A semiconductor device includes: a semiconductor chip having a main surface; an output region formed over the main surface with output elements being arranged in the output region; an inner element region surrounded by the output region and insulated and isolated from the output region with a first element different from the output elements being arranged in the inner element region; a first wiring layer formed over the main surface so as to cover the output region, and including a first output wiring electrically connected to the output elements; and a second wiring layer formed over the first wiring layer, and including second output wirings electrically connected to the first output wiring and a connection wiring insulated and isolated from the second output wirings, the connection wiring extending across the output region from the inner element region to an outer region outside the output region.

Provided is a semiconductor device including a semiconductor substrate, an electrode provided on a front surface of the semiconductor substrate, where the electrode contains aluminum, a barrier layer provided between the semiconductor substrate and the electrode. Here, the barrier layer includes a first titanium nitride layer, a first titanium layer, a second titanium nitride layer and a second titanium layer in a stated order with the first titanium nitride layer being positioned closest to the semiconductor substrate.

Methods of forming a semiconductor device are provided. A method includes introducing impurities into a part of a semiconductor substrate at a first surface of the semiconductor substrate by ion implantation, the impurities being configured to absorb electromagnetic radiation of an energy smaller than a bandgap energy of the semiconductor substrate. The method further includes forming a semiconductor layer on the first surface of the semiconductor substrate. The method further includes irradiating the semiconductor substrate with electromagnetic radiation configured to be absorbed by the impurities and configured to generate local damage of a crystal lattice of the semiconductor substrate. The method further includes separating the semiconductor layer and the semiconductor substrate by thermal processing of the semiconductor substrate and the semiconductor layer, where the thermal processing is configured to cause crack formation along the local damage of the crystal lattice by thermo-mechanical stress.

In a semiconductor device having a silicon carbide device, a technique capable of suppressing variation in a breakdown voltage and achieving reduction in an area of a termination structure is provided. In order to solve the above-described problem, in the present invention, in a semiconductor device having a silicon carbide device, a p-type first region and a p-type second region provided to be closer to an outer peripheral side than the first region are provided in a junction termination portion, a first concentration gradient is provided in the first region, and a second concentration gradient larger than the first concentration gradient is provided in the second region.

A switching device, such as a barrier junction Schottky diode, has a body of silicon carbide of a first conductivity type housing switching regions of a second conductivity type. The switching regions extend from a top surface of the body and delimit body surface portions between them. A contact metal layer having homogeneous chemical-physical characteristics extends on and in direct contact with the top surface of the body and forms Schottky contact metal portions with the surface portions of the body and ohmic contact metal portions with the switching regions. The contact metal layer is formed by depositing a nickel or cobalt layer on the body and carrying out a thermal treatment so that the metal reacts with the semiconductor material of the body and forms a silicide.

A semiconductor device is provided. On one main surface side of an n-type semiconductor substrate, a p-type diffusion region to serve as an anode of a diode is formed. A guard ring formed of a p-type diffusion region is formed to surround the anode. On the other main surface side, an n-type ultrahigh-concentration impurity layer and an n-type high-concentration impurity layer to serve as a cathode are formed. In a guard-ring opposed region located in the cathode and opposite to the guard ring, a cathode-side p-type diffusion region is formed. Accordingly, concentration of the electric current on an outer peripheral end portion of the anode is suppressed.

A method of forming a semiconductor device and a semiconductor device are provided. The method includes providing a wafer stack including a carrier wafer comprising graphite and a device wafer comprising a wide band-gap semiconductor material and having a first side and a second side opposite the first side, the second side being attached to the carrier wafer, defining device regions of the wafer stack, partly removing the carrier wafer so that openings are formed in the carrier wafer arranged within respective device regions and that the device wafer is supported by a residual of the carrier wafer; and further processing the device wafer while the device wafer remains supported by the residual of the carrier wafer.

Provided is a glass composition for protecting a semiconductor junction which contains at least SiO.sub.2, B.sub.2O.sub.3, Al.sub.2O.sub.3, ZnO and at least two oxides of alkaline earth metals selected from a group consisting of CaO, MgO and BaO, and substantially contains none of Pb, As, Sb, Li, Na and K, wherein an average linear expansion coefficient within a temperature range of 50 C. to 550 C. falls within a range of 3.3310.sup.6 to 4.1310.sup.6. A semiconductor device having high breakdown strength can be manufactured using such a glass material containing no lead in the same manner as a conventional case where a glass material containing lead silicate as a main component is used.

A semiconductor device according to the present invention includes: a semiconductor layer including a first conductivity type semiconductor region and a second conductivity type semiconductor region joined to the first conductivity type semiconductor region; and a surface electrode connected to the second conductivity type region on one surface of the semiconductor layer, including a first Al-based electrode, a second Al-based electrode, a barrier metal interposed between the first Al-based electrode and the second Al-based electrode, and a plated layer on the second Al-based electrode.

The nonvolatile memory device includes a memory cell having a transistor in which an insulating isolation layer is formed in a channel region. The nonvolatile memory device includes a metal-oxide-semiconductor (MOS) transistor as a basic component. An insulating isolation layer is formed in at least a channel region, and a gate insulating layer includes an insulating layer or a variable resistor and serves as a data storage. A gate includes a metal layer formed in a lower portion thereof. First source and drain regions are lightly doped with a dopant, and second source and drain regions are heavily doped with a dopant.