Doping techniques for fin-like field effect transistors (FinFETs) are disclosed herein. An exemplary method includes forming a fin structure, forming a doped amorphous layer over a portion of the fin structure, and performing a knock-on implantation process to drive a dopant from the doped amorphous layer into the portion of the fin structure, thereby forming a doped feature. The doped amorphous layer includes a non-crystalline form of a material. In some implementations, the knock-on implantation process crystallizes at least a portion of the doped amorphous layer, such that the portion of the doped amorphous layer becomes a part of the fin structure. In some implementations, the doped amorphous layer includes amorphous silicon, and the knock-on implantation process crystallizes a portion of the doped amorphous silicon layer.

A semiconductor device includes an edge terminal structure portion provided between the active portion and an end portion of the semiconductor substrate on an upper surface of the semiconductor substrate, in which the edge terminal structure portion has a first high concentration region of the first conductivity type which has a donor concentration higher than a doping concentration of the bulk donor in a region between the upper surface and a lower surface of the semiconductor substrate, an upper surface of the first high concentration region is located on an upper surface side of the semiconductor substrate, and a lower surface of the first high concentration region is located on a lower surface side of the semiconductor substrate.

Doping techniques for fin-like field effect transistors (FinFETs) are disclosed herein. An exemplary method includes forming a fin structure, forming a doped amorphous layer over a portion of the fin structure, and performing a knock-on implantation process to drive a dopant from the doped amorphous layer into the portion of the fin structure, thereby forming a doped feature. The doped amorphous layer includes a non-crystalline form of a material. In some implementations, the knock-on implantation process crystallizes at least a portion of the doped amorphous layer, such that the portion of the doped amorphous layer becomes a part of the fin structure. In some implementations, the doped amorphous layer includes amorphous silicon, and the knock-on implantation process crystallizes a portion of the doped amorphous silicon layer.

Structures with altered crystallinity beneath semiconductor devices and methods associated with forming such structures. Trench isolation regions surround an active device region composed of a single-crystal semiconductor material. A first non-single-crystal layer is arranged beneath the trench isolation regions and the active device region. A second non-single-crystal layer is arranged beneath the trench isolation regions and the active device region. The first non-single-crystal layer is arranged between the second non-single-crystal layer and the active device region.

A method for forming reliefs on a face of a substrate is provided, successively including forming a protective screen for protecting at least a first zone of the face; an implanting to introduce at least one species comprising carbon into the substrate from the face of the substrate, the forming of the protective screen and the implanting being configured to form, in the substrate, at least one carbon modified layer having a concentration of implanted carbon greater than or equal to an etching threshold only from a second zone of the face of the substrate not protected by the protective screen; removing the protective screen; and etching the substrate from the first zone selectively with respect to the second zone.

A method of forming a semiconductor structure includes forming vertical fins comprising a first semiconductor layer, an isolation layer and a second semiconductor layer, the first and second semiconductor layers providing vertical transport channels for lower and upper vertical transport field-effect transistors (VTFETs) of a stacked VTFET structure. The method also includes forming a first gate stack for the lower VTFET surrounding a first portion of the first semiconductor layer of the vertical fins. The method further includes forming a second gate stack for the upper VTFET surrounding a second portion of the second semiconductor layer of the vertical fins. The first and second portions have different sizes such that the upper and lower VTFETs of the stacked VTFET structure have different effective gate widths.

A method of forming a semiconductor structure includes forming vertical fins comprising a first semiconductor layer, an isolation layer and a second semiconductor layer, the first and second semiconductor layers providing vertical transport channels for lower and upper vertical transport field-effect transistors (VTFETs) of a stacked VTFET structure. The method also includes forming a first gate stack for the lower VTFET surrounding a first portion of the first semiconductor layer of the vertical fins. The method further includes forming a second gate stack for the upper VTFET surrounding a second portion of the second semiconductor layer of the vertical fins. The first and second portions have different sizes such that the upper and lower VTFETs of the stacked VTFET structure have different effective gate widths.

In accordance with some embodiments of the present disclosure, a semiconductor structure and a fabricating method thereof are provided. The method for forming a semiconductor structure comprises: forming a base substrate; forming a gate structure on the base substrate; forming openings in the base substrate on both sides of the gate structure; forming a barrier layer on sidewalls of the openings adjacent to the gate structure; and forming a doped layer in the openings, and forming a source region or a drain region in the doped layer.

A method for forming reliefs on a face of a substrate is provided, successively including forming a protective screen for protecting at least a first zone of the face; an implanting to introduce at least one species comprising carbon into the substrate from the face of the substrate, the forming of the protective screen and the implanting being configured to form, in the substrate, at least one carbon modified layer having a concentration of implanted carbon greater than or equal to an etching threshold only from a second zone of the face of the substrate not protected by the protective screen; removing the protective screen; and etching the substrate from the first zone selectively with respect to the second zone.

A method includes kicking out impurity atoms from substitutional sites of a crystal lattice of a semiconductor body by implanting particles via a first surface into the semiconductor body, reducing a thickness of the semiconductor body by removing semiconductor material of the semiconductor body, and annealing the semiconductor body in a first annealing process at a temperature of between 300 C. and 450 C. to diffuse impurity atoms out of the semiconductor body.