The present techniques relate to a semiconductor device having resistance which has a positive temperature coefficient and a suitable value, and to a method for manufacturing a semiconductor device having resistance which has a positive temperature coefficient and a suitable value. The semiconductor device related to the present techniques is a bipolar device in which a current flows through a pn junction. The semiconductor device includes an n-type silicon carbide drift layer, a p-type first silicon carbide layer formed on the silicon carbide drift layer, and a p-type second silicon carbide layer formed on the first silicon carbide layer. Then, the second silicon carbide layer has a positive temperature coefficient of resistance.

The present techniques relate to a semiconductor device having resistance which has a positive temperature coefficient and a suitable value, and to a method for manufacturing a semiconductor device having resistance which has a positive temperature coefficient and a suitable value. The semiconductor device related to the present techniques is a bipolar device in which a current flows through a pn junction. The semiconductor device includes an n-type silicon carbide drift layer, a p-type first silicon carbide layer formed on the silicon carbide drift layer, and a p-type second silicon carbide layer formed on the first silicon carbide layer. Then, the second silicon carbide layer has a positive temperature coefficient of resistance.

Disclosed examples include integrated circuits and bipolar transistors with a first region of a first conductivity type in a substrate, a collector region of a second conductivity type disposed in the substrate, and a base region of the first conductivity type extending into the first region. A first emitter region of the second conductivity type extends into the first region and includes a lateral side spaced from and facing the base region. A second emitter region of the second conductivity type extends downward into the first region, abutting the top surface and an upper portion of the first lateral side of the first emitter region to mitigate surface effects and gain degradation caused by hydrogen injection from radiation to provide a radiation hardened bipolar transistor.

A method of producing a semiconductor component is provided. The method includes providing a silicon substrate having a <111>-surface defining a vertical direction, forming in the silicon substrate at least one electronic component, forming at least two epitaxial semiconductor layers on the silicon substrate to form a heterojunction above the <111>-surface, and forming a HEMT-structure above the <111>-surface.

Methods for manufacturing a bipolar junction transistor are provided. A method includes providing a semiconductor substrate having a trench isolation, where a pad resulting from a manufacturing of the trench isolation is arranged on the semiconductor substrate, providing an isolation layer on the semiconductor substrate and the pad such that the pad is covered by the isolation layer, removing the isolation layer up to the pad, and selectively removing the pad to obtain an emitter window.

A transient voltage protection circuit includes a first input/output pad, a second input/output pad, and a trigger circuit coupled between the first input/output pad and the second input/output pad. The trigger circuit includes a first trigger element which includes a first input/output node, a second input/output node, a third input/output node, and a first substrate diode coupled to the third input/output node of the first trigger element. The trigger circuit further includes a first resistor coupled between the first input/output node of the first trigger element and the second input/output node of the first trigger element. The trigger circuit further includes a second trigger element which includes a first input/output node, a second input/output node, a third input/output node, wherein the second input/output node of the first trigger element is coupled to the first input/output node of the second trigger element, and a second substrate diode coupled to the third input/output node of the second trigger element. The trigger circuit further includes a second resistor coupled between the first input/output node of the second trigger element and the second input/output node of the second trigger element.

A method for manufacturing a bipolar junction transistor is provided. A layer stack is provided that comprises a semiconductor substrate having a trench isolation; an isolation layer arranged on the semiconductor substrate, wherein the first isolation layer comprises a recess forming an emitter window; lateral spacers arranged on sidewalls of the emitter window; a base layer arranged in the emitter window on the semiconductor substrate; and an emitter layer arranged on the isolation layer, the lateral spacers and the base layer. A sacrificial layer is provided on the emitter layer thereby overfilling a recess formed by the emitter layer due to the emitter window. The sacrificial layer is selectively removed up to the emitter layer while maintaining a part of the sacrificial layer filling the recess of the emitter layer. The emitter layer is selectively removed up to the isolation layer while maintaining the filled recess of the emitter layer.

A semiconductor device provided herein includes a trench in which a gate insulating layer (GIL) and a gate electrode are located. A step is provided in a lateral surface of the trench. The step surface descends toward a center of the trench. First and second regions are of a first conductivity type. A body region, a lateral region and a bottom region are of a second conductivity type. The first region, a body region, and the second region are in contact with the GIL at the upper lateral surface of the trench. The second region is in contact with the GIL at the lower lateral surface of the trench. A lateral region is in contact with the GIL at the lower lateral surface. A bottom region is in contact with the GIL at the bottom surface of the trench.

A semiconductor device including a well region in a substrate, an impurity region in the well region, a first active fin on the impurity region, a second active fin on the well region, and a connection pattern penetrating the second active fin and connected to the well region may be provided. The substrate and the impurity region include impurities having a first conductivity type. The well region includes impurities having a second conductivity type different from the first conductivity type. The first active fin includes a plurality of first semiconductor patterns that are spaced apart from each other in a direction perpendicular to a top surface of the substrate. The first semiconductor patterns and the impurity region include impurities having the first conductivity type.

A semiconductor device including a well region in a substrate, an impurity region in the well region, a first active fin on the impurity region, a second active fin on the well region, and a connection pattern penetrating the second active fin and connected to the well region may be provided. The substrate and the impurity region include impurities having a first conductivity type. The well region includes impurities having a second conductivity type different from the first conductivity type. The first active fin includes a plurality of first semiconductor patterns that are spaced apart from each other in a direction perpendicular to a top surface of the substrate. The first semiconductor patterns and the impurity region include impurities having the first conductivity type.