A method for forming a semiconductor structure is provided. The method includes forming a fin structure over a substrate and forming an isolation structure over the substrate. In addition, the fin structure is protruded from the isolation structure. The method further includes trimming the fin structure to a first width and forming a Ge-containing material covering the fin structure. The method further includes annealing the fin structure and the Ge-containing material to form a modified fin structure. The method also includes trimming the modified fin structure to a second width.

A number of monolithic diode limiter semiconductor structures are described. The diode limiters can include a hybrid arrangement of diodes with different intrinsic regions, all formed over the same semiconductor substrate. In one example, a method of manufacture of a monolithic diode limiter includes providing an N-type semiconductor substrate, providing an intrinsic layer on the N-type semiconductor substrate, implanting a first P-type region to a first depth into the intrinsic layer, implanting a second P-type region to a second depth into the intrinsic layer, and forming at least one passive circuit element over the intrinsic layer. The method can also include forming an insulating layer on the intrinsic layer, forming a first opening in the insulating layer, and forming a second opening in the insulating layer. The method can also include implanting the first P-type region through the first opening and implanting the second P-type region through the second opening.

A laminate that can be used for diffusing an impurity diffusion component into a semiconductor substrate and manufactured by a method with good film formability, and which allows sufficient diffusion of the impurity diffusion component; a method for manufacturing the laminate; and a method for manufacturing a semiconductor substrate using the laminate. The laminate includes a diffusion-undergoing semiconductor substrate, an amine compound layer, and an impurity diffusion component layer, the amine compound layer is in contact with one main surface of the diffusion-undergoing semiconductor substrate, the impurity diffusion component layer is in contact with a main surface of the amine compound layer, the main surface is not in contact with the diffusion-undergoing semiconductor substrate, and the amine compound layer includes an amine compound including two or more nitrogen atoms and having an amino group constituted by at least one of the two or more nitrogen atoms; and/or an amine compound residue having one or more amino groups and bonding to the main surface via a covalent bond.

A method of processing a substrate that includes: loading the substrate in a processing chamber, the substrate including a raised feature of a semiconductor; forming a conformal dopant layer on the raised feature by atomic layer deposition (ALD); forming a metal layer over the raised feature; thermally treating the dopant layer to form an ultra-shallow dopant region in the raised feature by diffusion of a dopant from the dopant layer into the raised feature; and thermally treating the metal layer to form an ohmic contact region in the raised feature by diffusion of a metal from the metal layer into the raised feature.

The present disclosure provides a semiconductor device and a manufacturing method thereof, and an electronic device including the semiconductor device. The semiconductor device includes: a substrate; an active region including a first source/drain region, a channel region and a second source/drain region stacked sequentially on the substrate and adjacent to each other; a gate stack formed around an outer periphery of the channel region; and spacers formed around the outer periphery of the channel region, respectively between the gate stack and the first source/drain region and between the gate stack and the second source/drain region; wherein the spacers each have a thickness varying in a direction parallel to a top surface of the substrate.

The present invention relates to a method for assembling molecules on the surface of a two-dimensional material formed on a substrate, the method comprises: forming a spacer layer comprising at least one of an electrically insulating compound or a semiconductor compound on the surface of the two-dimensional material, depositing molecules on the spacer layer, annealing the substrate with spacer layer and the molecules at an elevated temperature for an annealing time duration, wherein the temperature and annealing time are such that at least a portion of the molecules are allowed to diffuse through the spacer layer towards the surface of the two-dimensional material to assemble on the surface of the two-dimensional material. The invention also relates to an electronic device.

A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate. In the method, sacrificial spacer layers are formed on the plurality of fins, and portions of the semiconductor substrate located under the sacrificial spacer layers and located at sides of the plurality of fins are removed. Bottom source/drain regions are grown in at least part of an area where the portions of the semiconductor substrate were removed, and sacrificial epitaxial layers are grown on the bottom source/drain regions. The method also includes diffusing dopants from the bottom source/drain regions and the sacrificial epitaxial layers into portions of the semiconductor substrate under the plurality of fins. The sacrificial epitaxial layers are removed, and bottom spacers are formed in at least part of an area where the sacrificial epitaxial layers were removed.

The present disclosure provides a semiconductor device and a manufacturing method thereof, and an electronic device including the semiconductor device. The method includes: forming a first material layer and a second material layer sequentially on a substrate; defining an active region of the semiconductor device on the substrate, the first material layer and the second material layer, wherein the active region includes a channel region; forming spacers around an outer periphery of the channel region, respectively at set positions of the substrate and the second material layer; forming a first source/drain region and a second source/drain region on the substrate and the second material layer respectively; and forming a gate stack around the outer periphery of the channel region; wherein the spacers each have a thickness varying in a direction perpendicular to a direction from the first source/drain region pointing to the second source/drain region.

An embodiment of the present the disclosure provides a memory device, including: a substrate, an interconnection structure disposed on the substrate, a conductive layer disposed on the interconnection structure, a stop layer disposed on the conductive layer, and a gate stack structure disposed on the stop layer. The gate stack structure includes a plurality of insulating layers and a plurality of gate conductive layers that alternate with each other. A ratio of a thickness of a bottommost insulating layer of the gate stack structure to a thickness of the stop layer is 1:1 to 1:2. The memory device further includes a channel pillar extending through the gate stack structure and the stop layer and to electrically connect the conductive layer, and a charge storage structure disposed between sidewalls of the channel pillar and the plurality of gate conductive layers.

An apparatus including a circuit structure including a device stratum including a plurality of devices including a first side and an opposite second side; and a metal interconnect coupled to at least one of the plurality of devices from the second side of the device stratum. A method including forming a transistor device including a channel between a source region and a drain region and a gate electrode on the channel defining a first side of the device; and forming an interconnect to one of the source region and the drain region from a second side of the device.