A semiconductor device includes a semiconductor body with a first surface, a contact electrode arranged on the first surface, and a passivation layer on the first surface adjacent the contact electrode. The passivation layer includes a layer stack with an amorphous semi-insulating layer on the first surface, a first nitride layer on the amorphous semi-insulating layer, and a second nitride layer on the first nitride layer.

A method for forming a plurality of semiconductor devices on a plurality of semiconductor wafers includes forming an electrically conductive layer on a surface of a first semiconductor wafer so that a Schottky-contact is generated between the electrically conductive layer formed on the first semiconductor wafer and the first semiconductor wafer. The method further includes forming an electrically conductive layer on a surface of a second semiconductor wafer so that a Schottky-contact is generated between the electrically conductive layer formed on the second semiconductor wafer and the second semiconductor wafer. A material composition of the electrically conductive layers formed on the first and second semiconductor wafers are selected based on a value of the physical property of the first and second semiconductor wafers, respectively. The material composition of the electrically conductive layers formed on the first and second semiconductor wafers are different.

Under one aspect, a power Schottky diode includes a cathode; a semiconductor disposed over the cathode, the semiconductor including at least a first region and a second region, the second region defining a guard ring; an anode disposed over the first region and at least a portion of the guard ring, the anode including a metal, a junction between the anode and the first region defining a Schottky barrier; and an oxide disposed over the guard ring. Additionally, the power Schottky diode can include a resistive material disposed over at least a portion of the guard ring and at least a portion of the oxide. The resistive material can inhibit a flow of holes from the guard ring to the anode following a heavy ion strike to the guard ring. The anode further can be disposed over at least a portion of, or the entirety of, the resistive material.

A diode device and manufacturing method thereof are provided. The diode device includes a substrate, an epitaxial layer, a trench gate structure, a Schottky diode structure and a termination structure. An active region and a termination region are defined in the epitaxial layer. The Schottky diode structure and the trench gate structure are located in the active region and the termination structure is located in the termination region. The termination structure includes a termination trench formed in the epitaxial layer, a termination insulating layer, a first spacer, a second spacer and a first doped region. The termination insulating layer is conformingly formed on inner walls of the termination trench. The first and second spacers are disposed on two sidewalls of the termination trench. The first doped region formed beneath the termination trench has a conductive type reverse to that of the epitaxial layer.

A semiconductor device comprising a source region being electrically connected to a first load terminal (E) of the semiconductor device and a drift region comprising a first semiconductor material (M1) having a first band gap, the drift region having dopants of a first conductivity type and being configured to carry at least a part of a load current between the first load terminal (E) and a second load terminal (C) of the semiconductor device, is presented. The semiconductor device further comprises a semiconductor body region having dopants of a second conductivity type complementary to the first conductivity type and being electrically connected to the first load terminal (E), a transition between the semiconductor body region and the drift region forming a pn-junction, wherein the pn-junction is configured to block a voltage applied between the first load terminal (E) and the second load terminal (C). The semiconductor body region isolates the source region from the drift region and includes a reduced band gap zone comprising a second semiconductor material (M2) having a second band gap that is smaller than the first band gap, wherein the reduced band gap zone is arranged in the semiconductor body region such that the reduced band gap zone and the source region exhibit, in a cross-section along a vertical direction (Z), at least one of a common lateral extension range (LR) along a first lateral direction (X) and a common vertical extension range (VR) along the vertical direction (Z).

Techniques for reducing the specific contact resistance of metal-semiconductor (group IV) junctions by interposing a monolayer of group V or group III atoms at the interface between the metal and the semiconductor, or interposing a bi-layer made of one monolayer of each, or interposing multiple such bi-layers. The resulting low specific resistance metal-group IV semiconductor junctions find application as a low resistance electrode in semiconductor devices including electronic devices (e.g., transistors, diodes, etc.) and optoelectronic devices (e.g., lasers, solar cells, photodetectors, etc.) and/or as a metal source and/or drain region (or a portion thereof) in a field effect transistor (FET). The monolayers of group III and group V atoms are predominantly ordered layers of atoms formed on the surface of the group IV semiconductor and chemically bonded to the surface atoms of the group IV semiconductor.

A semiconductor device having a low on-voltage of IGBT and a small reverse recovery current of the diode is provided. The semiconductor device includes a semiconductor substrate having a gate trench and a dummy trench. The semiconductor substrate includes emitter, body, barrier and pillar regions between the gate trench and the dummy trench. The emitter region is an n-type region being in contact with the gate insulating film and exposed on a front surface. The body region is a p-type region being in contact with the gate insulating film at a rear surface side of the emitter region. The barrier region is an n-type region being in contact with the gate insulating film at a rear surface side of the body region and in contact with the dummy insulating film. The pillar region is an n-type region connected to the front surface electrode and the barrier region.

Field-plate structures are disclosed for electrical field management in semiconductor devices. A field-plate semiconductor device comprises a semiconductor substrate, a first ohmic contact and a second ohmic contact disposed over the semiconductor substrate, one or more coupling capacitors, and one or more capacitively-coupled field plates disposed over the semiconductor substrate between the first ohmic contact and the second ohmic contact. Each of the capacitively-coupled field plates is capacitively coupled to the first ohmic contact through one of the coupling capacitors, the coupling capacitor having a first terminal electrically connected to the first ohmic contact and a second terminal electrically connected to the capacitively-coupled field plate.

A semiconductor device includes a transistor, a semiconductor layer, an active region and a conductive layer. The active region is in the semiconductor layer. The conductive layer is configured to maintain a channel in the active region when the transistor is triggered to be conducted.

A method of manufacturing a silicon carbide semiconductor device is provided. The method suppresses the increase in the number of manufacturing steps and is capable of suppressing the degradation of ohmic characteristics of an alloy layer with respect to a semiconductor substrate. The method includes a step of forming a metal layer made of a first metal on a semiconductor substrate made of silicon carbide; a step of forming a metal nitride film obtained by nitriding a second metal on the metal layer; a step of directing a laser light through the metal nitride film to form a layer of an alloy of silicon carbide in the semiconductor substrate and the first metal in the metal layer; and a step of forming an electrode on the metal nitride film.