An ESD-protective-function-equipped composite electronic component is provided that includes multiple Zener diodes formed from first and second semiconductor layers. Moreover, the second semiconductor layers are disposed on an insulating substrate and in the same plane. The electronic component includes electrodes extending from each of the Zener diodes and one or more thin-film circuit element connected in series between a pair of the electrodes.

A robust electrostatic (ESD) protection device is provided. In one example, the ESD protection device is configured to accommodate three nodes. When used with a differential signal device, the first and second nodes may be coupled with the differential signal device's BP and BM signal lines, respectively, and the third node may be coupled to a voltage source. This allows for a single ESD protection device to be used to protect the signal lines of the differential signal device, thus providing significant substrate area savings as compared to the conventional means of using three dual-node ESD protection devices to accomplish substantially the same protection mechanism. Moreover, the ESD protection device may be structurally designed to handle high voltage ESD events, as required by the FlexRay standard.

A semiconductor structure includes a first device and a second device. The first device has a first surface. The first device includes a first active region defined by a first material system. The second device has a second surface. The second surface is coplanar with the first surface. The second device includes a second active region defined by a second material system. The second material system is different from the first material system.

Provided is a circuit board which includes a semiconductor substrate, a Zener diode, and a first vertical conductor and a second vertical conductor which configure a paired current path, wherein in the Zener diode, an N-type semiconductor region and a P-type semiconductor region being composed of the semiconductor substrate, with a PN junction extending in the thickness direction of the semiconductor substrate; and the first vertical conductor and the second vertical conductor penetrating the semiconductor substrate in the thickness direction, the first vertical conductor being brought into contact with the N-type semiconductor region, and the second vertical conductor being brought into contact with the P-type semiconductor region.

An ESD protection device includes a zener diode, and a series circuit of diodes and a series circuit of diodes that are connected in parallel with the zener diode. At the connection point between the diodes, an Al electrode film is formed on the surface of a Si substrate, and at the connection point between diodes, an Al electrode film is formed on the surface of the Si substrate. The diodes are formed on the surface of the Si substrate, and the diodes are formed in the thickness direction of the Si substrate. The Si substrate has a longitudinal direction and a shorter direction orthogonal to the longitudinal direction in planar view, and the Al electrode films are formed respectively at both ends in the shorter direction of the Si substrate. Thus, provided is an ESD protection device which suppresses the ESL, and keeps the clamp voltage low.

A semiconductor apparatus includes a semiconductor substrate, a semiconductor element, an edge termination region that surrounds the semiconductor element, a protective diode that has a first terminal and a second terminal, where the first terminal is positioned within the edge termination region and the second terminal is positioned outside the edge termination region, and a diffusion layer that has a floating potential, where the diffusion layer is provided in a gap portion between a region of the edge termination region that is aligned with the protective diode and the protective diode.

A semiconductor device includes a substrate, a well region of a first-conductivity type disposed in the substrate, a first impurity region of a second-conductivity type and having a plurality of branches disposed in the well region, a second impurity region of the first-conductivity type and having a plurality of branches, and a third impurity region of the first-conductivity type disposed in the well region. The second-conductivity type is opposite to the first-conductivity type. A portion of the first impurity region overlaps a portion of the third impurity region. The plurality of branches of the second impurity region are disposed in the third impurity region, and a portion of the third impurity region is disposed between the first impurity region and the second impurity region.

A semiconductor structure includes a first device and a second device. The first device has a first surface. The first device includes a first active region defined by a first material system. The second device has a second surface. The second surface is coplanar with the first surface. The second device includes a second active region defined by a second material system. The second material system is different from the first material system.

Three-dimensional electrostatic discharge (ESD) semiconductor devices are fabricated together with three-dimensional non-ESD semiconductor devices. For example, an ESD diode and FinFET are fabricated on the same bulk semiconductor substrate. A spacer merger technique is used in the ESD portion of a substrate to create double-width fins on which the ESD devices can be made larger to handle more current.

An exemplary lead frame includes a substrate and a bonding electrode, a first connecting electrode, and a second connecting electrode embedded in the substrate. A top surface of the bonding electrode includes a first bonding surface and a second bonding surface spaced from the first bonding surface. A top surface of the first connecting electrode includes a first connecting surface and a second connecting surface spaced from the first connecting surface. Top surfaces of the bonding electrode, the first connecting electrode and the second connecting electrode are exposed out of the substrate to support and electrically connect with light emitting chips. Light emitting chips can be mounted on the lead frame and electrically connect with each other in parallel or in series; thus, the light emitting chips can be connected with each in a versatile way.