Abstract: A MOSFET with a graphene nano-ribbon, and a method for manufacturing the same are provided. The MOSFET comprises an insulating substrate; and an oxide protection layer on the insulating substrate. At least one graphene nano-ribbon is embedded in the oxide protection layer and has a surface which is exposed at a side surface of the oxide protection layer. A channel region is provided in each of the at least one graphene nano-ribbon. A source region and a drain regions are provided in each of the at least one graphene nano-ribbon. The channel region is located between the source region and the drain region. A gate dielectric is positioned on the at least one graphene nano-ribbon. A gate conductor on the gate dielectric. A source and drain contacts contact the source region and the drain region respectively on the side surface of the oxide protection layer.

Abstract: The present invention provides a method for manufacturing a semiconductor device, comprising: forming a contact sacrificial pattern on a substrate to cover source and drain regions and expose a gate region; forming an interlayer dielectric layer on the substrate to cover the contact sacrificial pattern and expose the gate region; forming a gate stack structure in the exposed gate region; removing the contact sacrificial pattern to form the source/drain contact trench; and forming a source/drain contact in the source/drain contact trench. By means of a contact sacrificial layer process, the method of manufacturing a semiconductor device according to the present invention effectively reduces the distance between the gate spacer and the contact region and increases the area of the contact region, thus effectively reducing the parasitic resistance of the device.

Abstract: An isolation region is provided. The isolation region includes a first groove and an insulation layer filling the first groove. The first groove is embedded into a semiconductor substrate and includes a first sidewall, a bottom surface and a second sidewall that extends from the bottom surface and joins to the first sidewall. An angle between the first sidewall and a normal line of the semiconductor substrate is larger than a standard value. A method for forming an isolation region is further provided. The method includes: forming a first trench on a semiconductor substrate, wherein an angle between a sidewall of the first trench and a normal line of the semiconductor substrate is larger than a standard value; forming a mask on the sidewall to form a second trench on the semiconductor substrate by using the mask; and forming an insulation layer to fill the first and second trenches. A semiconductor device and a method for forming the same are still further provided.

Abstract: The present invention provides a method for manufacturing a semiconductor structure, comprising the steps of: providing a semiconductor substrate, forming an insulating layer on the semiconductor substrate, and forming a semiconductor base layer on the insulating layer; forming a sacrificial layer and a spacer surrounding the sacrificial layer on the semiconductor base layer, and etching the semiconductor base layer by taking the spacer as a mask to form a semiconductor body; forming a dielectric film on sidewalls of the semiconductor body; removing the sacrificial layer and the semiconductor body located under the sacrificial layer to form a first semiconductor fin and a second semiconductor fin; and forming a retrograde doped well structure on the inner walls of the first semiconductor fin and the second semiconductor fin, wherein the inner walls thereof are opposite to each other. Correspondingly, the present invention further provides a semiconductor structure.

Abstract: A method for manufacturing a semiconductor device, comprising: forming a gate stack structure and gate spacers on the substrate; forming the raised S/D regions on the substrate on both sides of the gate stack structure and the gate spacers; depositing a lower interlayer dielectric layer on the entire device, and planarizing the lower interlayer dielectric layer and the gate stack structure until the raised S/D regions are exposed; selective epitaxial growing to form the S/D extension regions in the raised S/D regions; forming an upper interlayer dielectric layer on the S/D extension regions; etching the upper interlayer dielectric layer until the S/D extension regions to form an S/D contact hole; forming a metal silicide in the S/D contact hole.

Abstract: The present invention discloses a semiconductor structure and a method for manufacturing the same, which comprises providing a substrate, and forming a stress layer, a buried oxide layer, and an SOI layer on the substrate; forming a doped region of the stress layer arranged in a specific position in the stress layer; forming an oxide layer and a nitride layer on the SOI layer, and forming a first trench that etches the nitride layer, the oxide layer, the SOI layer, and the buried oxide layer, and stops on the upper surface of the stress layer, and exposes at least part of the doped region of the stress layer; forming a cavity by wet etching through the first trench to remove the doped region of the stress layer; forming a polycrystalline silicon region of the stress layer and a second trench by filling the cavity with polycrystalline silicon and etching back; forming an isolation region by filling the second trench.

Abstract: The present disclosure provides a method for manufacturing a three-dimensional semiconductor memory device. In the method, a storage array is divided into a plurality of storage sub-arrays. As a result, a respective via of each storage sub-array can be etched respectively, which is different from the prior art, where a via for a bottom electrode of a plurality of layers of resistive cells is etched at one time. The vias are filled with metal so that storage sub-arrays are connected with each other. The method for manufacturing the three-dimensional semiconductor memory device according to the present disclosure can substantially reduce process complexity and difficulty of etching process in high-density integration, and also improve a number of layers of the resistive cells integrated in the storage array.

Abstract: A semiconductor device structure, a method for manufacturing the same, and a method for manufacturing a semiconductor fin are disclosed. In one embodiment, the method for manufacturing the semiconductor device structure comprises: forming a fin in a first direction on a semiconductor substrate; forming a gate line in a second direction, the second direction crossing the first direction on the semiconductor substrate, and the gate line intersecting the fin with a gate dielectric layer sandwiched between the gate line and the fin; forming a dielectric spacer surrounding the gate line; and performing inter-device electrical isolation at a predetermined position, wherein isolated portions of the gate line form independent gate electrodes of respective devices.

Abstract: The present invention relates to a shallow trench isolation structure, manufacturing method thereof and a device based on the structure. The present invention provides a method for manufacturing a shallow trench isolation (STI) structure, characterized in comprising the following steps: providing a semiconductor substrate; forming an insulating medium on said semiconductor substrate; etching a part of the insulating medium by using a mask to expose the semiconductor substrate thereunder, the unetched insulating medium forming STI regions; and epitaxially growing a semiconductor layer on said semiconductor substrate between said STI regions as an active region. With the method provided by the present invention, the problem of filling a small-size trench is solved and the problem of STI step height is overcome.

Abstract: Semiconductor devices and methods for manufacturing the same are disclosed. In one embodiment, a method includes forming a first shielding layer on a substrate. The method further includes forming one of source and drain regions, which is stressed, with the first shielding layer as a mask. The method further includes forming a second shielding layer on the substrate, and forming the other of the source and drain regions with the second shielding layer as a mask. The method further includes removing a portion of the second shielding layer which is next to the other of the source and drain regions. The method further includes forming a gate dielectric layer, and forming a gate conductor as a spacer on a sidewall of a remaining portion of the second shielding layer.

Abstract: The present invention discloses a semiconductor device. In one embodiment, the semiconductor device comprises a substrate, a diffusion stop layer formed on the substrate, an SOI layer formed on the diffusion stop layer, an MOSFET transistor formed on the SOI layer, and a TSV formed in a manner of penetrating through the substrate, the diffusion stop layer, the SOI layer, and a layer where the MOSFET transistor is located; and an interconnect structure connecting the MOSFET transistor and the TSV.

Abstract: The present application discloses a method for manufacturing a semiconductor device, comprising: forming a gate stack structure and gate sidewall spacers on the substrate, and forming a source region and a drain region on the substrate on opposite sides of the gate stack structure and the gate sidewall spacers, respectively; selectively forming a block layer in the drain region, wherein the block layer covers the drain region and exposes the source region; epitaxially forming an raised source region in the exposed source region; removing the block layer. According to the semiconductor device manufacturing method in the present disclosure, by selectively forming an raised source region in the source region side to form an asymmetric device structure, the parasitic resistance on the source region side and the parasitic capacitance on the drain region side are pertinently reduced and the device performance is effectively improved.

Abstract: The present disclosure provides a semiconductor device and a method for manufacturing the same.

Abstract: The present invention discloses a method for manufacturing a semiconductor device, which comprises: forming a plurality of fins on a substrate, which extend along a first direction and have rhombus-like cross-sections; forming a gate stack structure on each fin, which traverses the plurality of fins and extends along a second direction; wherein a portion in each fin that is under the gate stack structure forms a channel region of the device, and portions in each fin that are at both sides of the gate stack structure along the first direction form source and drain regions. The semiconductor device and its manufacturing method according to the present invention use rhombus-like fins to improve the gate control capability to effectively suppress the short channel effect, moreover, an epitaxial quantum well is used therein to better limit the carriers, thus improving the device drive capability.

Abstract: This invention discloses a CMOS device, which includes: a first MOSFET; a second MOSFET different from the type of the first MOSFET; a first stressed layer covering the first MOSFET and having a first stress; and a second stressed layer covering the second MOSFET, wherein the second stressed layer is doped with ions, and thus has a second stress different from the first stress. This invention's CMOS device and method for manufacturing the same make use of a partitioned ion implantation method to realize a dual stress liner, without the need of removing the tensile stressed layer on the PMOS region or the compressive stressed layer on the NMOS region by photolithography/etching, thus simplifying the process and reducing the cost, and at the same time, preventing the stress in the liner on the NMOS region or PMOS region from the damage that might be caused by the thermal process of the deposition process.

Abstract: The present invention relates to substrates for ICs and method for forming the same. The method comprises the steps of: forming a hard mask layer on the bulk silicon material; etching the hard mask layer and the bulk silicon material to form a first part for shallow trench isolation of at least one trench; forming a dielectric film on the sidewall of the at least one trench; further etching the bulk silicon material to deepen the at least one trench so as to form a second part of the at least one trench; completely oxidizing or nitridizing parts of the bulk silicon material which are between the second parts of the trenches, and parts of the bulk silicon material which are between the second parts of the trenches and side surfaces of the bulk silicon substrate; filling dielectric materials in the first and second parts of the at least one trench; and removing the hard mask layer.

Abstract: Disclosed is a read timing generation circuit, capable of reducing dynamic power consumption. After a multi-bit address Add1, Add2, . . . , and AddN passes through an address change monitoring unit (100), a response pulse signal corresponding the address is generated. After the response pulse signal passes through an address trigger determination unit (200), a single trigger determination signal ATDPRE is generated. The single trigger determination signal ATDPRE passes through an ATD timing generation unit (300) and a post-timing generation unit (1000), thereby forming a read timing generation circuit in a serial link and generating corresponding read timing. Compared with the conventional read timing generation circuit in which each bit of an address signal corresponds to a stage of structures to execute the trigger, ATD control timing output, and ATD determination process separately, the present invention greatly reduces the total dynamic power consumption of the circuit.

Abstract: The present invention provides a method for manufacturing a semiconductor structure, which comprises following steps: providing a substrate, which comprises upwards in order a base layer, a buried isolation layer, a buried ground layer, an ultra-thin insulating buried layer and a surface active layer; implementing ion implantation doping to the buried ground layer; forming a gate stack, sidewall spacers and source/drain regions on the substrate; forming a mask layer on the substrate that covers the gate stack and the source/drain regions, and etching the mask layer to expose the source region; etching the source region and the ultra-thin insulating buried layer under the source region to form an opening that exposes the buried ground layer; filling the opening through epitaxial process to form a contact plug for the buried ground layer. Accordingly, the present invention further provides a semiconductor structure.

Abstract: The present disclosure provides a device and method for storing encoded and/or decoded codes by re-using an encoder. The device and method for storing the encoded and/or decoded codes according to the present disclosure enables re-use of the encoder during a decoding process, which makes it unnecessary to use additional hardware and thereby reduces an area consumed by an EDAC (error detection and correction) decoder.

Abstract: The present disclosure discloses a method for manufacturing an N-type MOSFET, comprising: forming a part of the MOSFET on a semiconductor substrate, the part of the MOSFET comprising source/drain regions in the semiconductor substrate, a replacement gate stack between the source/drain regions above the semiconductor substrate, and a gate spacer surrounding the replacement gate stack; removing the replacement gate stack of the MOSFET to form a gate opening exposing a surface of the semiconductor substrate; forming an interface oxide layer on the exposed surface of the semiconductor; forming a high-K gate dielectric layer on the interface oxide layer in the gate opening; forming a first metal gate layer on the high-K gate dielectric layer; implanting dopant ions into the first metal gate layer; and performing annealing to cause the dopant ions to diffuse and accumulate at an upper interface between the high-K gate dielectric layer and the first metal gate layer and a lower interface between the high-K gate diel