Structures including electrical isolation and methods of forming a structure including electrical isolation. A semiconductor layer is formed over a semiconductor substrate and shallow trench isolation regions are formed in the semiconductor layer. The semiconductor layer includes single-crystal semiconductor material having an electrical resistivity that is greater than or equal to 1000 ohm-cm. The shallow trench isolation regions are arranged to surround a portion of the semiconductor layer to define an active device region. A polycrystalline layer is positioned in the semiconductor layer and extends laterally beneath the active device region and the shallow trench isolation regions that surround the active device region.

An array of gated devices includes a plurality of gated devices arranged in rows and columns and individually including an elevationally inner region, a mid region elevationally outward of the inner region, and an elevationally outer region elevationally outward of the mid region. A plurality of access lines are individually laterally proximate the mid regions along individual of the rows. A plurality of data/sense lines are individually elevationally outward of the access lines and electrically coupled to the outer regions along individual of the columns. A plurality of metal lines individually extends along and between immediately adjacent of the rows elevationally inward of the access lines. The individual metal lines are directly against and electrically coupled to sidewalls of the inner regions of each of immediately adjacent of the rows. The metal lines are electrically isolated from the data/sense lines. Other arrays of gated devices and methods of forming arrays of gated devices are disclosed.

A power amplifier circuit includes a first transistor disposed on a semiconductor substrate; a second transistor that supplies a bias current based on a first current which is a part of a control current to the first transistor; a current output element in which a current flowing therethrough increases in accordance with a rise in temperature; and a wiring portion including a plurality of metal layers that are electrically connected to an emitter of the first transistor and that are stacked one on top of another so as to oppose the semiconductor substrate. At least one metal layer among the plurality of metal layers extends so as to overlap an area extending from at least a part of a first disposition area in which the first transistor is disposed to a second disposition area in which the current output element is disposed in plan view of the semiconductor substrate.

An IGBT module, a conductor installing structure for the IGBT module and an inverter are provided. The conductor installing structure for the IGBT module includes a substrate, a conductor and an insulation sleeve sleeved on the conductor and insulatedly isolating the conductor from the substrate. In the conductor installing structure for the IGBT module according to the present disclosure, by using the insulation sleeve sleeved on the conductor to insulatedly isolating the conductor from the substrate, the comparative tracking index of the IGBT module is improved, thereby improving the creepage distance of the IGBT module. In addition, compared with conventional technologies of spraying insulation varnish or insulation paste, the insulating property of the insulation sleeve can be better detected and guaranteed, and the bounding between the insulation sleeve and the substrate can be better enhanced, improving the insulation reliability.

An array of gated devices includes a plurality of gated devices arranged in rows and columns and individually including an elevationally inner region, a mid region elevationally outward of the inner region, and an elevationally outer region elevationally outward of the mid region. A plurality of access lines are individually laterally proximate the mid regions along individual of the rows. A plurality of data/sense lines are individually elevationally outward of the access lines and electrically coupled to the outer regions along individual of the columns. A plurality of metal lines individually extends along and between immediately adjacent of the rows elevationally inward of the access lines. The individual metal lines are directly against and electrically coupled to sidewalls of the inner regions of each of immediately adjacent of the rows. The metal lines are electrically isolated from the data/sense lines. Other arrays of gated devices and methods of forming arrays of gated devices are disclosed.

An array of gated devices includes a plurality of gated devices arranged in rows and columns and individually including an elevationally inner region, a mid region elevationally outward of the inner region, and an elevationally outer region elevationally outward of the mid region. A plurality of access lines are individually laterally proximate the mid regions along individual of the rows. A plurality of data/sense lines are individually elevationally outward of the access lines and electrically coupled to the outer regions along individual of the columns. A plurality of metal lines individually extends along and between immediately adjacent of the rows elevationally inward of the access lines. The individual metal lines are directly against and electrically coupled to sidewalls of the inner regions of each of immediately adjacent of the rows. The metal lines are electrically isolated from the data/sense lines. Other arrays of gated devices and methods of forming arrays of gated devices are disclosed.

In accordance with at least one embodiment, an ESD device comprises: a semiconductor; a pad; a ground rail; a p-well formed in the semiconductor; a first p-type region formed in the p-well and electrically coupled to the ground rail; a first n-type region formed in the p-well and electrically coupled to the pad; a second n-type region formed in the p-well and electrically coupled to the ground rail; an n-well formed in the semiconductor; a first n-type region formed in the n-well; a first p-type region formed in the n-well and electrically coupled to the pad; and a second p-type region formed in the n-well and electrically coupled to the first n-type region formed in the n-well.

Structures that include bipolar junction transistors and methods of forming such structures. The structure comprises a semiconductor layer, a substrate, and a dielectric layer disposed between the semiconductor layer and the substrate. The structure further comprises a first bipolar junction transistor including a first collector in the substrate, a first emitter, and a first base layer. The first base layer extends through the dielectric layer from the first emitter to the first collector. The structure further comprises a second bipolar junction transistor including a second collector in the substrate, a second emitter, and a second base layer. The second base layer extends through the dielectric layer from the second emitter to the second collector. The second base layer is connected to the first base layer by a section of the semiconductor layer to define a base line.

Structures that include bipolar junction transistors and methods of forming such structures. The structure comprises a substrate having a top surface, a trench isolation region in the substrate, and a base layer on the top surface of the substrate. The base layer extending across the trench isolation region. A first bipolar junction transistor includes a first collector in the substrate and a first emitter on a first portion of the first base layer. The first portion of the first base layer is positioned between the first collector and the first emitter. A second bipolar junction transistor includes a second collector in the substrate and a second emitter on a second portion of the first base layer. The second portion of the first base layer is positioned between the second collector and the second emitter.

A PNP transistor is manufactured in parallel with the manufacture of NPN, NMOS, and PMOS transistors. A first semiconductor layer is deposited on a P-type doped semiconductor substrate and divided into first, second, and third regions, with the third region forming the base. An insulating well is deeply implanted into the substrate. First and second third wells, respectively of N-type and P-type are formed to extend between the second region and third region and the insulating well. A third well of P-type is formed below the third region to provide the collector. Insulating layers are deposited over the third region and patterned to form an opening. Epitaxial growth of a second P-type doped semiconductor layer is performed in the opening to provide the emitter.