Abstract: Embodiments of the present disclosure relate to an electrostatic protection structure and an electrostatic protection circuit. The electrostatic protection structure includes: a SCR structure and a trigger structure; the SCR structure includes: a well region of a second conductivity type and a first well of a first conductivity type region, a first-doped region of the first conductivity type, and a first-doped region of the second conductivity type; the trigger structure includes: a first-doped region of the second conductivity type, a second well region of the first conductivity type, a second-doped region of two conductivity types, a third-doped region of the second conductivity type, a fourth-doped region of the second conductivity type, and a first gate electrode.

Abstract: A continuously variable transmission with both equal-difference output and equal-ratio output includes an input mechanism, a hydraulic transmission mechanism, a planetary-gear-set convergence mechanism, an equal-difference output mechanism, an equal-ratio output mechanism, a clutch assembly, and a brake. The clutch assembly connects an output end of the input mechanism to an input end of the hydraulic transmission mechanism and the planetary-gear-set convergence mechanism and connects an output end of the hydraulic transmission mechanism to the planetary-gear-set convergence mechanism. The clutch assembly connects the planetary-gear-set convergence mechanism to the equal-difference output mechanism and the equal-ratio output mechanism. The clutch assembly connects the equal-ratio output mechanism to the equal-difference output mechanism.

Abstract: A continuously variable transmission with both equal-difference output and equal-ratio output includes an input mechanism, a hydraulic transmission mechanism, a planetary-gear-set convergence mechanism, an equal-difference output mechanism, an equal-ratio output mechanism, a clutch assembly, and a brake. The clutch assembly connects an output end of the input mechanism to an input end of the hydraulic transmission mechanism and the planetary-gear-set convergence mechanism and connects an output end of the hydraulic transmission mechanism to the planetary-gear-set convergence mechanism. The clutch assembly connects the planetary-gear-set convergence mechanism to the equal-difference output mechanism and the equal-ratio output mechanism. The clutch assembly connects the equal-ratio output mechanism to the equal-difference output mechanism.

Abstract: A discharge unit is connected to a power pad, a ground pad, and an I/O pad, and can discharge an electrostatic charge when an electrostatic pulse appears on any of the power pad, the ground pad, and the I/O pad. The discharge unit includes a first discharge unit and a second discharge unit, the first discharge unit is connected to the second discharge unit, the power pad, and the I/O pad, and the second discharge unit is connected to the ground pad and the I/O pad. The first discharge unit and/or the second discharge unit can discharge electrostatic charges on different pads, respectively.

Abstract: Embodiments relate to the field of semiconductors, and provide a semiconductor structure and a fabricating method thereof. The semiconductor structure includes: a substrate (100), and a gate oxide layer (110) on a surface of the substrate (100); a gate stack layer (120) positioned on a surface of the gate oxide layer (110); a spacer(130) at least covering a first sidewall of the gate stack layer (120); a contact structure (140) at least positioned on the surface of the substrate (100); and a dielectric layer (150) at least positioned between the contact structure (140) and a second sidewall of the gate stack layer (120). The first sidewall and the second sidewall are arranged opposite to each other, and a thickness of the dielectric layer (150) is less than a thickness of the spacer(130). A breakdown difficulty of a fuse structure may be reduced at least.

Abstract: A discharge unit is connected to a power pad, a ground pad, and an I/O pad, and can discharge an electrostatic charge when an electrostatic pulse appears on any of the power pad, the ground pad, and the I/O pad. The discharge unit includes a first discharge unit and a second discharge unit, the first discharge unit is connected to the second discharge unit, the power pad, and the I/O pad, and the second discharge unit is connected to the ground pad and the I/O pad. The first discharge unit and/or the second discharge unit can discharge electrostatic charges on different pads, respectively.

Abstract: Provided are a semiconductor structure and method for preparing same. The semiconductor structure includes a gate, a source or a drain being provided in the substrate at either side of the gate; a dielectric layer; a contact structure; a first electrical connection part and a second electrical connection part arranged at intervals. The second electrical connection part is in contact with a partial top surface of the contact structure. The first electrical connection part includes a first barrier layer and a first conductive layer which are stacked. In a direction from the source to the drain, a distance between the sidewall of the first barrier layer facing the contact structure and the contact structure is a first distance, and a distance between the sidewall of the first conductive layer facing the contact structure and the contact structure is a second distance, the first distance being greater than the second distance.

Abstract: Provided are semiconductor and a method for manufacturing semiconductor. The semiconductor structure includes: a substrate and a gate located on the substrate, a source is formed in the substrate on one side of the gate, and a drain is formed in the substrate on another side of the gate; a dielectric layer covering a surface of the gate; a contact structure passing through the dielectric layer and electrically connected to the source or the drain, the contact structure including a stack of a first contact layer and a second contact layer, and in a direction from the source to the drain, a width of the second contact layer being greater than a width of the first contact layer; and an electrical connection layer located at a top surface of the dielectric layer and in contact with part of a top surface of the second contact layer.

Abstract: The present disclosure provides a diode-triggered bidirectional silicon controlled rectifier and circuit. The silicon controlled rectifier includes: a P-type substrate; a first P well formed in the P-type substrate, a first P-type doped region and a first N-type doped region being formed in the first P well; a second P well formed in the P-type substrate, a third N-type doped region and a fourth P-type doped region being formed in the second P well; and an N well formed in the P-type substrate, a second P-type doped region, a second N-type doped region and a third P-type doped region being formed in the N well. The second N-type doped region is electrically connected with a positive electrode of a diode string, and the first P-type doped region and the fourth P-type doped region are electrically connected with a negative electrode of the diode string.

Abstract: Embodiments provide a semiconductor structure and a method for fabricating a semiconductor structure. The semiconductor structure includes: a source region and a drain region arranged at intervals on a substrate; a gate oxide layer arranged between the source region and the drain region; a gate structure arranged on the gate oxide layer; and a conductive plug arranged at a corresponding location of the source region and a corresponding location of the drain region. The gate structure includes a plurality of conductive layers, at least one target conductive layer is present in the plurality of conductive layers, and a distance from the at least one target conductive layer to the conductive plug is greater than a distance from at least one adjacent layer of the target conductive layer to the conductive plug.

Abstract: Embodiments provide a semiconductor structure and a method for fabricating a semiconductor structure. The semiconductor structure includes: a source region and a drain region arranged at intervals on a substrate; a gate oxide layer arranged between the source region and the drain region; a gate structure arranged on the gate oxide layer; and a conductive plug arranged at a corresponding location of the source region and a corresponding location of the drain region. The gate structure includes a conductive layer having a recessed side surface facing toward the conductive plug. Compared with a traditional gate structure, in the solutions of the present disclosure, a distance between the conductive layer having the recessed side surface and the conductive plug is increased, thereby reducing a parasitic capacitance between the gate structure and the conductive plug, such that capacitances between a gate and the source/drain region are reduced, and device characteristics are improved.

Abstract: Embodiments provide a semiconductor structure and a method for fabricating a semiconductor structure. The semiconductor structure includes: a source region and a drain region arranged at intervals on a substrate; a gate oxide layer arranged between the source region and the drain region; a gate structure arranged on the gate oxide layer; and a conductive plug arranged at a corresponding position of the source region and a corresponding position of the drain region. The gate structure includes a conductive layer having an inclined side surface facing toward the conductive plug. Compared with a traditional gate structure, in the solutions of the present disclosure, a distance between the conductive layer having the inclined side surface and the conductive plug is increased, thereby reducing a parasitic capacitance between the gate structure and the conductive plug, such that capacitance between a gate and the source/drain region is reduced, and device characteristics are improved.