Abstract: A method for forming a semiconductor structure by bonding a donor substrate to a carrier substrate is disclosed herein. The donor substrate may include a plurality of semiconductor layers epitaxially grown on top of one another in, and optionally above, a trench of the donor substrate. The carrier substrate may include a first semiconductor device thereon. The method may include removing at least part of the donor substrate in such a way as to expose a semiconductor layer grown on the bottom of the trench, removing at least part of the exposed semiconductor layer, thereby modifying the plurality of semiconductor layers, and forming a second semiconductor device from the modified plurality of semiconductor layers.

Abstract: A method for forming a semiconductor structure by bonding a donor substrate to a carrier substrate is disclosed herein. The donor substrate may include a plurality of semiconductor layers epitaxially grown on top of one another in, and optionally above, a trench of the donor substrate. The carrier substrate may include a first semiconductor device thereon. The method may include removing at least part of the donor substrate in such a way as to expose a semiconductor layer grown on the bottom of the trench, removing at least part of the exposed semiconductor layer, thereby modifying the plurality of semiconductor layers, and forming a second semiconductor device from the modified plurality of semiconductor layers.

Abstract: A method of producing a pre-patterned structure comprising at least one cavity for growing a vertical nanostructure is disclosed. The method includes providing at least one protruding structure that extends upwardly from a main surface of a substrate. The at least one protruding structure has a main portion of a first height and an upper portion on the main portion. The method also includes embedding the at least one protruding structure in a dielectric material. Further, the method includes removing at least an excess portion of the dielectric material, thereby exposing a top surface of the upper portion and forming a flattened surface of the top surface of the upper portion and the dielectric material. In addition, the method includes forming at least one cavity of a first depth by removing the upper portion, thereby exposing a top surface of the main portion of the at least one protruding structure.

Abstract: An example method includes providing a layer stack in a trench defined by adjacent STI structures and recessing the STI structures adjacent to the layer stack to thereby expose an upper portion of the layer stack, the upper portion comprising at least a channel portion. The method further includes providing one or more protection layers on the upper portion of the layer stack and then further recessing the STI structures selectively to the protection layers and the layer stack, to thereby expose a central portion of the layer stack. And the method includes removing the central portion of the layer stack, resulting in a freestanding upper part and a lower part of the layer stack being physically separated from each other.

Abstract: A Tunnel Field-Effect Transistor (TFET) device is provided comprising at least one heterosection between the source region and the channel region. The at least one heterosection has a low dielectric constant and thickness below 10 nm. Additionally a pocket region and another heterosection may be added in between the at least one heterosection and the channel region.

Abstract: An example method includes providing a layer stack in a trench defined by adjacent STI structures and recessing the STI structures adjacent to the layer stack to thereby expose an upper portion of the layer stack, the upper portion comprising at least a channel portion. The method further includes providing one or more protection layers on the upper portion of the layer stack and then further recessing the STI structures selectively to the protection layers and the layer stack, to thereby expose a central portion of the layer stack. And the method includes removing the central portion of the layer stack, resulting in a freestanding upper part and a lower part of the layer stack being physically separated from each other.

Abstract: A Tunnel Field-Effect Transistor (TFET) device is provided comprising at least one heterosection between the source region and the channel region. The at least one heterosection has a low dielectric constant and thickness below 10 nm. Additionally a pocket region and another heterosection may be added in between the at least one heterosection and the channel region.

Abstract: A method for manufacturing a transistor device is provided, comprising providing a plurality of parallel nanowires on a substrate; providing a dummy gate structure over a central portion of the parallel nanowires; epitaxially growing extension portions of a second material, selectively on the parallel nanowires, outside a central portion; providing a filler layer around and on top of the dummy gate structure and the extension portions; removing the dummy gate structure to create a gate trench, exposing the central portion of the parallel nanowires; providing spacer structures on the sidewalls of the gate trench, to define a final gate trench; thinning the parallel nanowires, thereby creating free space in between the nanowires and spacer structures; and selectively growing a quantum well layer on or around the parallel nanowires, at least partially filling the free space, to thereby provide a connection between the quantum well layer and extension portions.

Abstract: A Tunnel Field Effect Transistor device (TFET) made of at least following layers: a highly doped drain layer, a highly doped source layer, a channel layer, a gate dielectric layer and a gate electrode layer, the gate dielectric layer extending along the source layer, and a highly doped pocket layer extending in between and along the gate dielectric layer and the source layer, characterized in that the pocket layer extends to between and along the source layer and the channel layer.

Abstract: A method for manufacturing a transistor device is provided, comprising providing a plurality of parallel nanowires on a substrate; providing a dummy gate structure over a central portion of the parallel nanowires; epitaxially growing extension portions of a second material, selectively on the parallel nanowires, outside a central portion; providing a filler layer around and on top of the dummy gate structure and the extension portions; removing the dummy gate structure to create a gate trench, exposing the central portion of the parallel nanowires; providing spacer structures on the sidewalls of the gate trench, to define a final gate trench; thinning the parallel nanowires, thereby creating free space in between the nanowires and spacer structures; and selectively growing a quantum well layer on or around the parallel nanowires, at least partially filling the free space, to thereby provide a connection between the quantum well layer and extension portions.

Abstract: A Tunnel Field Effect Transistor device (TFET) made of at least following layers: a highly doped drain layer, a highly doped source layer, a channel layer, a gate dielectric layer and a gate electrode layer, the gate dielectric layer extending along the source layer, and a highly doped pocket layer extending in between and along the gate dielectric layer and the source layer, characterized in that the pocket layer extends to between and along the source layer and the channel layer.

Abstract: A tunnel transistor is provided including a drain, a source and at least a first gate for controlling current between the drain and the source, wherein the first sides of respectively the first and the second gate dielectric material are positioned substantially along and substantially contact respectively the first and the second semiconductor part.

Abstract: The present disclosure provides a method for manufacturing at least one nanowire Tunnel Field Effect Transistor (TFET) semiconductor device. The method comprises providing a stack comprising a layer of channel material with on top thereof a layer of sacrificial material, removing material from the stack so as to form at least one nanowire from the layer of channel material and the layer of sacrificial material, and replacing the sacrificial material in the at least one nanowire by heterojunction material. A method according to embodiments of the present disclosure is advantageous as it enables easy manufacturing of complementary TFETs.

Abstract: A tunnel transistor is provided comprising a drain, a source and at least a first gate for controlling current between the drain and the source, wherein the first sides of respectively the first and the second gate dielectric material are positioned substantially along and substantially contact respectively the first and the second semiconductor part.

Abstract: The present disclosure provides a method for manufacturing at least one nanowire Tunnel Field Effect Transistor (TFET) semiconductor device. The method comprises providing a stack comprising a layer of channel material with on top thereof a layer of sacrificial material, removing material from the stack so as to form at least one nanowire from the layer of channel material and the layer of sacrificial material, and replacing the sacrificial material in the at least one nanowire by heterojunction material. A method according to embodiments of the present disclosure is advantageous as it enables easy manufacturing of complementary TFETs.

Abstract: A method for fabricating a semiconductor device and the device made thereof are disclosed. In one aspect, the method includes providing a substrate comprising a semiconductor material. The method further includes patterning at least one fin in the substrate, the fin comprising a top surface, at least one sidewall surface, and at least one corner. A supersaturation of point defects is created in the at least one fin. The at least one fin is annealed and then cooled down such that semiconductor atoms of the semiconductor material migrate via the point defects.

Abstract: One inventive aspect relates to a method of selective epitaxial growth of source/drain (S/D) areas. The method includes providing a substrate having a first and a second substrate area, the first area including at least one gate stack. The method includes applying a poly-Si or poly-SiGe top layer on the substrate, the top layer being etchable with the same etch chemistry as the substrate. The method includes removing the poly-Si or poly-SiGe top layer from the first area selectively towards the poly-Si or poly-SiGe top layer in the second area. The method includes removing simultaneously the poly-Si or poly-SiGe top layer on the second area and at least a part of the substrate in the S/D areas of the first area selectively to the gate stack. The method includes performing a selective epitaxial growth of S/D areas in the first area.

Abstract: A method for forming at least one quantum dot at at least one predetermined location on a substrate is disclosed. In one aspect, the method comprises providing a layer of semiconductor material on an insulating layer on the substrate. The layer of semiconductor material is patterned so as to provide at least one line of semiconductor material having a width (wL) and having a local width variation at at least one predetermined location where the at least one quantum dot has to be formed. The local width variation has an amplitude (A) of between about 20 nm and 35 nm higher than the width wL of the at least one line. The at least one line is patterned to form at least one quantum dot. A design for a lithographic mask for use with the method and a method for making such a design are also disclosed.

Abstract: A method for fabricating a semiconductor device and the device made thereof are disclosed. In one aspect, the method includes providing a substrate comprising a semiconductor material. The method further includes patterning at least one fin in the substrate, the fin comprising a top surface, at least one sidewall surface, and at least one corner. A supersaturation of point defects is created in the at least one fin. The at least one fin is annealed and then cooled down such that semiconductor atoms of the semiconductor material migrate via the point defects.

Abstract: A method for forming at least one quantum dot at least one predetermined location on a substrate is disclosed. In one aspect, the method comprises providing a layer of semiconductor material on an insulating layer on the substrate. The layer of semiconductor material is patterned so as to provide at least one line of semiconductor material having a width (wL) and having a local width variation at least one predetermined location where the at least one quantum dot has to be formed. The local width variation has an amplitude (A) of between about 20 nm and 35 nm higher than the width wL of the at least one line. The at least one line is patterned to form at least one quantum dot. A design for a lithographic mask for use with the method and a method for making such a design are also disclosed.