A bipolar junction transistor is provided with an emitter structure that is positioned above the upper surface of the base region. The thickness of the emitter and the interfacial oxide thickness between the emitter and the base is configured to optimize a gain for a given type of transistor. A method of fabricating PNP and NPN transistors on the same substrate using a complementary bipolar fabrication process is provided. The method enables the emitter structure for the NPN transistor to be defined separately to that of the PNP transistor. This is achieved by epitaxially growing the emitter layer for the PNP transistor and growing the emitter layer for the NPN transistor in a thermal furnace.

The application provides a SCR and a manufacturing method thereof. The SCR comprises: a P-type heavily doped region 20 and an N-type lightly doped region 28 forming an anode formed on the upper part of an N-type well 60, a P-type heavily doped region 26 and an N-type heavily doped region 24 forming a cathode formed on the upper part of a P-type well 70, an active region of the N-type well 60 is between the N-type lightly doped region 28 and an interface of the N-type well 60 and the P-type well 70, a STI is provided between the N-type heavily doped region 24 and the interface, the STI is adjacent to the N-type heavily doped region 24, and an active region of the P-type well 70 is provided between the STI and the interface. The present application can improve trigger voltage of the SCR and save layout area.

The application provides a SCR and a manufacturing method thereof. The SCR comprises: a P-type heavily doped region 20 and an N-type lightly doped region 28 forming an anode formed on the upper part of an N-type well 60, a P-type heavily doped region 26 and an N-type heavily doped region 24 forming a cathode formed on the upper part of a P-type well 70, an active region of the N-type well 60 is between the N-type lightly doped region 28 and an interface of the N-type well 60 and the P-type well 70, a STI is provided between the N-type heavily doped region 24 and the interface, the STI is adjacent to the N-type heavily doped region 24, and an active region of the P-type well 70 is provided between the STI and the interface. The present application can improve trigger voltage of the SCR and save layout area.

A microelectronic device includes a PNP transistor and NPN transistor arranged vertically in a P-type doped semiconductor substrate. The PNP and NPN transistors are manufactured by: forming an N+ doped isolating well for the PNP transistor in the semiconductor substrate; forming a P+ doped region in the N+ doped isolating well; epitaxially growing a first semiconductor layer on the semiconductor substrate; forming an N+ doped well for the NPN transistor, where at least part of the N+ doped well extends into the first semiconductor layer; then epitaxially growing a second semiconductor layer on the first semiconductor layer; forming a P doped region forming the collector of the PNP transistor in the second semiconductor layer and in electrical contact with the P+ doped region; and forming an N doped region forming the collector of the NPN transistor in the second semiconductor layer and in electrical contact with the N+ doped well.

A microelectronic device includes a PNP transistor and NPN transistor arranged vertically in a P-type doped semiconductor substrate. The PNP and NPN transistors are manufactured by: forming an N+ doped isolating well for the PNP transistor in the semiconductor substrate; forming a P+ doped region in the N+ doped isolating well; epitaxially growing a first semiconductor layer on the semiconductor substrate; forming an N+ doped well for the NPN transistor, where at least part of the N+ doped well extends into the first semiconductor layer; then epitaxially growing a second semiconductor layer on the first semiconductor layer; forming a P doped region forming the collector of the PNP transistor in the second semiconductor layer and in electrical contact with the P+ doped region; and forming an N doped region forming the collector of the NPN transistor in the second semiconductor layer and in electrical contact with the N+ doped well.

A semiconductor device includes a bipolar junction transistor (BJT) structure including emitters in a first well having a first conductive type, collectors in respective second wells, the second wells having a second conductive type different from the first conductive type and being spaced apart from each other with the first well therebetween, and bases in the first well and between the emitters and the collectors. The BJT structure includes active regions having different widths that form the emitters, the collectors, and the bases.

A semiconductor device includes a bipolar junction transistor (BJT) structure including emitters in a first well having a first conductive type, collectors in respective second wells, the second wells having a second conductive type different from the first conductive type and being spaced apart from each other with the first well therebetween, and bases in the first well and between the emitters and the collectors. The BJT structure includes active regions having different widths that form the emitters, the collectors, and the bases.

Methods of according to the present disclosure can include: providing a substrate including: a first semiconductor region, a second semiconductor region, and a trench isolation (TI) laterally between the first and second semiconductor regions; forming a seed layer on the TI and the second semiconductor region of the substrate, leaving the first semiconductor region of the substrate exposed; forming an epitaxial layer on the substrate and the seed layer, wherein the epitaxial layer includes: a first semiconductor base material positioned above the first semiconductor region of the substrate, and an extrinsic base region positioned above the seed layer; forming an opening within the extrinsic base material and the seed layer to expose an upper surface of the second semiconductor region; and forming a second semiconductor base material in the opening.

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.

Various implementations described herein relate to a method for manufacturing, or causing to be manufactured, multiple devices packaged within a single semiconductor die. The multiple devices may have first devices that are arranged in a first multi-transistor stack with a first P-N configuration. The multiple devices may have second devices that are arranged in a second multi-transistor stack with a second P-N configuration that is different than the first P-N configuration.