped with the second-type ions, in a bottom portion of each fin to connect to the drain region and in a portion of the substrate, in the input region; and a counter-doped region, doped with the first-type ions, in a portion of the substrate between two adjacent fins to insulate adjacent extended drain regions.

Abstract: Fin field-effect transistors are provided. A fin field-effect transistor includes a semiconductor substrate; a plurality of fins on the semiconductor substrate; a gate structure across the fins by covering portions of top and side surfaces of the fins, providing portions of the fins under the gate structure as channel regions; lightly doped regions in the fins at both sides of the gate structure; doped source/drain regions in the fins at both sides of the gate structure; and counter doped regions in fins and between the lightly doped regions and the doped source/drain regions.

Abstract: An eFuse memory cell, an eFuse memory array and a using method thereof, and an eFuse system are provided.

Abstract: A semiconductor structure and method for forming same are provided. The forming method includes: providing a base; forming a discrete core layer on the base; forming a spacer on a sidewall of the core layer; removing the core layer; after the core layer is removed, patterning the base using the spacer as a mask to form a fin, the fin including a device fin and a dummy fin; removing the spacer; performing doping removal on the dummy fin one or more times to remove the dummy fin, the step of the doping removal including: performing ion doping on the entire dummy fin or a part of the dummy fin in thickness for improving an etching selection ratio of the dummy fin to the device fin; and removing the ion-doped dummy fin. Embodiments and implementations of the present disclosure help increase a process window of a fin cut process.

Abstract: Embodiments and implementations of the present disclosure provide assistant pattern configuration methods, masks and forming methods thereof, and related devices.

Abstract: A fin-type semiconductor device includes a semiconductor structure having a plurality of fins formed in a substrate and a plurality of trenches each disposed between two adjacent fins, a spacer in each of the trenches, and an etch stop layer disposed below an upper surface of the spacer.

Abstract: Semiconductor structures and fabrication methods are provided. An exemplary semiconductor structure includes a semiconductor substrate having a plurality of cell regions. Each of the cell regions includes a device region, a protection region surrounding the device region and an isolation region surrounding the device region and the protection region. The semiconductor structure also includes a device structure on the semiconductor substrate in the device region; a protection ring structure on the semiconductor substrate in the protection region; an isolation structure on the semiconductor substrate in the isolation region; a passivation layer on the protection ring structure, the device structure and the isolation structure; and a trench passing through the passivation layer in the isolation region.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a substrate, including a first region and a second region; a first doped region in the first region of the substrate, the first doped region having first doping ions; a second doped region in the second region of the substrate, the second doped region having second dopant ions with a conductivity type opposite to the first doping ions; a first metallide on a surface of the first doped region having the first doping ions; and a second metallide on a surface of the second doped region having the second doping ions, the second metallide and the first metallide being made of different materials.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a base substrate; and a first doped epitaxial layer and a second doped epitaxial layer in the base substrate. Each of the first and second doped epitaxial layers is corresponding to a different gate structure on the base substrate. The semiconductor structure further includes a repaired dielectric layer formed on and surrounding each of the first and second doped epitaxial layer; a metal layer on the repaired dielectric layer; an interlayer dielectric layer over the base substrate and covering tops of gate structures; and a conductive plug on the metal layer and through the interlayer dielectric layer.

Abstract: A fabrication method for a static random-access memory device is provided. The method includes: forming an initial substrate including at least one first region; and removing a portion of the initial substrate in the first region, to forming a substrate, first fins on the substrate, and second initial fins on the substrate. A width of the second initial fins is different from a width of the first fins. A portion of the first fins is used to form pass-gate transistors, and another portion of the first fins and the second initial fins are used to form pull-down transistors.

Abstract: Readout circuit and magnetic memory are provided. The readout circuit includes a first charging capacitor with one end grounded and another end coupled to an output of a data unit; a first pre-charge module for charging the first charging capacitor; a first discharge control module for controlling a magnitude of a data voltage; a second charging capacitor with one end grounded and another end coupled to an output of a reference unit; a second pre-charge module for charging the second charging capacitor; a second discharge control module for controlling a magnitude of a reference voltage; and a sense amplifier for outputting readout signals.

Abstract: A substrate surface defect detection device includes an optical waveguide for receiving first light and directing the received first light to a surface of a to be tested substrate, the optical waveguide having a first surface facing toward the substrate and a second surface facing away from the substrate, a microlens array disposed on the second surface of the optical waveguide, the microlens array including a plurality of microlenses arranged in an array for receiving second light from the surface of the to be tested substrate and converging the received second light to converged light, and an imaging component for receiving the converged light from the at least one microlens array for optical imaging. The substrate surface defect detection device requires significantly less time than conventional substrate surface defect detection devices.

Abstract: A method for fabricating a semiconductor device includes providing a semiconductor structure including a semiconductor substrate, a plurality of semiconductor fin structures, and a trench insulation layer formed on the semiconductor substrate and surrounding each semiconductor fin structure. The semiconductor fin structures include a plurality of first semiconductor fin structures and a plurality of second semiconductor fin structures. The top surface of the trench insulation layer is leveled with the top surface of the semiconductor fin structures.

Abstract: An interconnect structure includes a metal interconnect layer, a dielectric layer on the metal interconnect layer, a fluorocarbon layer on the dielectric layer, a metal interconnect extending through the fluorocarbon layer and the dielectric layer to the metal interconnect layer. The metal interconnect includes a first portion extending through the fluorocarbon layer and into an upper portion of the dielectric layer and a second portion below the first portion and extending through a lower portion of the dielectric layer to the metal interconnect layer.

Abstract: A method for fabricating a semiconductor device includes forming an initial fin structure on a semiconductor substrate; and forming a plurality of first dummy gate structures and a second dummy gate structure across the initial fin structure. The second dummy gate structure is formed between two adjacent first dummy gate structures, and includes a second dummy-gate-structure body. The method also includes forming a trench in the initial fin structure by etching and removing the second dummy-gate-structure body and a portion of the initial fin structure under the second dummy-gate-structure body. The trench divides the initial fin structure to form two fin structures. The method further includes forming a trench isolation layer in the trench and an interlayer dielectric layer on the plurality of first dummy gate structures. The interlayer dielectric layer covers a portion of the semiconductor substrate and the two fin structures adjacent to the trench.

Abstract: Methods for forming a semiconductor structure are provided. In one form, a method includes: providing a base; forming an initial pattern layer on the base; and performing atomic layer etching processing on a sidewall of the initial pattern layer one or more times to form a pattern layer, where the atomic layer etching processing includes: forming an organic layer on the sidewall of the initial pattern layer; and removing the organic layer. Generally, bond energy between an atom on an outermost surface of the sidewall of the initial pattern layer and an atom at an inner layer is less than bond energy between the atom at the inner layer. The organic layer usually includes an element that may react with the sidewall of the initial pattern layer, further reducing the bond energy between the atom on the outermost surface of the sidewall of the initial pattern layer and the atom at the inner layer.

Abstract: Semiconductor device and formation method are provided. The method includes providing a substrate, a first fin and a second fin on the substrate, an isolation structure covering a portion of sidewalls of the first and second fins, a gate structure across the first fin or the second fin, a first doped source/drain region in the first fin, a second doped source/drain region in the second fin, and an interlayer dielectric layer on the isolation structure, the first and second fins, and the gate structure. A first through hole is formed in the interlayer dielectric layer, exposing the first doped source/drain region or the second doped source/drain region. A second through hole is formed in the interlayer dielectric layer on the isolation structure to connect to the first through hole. A first plug is formed in the first through hole and a second plug is formed in the second through hole.

Abstract: A semiconductor device includes a semiconductor substrate, a trench isolator portion in the semiconductor substrate, a dummy gate on the semiconductor substrate, a first doped region between the trench isolator portion and the dummy gate in the semiconductor substrate, and a first connecting member electrically connected the dummy gate with the first doped region. With the dummy gate electrically connected to the first doped region, a transistor including the dummy gate is turned off, thereby preventing the occurrence of current leakage and improving the reliability of a memory device having the semiconductor device.

Abstract: A semiconductor device and a fabrication method are provided. The method includes forming a first fin structure and a second fin structure on a substrate. The first fin structure includes a first sidewall surface, facing to the second fin structure, and a second sidewall surface opposite to the first sidewall surface. The method also includes forming an isolation layer to cover a portion of sidewall surfaces of the first fin structure and the second fin structure. The top surface of the isolation layer is lower than the top surfaces of the first fin structure and the second fin structure. The method further includes forming a first sidewall on the first sidewall surface; forming a first doped layer in the first fin structure; and forming a second doped layer in the second fin structure. The first sidewall covers a portion of a sidewall surface of the first doped layer.

Abstract: Semiconductor devices and fabrication methods are provided. An exemplary semiconductor device includes a semiconductor substrate having a first region. The first region includes a first middle region and a first edge region adjacent to and surrounding the first middle region; and a surface of the first middle region of the semiconductor substrate is higher than a surface of the first edge region of the semiconductor substrate. The semiconductor device also includes a plurality of first fins discretely formed on the first middle region of the semiconductor substrate; and an isolation structure formed on the first middle region of the semiconductor substrate and the first edge region of the semiconductor substrate and covering portions of sidewall surfaces of the first fins.