A power element includes a substrate structure, an insulation layer, a dielectric layer, a transistor, and a plurality of zener diodes. The transistor is located in a transistor formation region of the substrate structure. The plurality of zener diodes are located in a circuit element formation region of the substrate structure and connected in series with each other. Each of the zener diodes includes a zener diode doping structure and a zener diode metal structure. The zener diode doping structure is formed on the insulation layer and is covered by the dielectric layer. The zener diode doping structure includes a P-type doped region and an N-type doped region that are in contact with each other. The zener diode metal structure is formed on the dielectric layer and partially passes through the dielectric layer to be electrically connected to the P-type doped region and the N-type doped region.

A transient voltage suppressor is disclosed that includes an electrode, a substrate disposed on the electrode, the substrate having a first doping, an epitaxial layer disposed on the substrate, the epitaxial layer having a second doping that is different from the first doping, a channel formed in the epitaxial layer having a width W, a length L and a plurality of curved regions, the channel forming a plurality of adjacent sections, the channel having a third doping that is different from the first doping and the second doping and a metal layer formed on top of the channel and contained within the width W of the channel.

A semiconductor device includes a semiconductor substrate, an upper diffusion region and a lower diffusion region. The semiconductor substrate has a main surface. The upper diffusion region of a first conductivity type is disposed close to the main surface of the semiconductor device. The lower diffusion region of a second conductivity type is disposed up to a position deeper than the upper diffusion region in a depth direction of the semiconductor substrate from the main surface as a reference, and has a higher impurity concentration than the semiconductor substrate. A diode device is provided by having a PN junction surface at an interface between the upper diffusion region and the lower diffusion region, and the PN junction surface has a curved surface disposed at a portion opposite to the main surface.

Devices, systems and methods for uniquely identifying integrated circuits are provided. For at least one embodiment, an identifiable integrated circuit in a lot of integrated circuits includes a plurality of identifier devices. Each of the identifier devices, when tested, returns a series of first test results that form an analog identifier for the integrated circuit. For one embodiment, the identifier devices is a Zener diode. The test results may be based on reverse breakdown voltage measurements determined prior to packaging of the integrated circuit. Later testing of the integrated circuit returns a second series of reverse breakdown voltage measurements that monotonically vary over time and temperature, as compared to the first series of test results. Such monotonical variation facilitates correlation of the first series of test results with the second series of test results and, thereby, identification of the integrated circuit.

A transient voltage suppression device includes a substrate; a first conductivity type well region disposed in the substrate and comprising a first well and a second well; a third well disposed on the substrate, a bottom part of the third well extending to the substrate; a fourth well disposed in the first well; a first doped region disposed in the second well; a second doped region disposed in the third well; a third doped region disposed in the fourth well; a fourth doped region disposed in the fourth well; a fifth doped region extending from inside of the fourth well to the outside of the fourth well, a portion located outside the fourth well being located in the first well; a sixth doped region disposed in the first well; a seventh doped region disposed below the fifth doped region and in the first well.

A power element includes a substrate structure, an insulation layer, a dielectric layer, a transistor, and a plurality of zener diodes. The transistor is located in a transistor formation region of the substrate structure. The plurality of zener diodes are located in a circuit element formation region of the substrate structure and connected in series with each other. Each of the zener diodes includes a zener diode doping structure and a zener diode metal structure. The zener diode doping structure is formed on the insulation layer and is covered by the dielectric layer. The zener diode doping structure includes a P-type doped region and an N-type doped region that are in contact with each other. The zener diode metal structure is formed on the dielectric layer and partially passes through the dielectric layer to be electrically connected to the P-type doped region and the N-type doped region.

A composite power element and a method for manufacturing the same are provided. The power element includes a substrate structure, an insulation layer, a dielectric layer, a metal-oxide-semiconductor field-effect transistor (MOSFET), and a zener diode. The MOSFET is formed in a transistor formation region of the substrate structure. The zener diode is formed in a circuit element formation region of the substrate structure, and includes a zener diode doped structure formed on the insulation layer and covered by the dielectric layer. The zener diode doped structure includes a P-type doped region and an N-type doped region. The zener diode includes a zener diode metal structure formed on the dielectric layer and partially passes through the dielectric layer to be electrically connected to the P-type doped region and the N-type doped region. The zener diode is configured to receive a reverse bias voltage when the power element is energized.

A diode structure and a manufacturing method are disclosed. The diode structure includes a semiconductor substrate, a first semiconductor layer, a second semiconductor layer and an epitaxy layer. The semiconductor substrate includes a first surface. The first semiconductor layer and the second semiconductor layer are extended toward the interior of the semiconductor substrate from the first surface by implanting a dopant. Both of the semiconductor types of the first semiconductor layer and the second semiconductor layer are opposite to the semiconductor type of the semiconductor substrate. The epitaxy layer is formed on the first surface, connected with the first semiconductor layer and the second semiconductor layer and extended outwardly from the first surface. The first semiconductor layer and the second semiconductor layer are connected with each other, continuously. The concentration distribution of the dopant within the first semiconductor layer and the second semiconductor layer is in a discontinuous curve.

Provided is a semiconductor device including a semiconductor substrate; a transistor portion provided in the semiconductor substrate; a current sensing portion for detecting current flowing through the transistor portion; an emitter electrode set to an emitter potential of the transistor portion; a sense electrode electrically connected to the current sensing portion; and a Zener diode electrically connected between the emitter electrode and the sense electrode. Provided is a semiconductor device fabricating method including providing a transistor portion in a semiconductor substrate; providing a current sensing portion for detecting current flowing through the transistor portion; providing an emitter electrode set to an emitter potential of the transistor portion; providing a sense electrode electrically connected to the current sensing portion; and providing a Zener diode electrically connected between the emitter electrode and the sense electrode.

A method for manufacturing a Zener diode includes implanting an N-type Buried Layer (NBL) with an N-type dopant in a first epitaxial layer, wherein the NBL comprises an NBL opening excluding the N-type dopant. A P-type Buried Layer (PBL) having a peak PBL doping concentration below the NBL is implanted. A second epitaxial layer is grown over the NBL. A P-type region (Plink) is implanted to couple to the PBL above the NBL opening, and to couple the Plink to an Anode electrode. An N-type region (Nlink) is implanted to couple the NBL to a Cathode electrode.