Structures for a bipolar junction transistor and methods of fabricating a structure for a bipolar junction transistor. The structure includes a first base layer, a second base layer, a first terminal positioned between the first base layer and the second base layer, a second terminal, and a third terminal. The first base layer, the second base layer, and the first terminal are positioned between the second terminal and the third terminal. For example, the first terminal may be positioned in a vertical direction between the first and second base layers.

The present disclosure relates to semiconductor structures and, more particularly, to high-voltage electrostatic discharge (ESD) devices and methods of manufacture. The structure includes a vertical silicon-controlled rectifier (SCR) connecting to an anode, and comprising a buried layer of a first dopant type in electrical contact with an underlying buried layer a second dopant type split with an isolation region of the first dopant type within a substrate

The present disclosure relates to semiconductor structures and, more particularly, to high-voltage electrostatic discharge (ESD) devices and methods of manufacture. The structure includes a vertical silicon-controlled rectifier (SCR) connecting to an anode, and comprising a buried layer of a first dopant type in electrical contact with an underlying buried layer a second dopant type split with an isolation region of the first dopant type within a substrate

Devices and methods for manufacturing a deep trench capacitor fuse for high voltage breakdown defense. A semiconductor device comprising a deep trench capacitor structure and a transistor structure. The transistor structure may comprise a base, a first terminal formed within the base, and a second terminal formed within the base. The first terminal and the second terminal may be formed by doping the base. The deep trench capacitor structure may comprise a first metallic electrode layer and a second metallic electrode layer. The first terminal may be electrically connected to the first metallic electrode layer, and the second terminal may be electrically connected to the second metallic electrode layer.

Devices and methods for manufacturing a deep trench capacitor fuse for high voltage breakdown defense. A semiconductor device comprising a deep trench capacitor structure and a transistor structure. The transistor structure may comprise a base, a first terminal formed within the base, and a second terminal formed within the base. The first terminal and the second terminal may be formed by doping the base. The deep trench capacitor structure may comprise a first metallic electrode layer and a second metallic electrode layer. The first terminal may be electrically connected to the first metallic electrode layer, and the second terminal may be electrically connected to the second metallic electrode layer.

Structures for a bipolar junction transistor and methods of forming a structure for a bipolar junction transistor. The structure includes a substrate having a well, a first terminal including a first raised semiconductor layer, a second terminal including a second raised semiconductor layer, and a base layer positioned in a lateral direction between the first raised semiconductor layer of the first terminal and the second raised semiconductor layer of the second terminal. The base layer has an overlapping arrangement with the well. The structure further includes a dielectric layer positioned in a vertical direction between the first terminal and the substrate, the second terminal and the substrate, and the base layer and the substrate.

A method of fabricating a transistor includes doping non-overlapping first, second, and third wells in a silicon layer of a substrate. The substrate, second and third wells have a first type of conductivity and the first well and silicon layer have a second type of conductivity. First and second insulating layers are thermally grown over the second well between the first well and the third well, and over the third well, respectively. A gate stack is formed over the first insulating layer and the third well. A first source region having the second type of conductivity is formed in the third well. A gate spacer is formed, a fourth well having the first type of conductivity is doped in the third well between the second insulating layer and the gate spacer, a second source region is formed over the fourth well, and a drain is formed in the first well.

A method of fabricating a transistor includes doping non-overlapping first, second, and third wells in a silicon layer of a substrate. The substrate, second and third wells have a first type of conductivity and the first well and silicon layer have a second type of conductivity. First and second insulating layers are thermally grown over the second well between the first well and the third well, and over the third well, respectively. A gate stack is formed over the first insulating layer and the third well. A first source region having the second type of conductivity is formed in the third well. A gate spacer is formed, a fourth well having the first type of conductivity is doped in the third well between the second insulating layer and the gate spacer, a second source region is formed over the fourth well, and a drain is formed in the first well.

A wafer has a device area on one side with a plurality of devices partitioned by a plurality of division lines. Either side of the wafer is attached to an adhesive tape supported by a first annular frame. A modified region is formed in the wafer along the division lines by a laser. The wafer is placed on a support member whose outer diameter is smaller than an inner diameter of the first annular frame. After applying the laser beam, the adhesive tape is expanded thereby dividing the wafer along the division lines. A second annular frame is attached to a portion of the expanded adhesive tape. An inner diameter of the second annular frame is smaller than the outer diameter of the support member and smaller than the inner diameter of the first annular frame.

A wafer has a device area on one side with a plurality of devices partitioned by a plurality of division lines. Either side of the wafer is attached to an adhesive tape supported by a first annular frame. A modified region is formed in the wafer along the division lines by a laser. The wafer is placed on a support member whose outer diameter is smaller than an inner diameter of the first annular frame. After applying the laser beam, the adhesive tape is expanded thereby dividing the wafer along the division lines. A second annular frame is attached to a portion of the expanded adhesive tape. An inner diameter of the second annular frame is smaller than the outer diameter of the support member and smaller than the inner diameter of the first annular frame.