A method of selectively and conformally doping semiconductor materials is disclosed. Some embodiments utilize a conformal dopant film deposited selectively on semiconductor materials by thermal decomposition. Some embodiments relate to doping non-line of sight surfaces. Some embodiments relate to methods for forming a highly doped crystalline semiconductor layer.

A method of forming a power semiconductor device includes providing a semiconductor layer of a first conductivity type extending to a first side and having a first doping concentration of first dopants providing majority charge carriers of a first electric charge type in the layer, and forming a deep trench isolation including forming a trench which extends from the first side into the semiconductor layer and includes, in a vertical cross-section perpendicular to the first side, a wall, forming a compensation semiconductor region of the first conductivity type at the wall and having a second doping concentration of the first dopants higher than the first doping concentration, and filling the trench with a dielectric material. The amount of first dopants in the compensation semiconductor region is such that a field-effect of fixed charges of the first electric charge type which are trapped in the trench is at least partly compensated.

The present disclosure discloses a semiconductor device with C-shaped channel portion, a method of manufacturing the same, and an electronic apparatus including the same. According to the embodiments, the semiconductor device may comprise a channel portion on a substrate, the channel portion including two or more curved nanosheets or nanowires spaced apart from each other in a lateral direction relative to the substrate and each having a C-shaped cross section; source/drain portions respectively located at upper and lower ends of the channel portion relative to the substrate; and a gate stack surrounding an outer circumference of each nanosheet or nanowire in the channel portion.

A fin field-effect transistor (“FinFET”) semiconductor device and method of forming the same. In one example, a semiconductor fin is formed over a semiconductor substrate. A conformal dielectric layer is formed on a top and side surfaces of the fin. A doped semiconductor layer is formed over the conformal dielectric layer, the doped semiconductor layer including a dopant. The doped semiconductor layer is heated thereby driving the dopant through the conformal dielectric layer and forming a doped region of the fin.

Disclosed herein are structures and techniques for device isolation in integrated circuit (IC) assemblies. In some embodiments, an IC assembly may include multiple transistors spaced apart by an isolation region. The isolation region may include a doped semiconductor body whose dopant concentration is greatest at one or more surfaces, or may include a material that is lattice-mismatched with material of the transistors, for example.

An edge delimits a semiconductor body in a direction parallel to a first side of the semiconductor body. A peripheral area is arranged between the active area and edge. A first semiconductor region of a first conductivity type extends from the active area into the peripheral area. A second semiconductor region of a second conductivity type forms a pn-junction with the first semiconductor region. A first edge termination region of the second conductivity type arranged at the first side adjoins the first semiconductor region, between the second semiconductor region and edge. A second edge termination region of the first conductivity type arranged at the first side and between the first edge termination region and edge has a varying concentration of dopants of the first conductivity type which increases at least next to the first edge termination region substantially linearly with an increasing distance from the first edge termination region.

One aspect of the disclosure is directed to a method of forming a semiconductor structure including: forming a fin over a substrate within a device region, the fin including alternating layers of a sacrificial material and a semiconductor material, and including a lower channel region; forming a dopant-containing layer over the fin and the substrate; exposing an upper portion of the fin by removing the dopant-containing layer from the upper portion of the fin; removing the sacrificial material from the fin thereby suspending the semiconductor material within the fin between a pair of spacers and over the lower channel region of the fin; performing an anneal to drive in dopants from the dopant-containing layer to the lower channel region of the fin; and forming an active gate over the lower channel region of the fin and substantially surrounding the suspended semiconductor material over the lower channel region of the fin.

A method of forming a semiconductor structure includes forming a substrate, the substrate having a first portion with a first height and second recessed portions with a second height less than the first height. The method also includes forming embedded source/drain regions disposed over top surfaces of the second recessed portions of the substrate, and forming one or more fins from a portion of the substrate disposed between the embedded source/drain regions, the one or more fins providing channels for fin field-effect transistors (FinFETs). The method further includes forming a gate stack disposed over the one or more fins, and forming inner oxide spacers disposed between the gate stack and the source/drain regions.

A method for semiconductor processing includes forming a first dielectric layer comprising an N-type dopant over a first plurality of fins extending above a first region of a substrate, forming a second dielectric layer comprising a P-type dopant over the first plurality of fins and a second plurality of fins extending above a second region of the substrate, the second dielectric layer overlying the first dielectric layer, and forming an isolation layer between adjacent ones of the first plurality of fins, and between adjacent ones of the second plurality of fins. The method further includes performing an implantation process using a first dopant, the implantation process changing an etching rate of the isolation layer, and recessing the isolation layer, the first dielectric layer, and the second dielectric layer, where after the recessing, the first and the second plurality of fins extend above an upper surface of the isolation layer.

A method for fabricating a vertical transistor device includes forming a first plurality of fins in a first device region and a second plurality of fins in a second device region on a substrate. The first plurality of fins have a SiGe portion exposed above a top surface of the first region and a portion of the second plurality of fins are exposed above a top surface of the second region. The method further includes depositing a first GeO.sub.2 layer on the top surface of the device and over the exposed SiGe portion of the first plurality of fins and the exposed portion of the second plurality of fins.