Abstract: The present invention provides a semiconductor structure and a method for manufacturing the same. The method comprises: providing a substrate, forming sequentially a first high-k dielectric layer, an adjusting layer, a second high-k dielectric layer and a metal gate on the substrate, etching the first high-k dielectric layer, the adjusting layer, the second high-k dielectric layer and the metal gate to form a gate stack. Accordingly, the present invention further provides a semiconductor structure. The present invention proposes to arrange an adjusting layer between two layers of high-k dielectric layer, which effectively avoids reaction of the adjusting layer with the metal gate because of their direct contact, so as to maintain the performance of semiconductor devices.

Abstract: The present invention provides a semiconductor structure and a method for manufacturing the same. The method comprises the following steps: providing a semiconductor substrate, forming sequentially a gate dielectric layer, a metal gate, a CMP stop layer, and a poly silicon layer on the semiconductor substrate; etching the gate dielectric layer, the metal gate, the CMP stop layer and the poly silicon layer to form a gate stack; forming a first interlayer dielectric layer on the semiconductor substrate to cover the gate stack on the semiconductor substrate and the portions on both sides of the gate stack; performing a planarization process, such that the CMP stop layer is exposed and flushed with the upper surface of the first interlayer dielectric layer. Accordingly, the present invention further provides a semiconductor structure.

Abstract: The present invention relates to a method of manufacturing a semiconductor device, wherein the method comprises: providing a substrate; forming a source region, a drain region, a dummy gate structure, and a gate dielectric layer on the substrate, wherein the dummy gate structure is between the source region and the drain region on the substrate, and the gate dielectric layer is between the substrate and the dummy gate structure; annealing the source region and the drain region; removing the dummy gate structure to form an opening; implanting dopants into the substrate from the opening to form a steep retrograded well; annealing to activate the dopants; and forming a metal gate on the gate dielectric layer by deposition.

Abstract: The present disclosure relates to the microelectronics field, and particularly, to a metal oxide resistive switching memory and a method for manufacturing the same. The method may comprise: forming a W-plug lower electrode above a MOS device; sequentially forming a cap layer, a first dielectric layer, and an etching block layer on the W-plug lower electrode; etching the etching block layer, the first dielectric layer, and the cap layer to form a groove for a first level of metal wiring; sequentially forming a metal oxide layer, an upper electrode layer, and a composite layer of a diffusion block layer/a seed copper layer/a plated copper layer in the groove for the first level of metal wiring; patterning the upper electrode layer and the composite layer by CMP, to form a memory cell and the first level of metal wiring in the groove in the first dielectric layer; and performing subsequent processes to complete the metal oxide resistive switching memory.

Abstract: An embodiment of the present invention discloses a method for manufacturing a FinFET, when a fin is formed, a dummy gate across the fin is formed on the fin, a source/drain opening is formed in both the cover layer and the first dielectric layer at both sides of the dummy gate, the source/drain opening is at both sides of the fin covered by the dummy gate and is an opening region surrounded by the cover layer and the first dielectric layer around it. In the formation of a source/drain region in the source/drain opening, stress is generated due to lattice mismatching, and applied to the channel due to the limitation by the source/drain opening in the first dielectric layer, thereby increasing the carrier mobility of the device, and improving the performance of the device.

Abstract: A method for manufacturing a semiconductor device includes the steps of: forming a first gate stack on a semiconductor substrate, the first gate stack includes a first gate conductor and a first gate dielectric between the first gate conductor and the semiconductor substrate; forming source/drain regions on the semiconductor substrate; forming a multilayer structure including at least one sacrificial layer and at least one insulating layer under the sacrificial layer on the semiconductor substrate and the first gate stack; performing a first RIE on the multilayer structure; performing a second RIE on the multilayer structure; selectively etching the first gate stack with respect to the insulating layer, in which the first gate conductor is removed and an opening is formed in the insulating layer; and forming a second gate conductor in the opening.

Abstract: The present application provides a method for manufacturing a semiconductor structure, which comprises following steps: providing a substrate; forming a gate dielectric layer on the substrate; forming a dummy gate structure on the gate dielectric layer, wherein the dummy gate is formed from a polymer material; implanting dopants into portions of the substrates on opposite sides of the dummy gate structure to form source/drain regions; removing the dummy gate; annealing the source/drain regions to activate the dopants; and forming a metal gate. According to the present invention, it is proposed to manufacture a dummy gate structure with a polymer material, which significantly simplifies the subsequent etching process for removing the dummy gate structure and alleviates the etching difficulty accordingly.

Abstract: The present application discloses a device performance prediction method and a device structure optimization method. According to an embodiment of the present invention, a set of structural parameters and/or process parameters for a semiconductor device constitutes a parameter point in a parameter space, and a behavioral model library is established with respect to a plurality of discrete predetermined parameter points in the parameter space, and the predetermined parameter points being associated with their respective performance indicator values in the behavioral model library.

Abstract: The present invention discloses a flash memory device. The flash memory device comprises a semiconductor substrate and a flash memory area located on the semiconductor substrate. The flash memory area comprises a first doped well, which is divided into a first region and a second region by an isolation region, the second region being doped with an impurity having an electrical conductivity opposite to that of the first doped well; a high-k gate dielectric layer located on the first doped well; and a metal layer located on the high-k gate dielectric layer. The present invention enables compatibility between the high-k dielectric metal gate and the erasable flash memory and increases the operation performance of the flash memory. The present invention also provides a manufacturing method of the flash memory device, which greatly increases the production efficiency and yield of flash memory devices.

Abstract: The present invention relates to a semiconductor device and a method for manufacturing the same. According to the present invention, when a gate is formed via a replacement gate process, a portion of a work function metal layer and a portion of a first metal layer are removed after the work function metal layer and the first metal layer are formed, and then the removed portions are replaced with a second metal layer. A device having such a gate structure greatly reduces the resistivity of the whole gate, due to a portion of the work function metal layer with a high resistivity being removed and the removed portion being filled with the second metal layer with a low resistivity, thereby AC performances of the device are improved.

Abstract: A method of adjusting a metal gate work function of an NMOS device comprises: depositing a layer of metal nitride film or metal film on a high K dielectric as a metal gate electrode by a physical vapor deposition process; implanting elements such as Tb, Er, Yb or Sr into the metal gate electrode by an ion implantation process; performing a high temperature annealing so that the doped metal ions are driven to and accumulate on the interface between the metal gate electrode and the high K gate dielectric, or form dipoles by an interface reaction on the interface between the high K gate dielectric and SiO2. The method is capable of adjusting the metal gate work function, and is well-compatible with CMOS process.

Abstract: A semiconductor device is provided. A multi-component high-k interface layer containing elements of the substrate is formed from an ultra-thin high-k dielectric material in a single-layer structure of atoms by rapid annealing in the manufacturing of a CMOS transistor by the replacement gate process, and a high-k gate dielectric layer with a higher dielectric constant and a metal gate layer are formed thereon. The EOT of the device is effectively decreased, and the diffusion of atoms in the high-k gate dielectric layer from an upper level thereof is effectively prevented by the optimized high-k interface layer at high-temperature treatment.

Abstract: The invention relates to a method for forming a semiconductor structure, comprising: providing a semiconductor substrate which comprises a dummy gate formed thereon, a spacer surrounding the dummy gate, source and drain regions formed on two sides of the dummy gate, respectively, and a channel region formed in the semiconductor substrate and below the dummy gate; removing the dummy gate to form a gate opening; forming a stressed material layer in the gate opening; performing an annealing to the semiconductor substrate, the stressed material layer having tensile stress characteristics during the annealing; removing the stressed material layer in the gate opening; and forming a gate in the gate opening. By the above steps, the stress memorization technique can be applied to the pMOSFET.

Abstract: The present application discloses a method for manufacturing a semiconductor structure, comprising the steps of: a) providing an n-type field effect transistor comprising a source region, a drain region, and a first gate; b) forming a tensile stress layer on the n-type field effect transistor; c) removing the first gate so as to form a gate opening; d) performing an anneal so that the source region and the drain region memorize a stress induced by the tensile stress layer; e) forming a second gate; f) removing the tensile stress layer; and b) forming an interlayer dielectric layer on the n-type field effect transistor. The present method incorporates a replacement process and a stress memorization technique, which enhances the stress memorization effect and thus mobility of electrons, which in turn improves overall properties of the semiconductor structure.

Abstract: A method for improving the efficiency of the electron-beam exposure is provided, comprising: step 1) coating a positive photoresist on a wafer to be processed, and performing a pre-baking; step 2) separating pattern data, optically exposing a group of relatively large patterns, and then performing a post-baking; step 3) developing the positive photoresist; step 4) performing a plasma fluorination; step 5) performing a baking to solidify the photoresist; step 6) coating a negative electron-beam resist and performing a pre-baking; step 7) electron-beam exposing a group of fine patterns; step 8) performing a post-baking; and step 9) developing the negative electron-beam resist, so that the fabrication of the patterns is finished. According to the invention, it is possible to save 30-60% of the exposure time. Thus, the exposure efficiency is significantly improved, and the cost is greatly reduced. Further, the method is totally compatible with the CMOS processes, without the need of any special equipments.

Abstract: The invention provides a method for forming a contact plug, comprising: forming a gate, a sidewall spacer, a sacrificial sidewall spacer, a source region and a drain region on a substrate, wherein the sidewall spacer is formed around the gate, the sacrificial sidewall spacer is formed over the sidewall spacer, and the source region and the drain region are formed within the substrate and on respective sides of the gate; forming an interlayer dielectric layer, with the gate, the sidewall spacer and the sacrificial sidewall spacer being exposed; removing the sacrificial sidewall spacer to form a contact space, the sacrificial sidewall spacer material being different from that of the gate, the sidewall spacer and the interlayer dielectric layer; forming a conducting layer to fill the contact space; and cutting off the conducting layer, to form at least two conductors connected to the source region and the drain region respectively.

Abstract: A chemical-mechanical polishing tool and a method for preheating the same are disclosed. The chemical-mechanical polishing tool includes: a polishing pad, a deionized water supply channel, a polishing slurry supply channel and a polishing pad conditioner; and the chemical-mechanical polishing tool further includes: a heating apparatus, adapted to heat DI water fed to the DI water supply channel; a temperature sensor, arranged close to the polishing pad to measure a temperature of the polishing pad; and a preheating control system, connected to the temperature sensor, and adapted to control the DI water supply channel to spray the heated DI water to the polishing pad, and when the temperature measured by the temperature sensor is equal to or higher than a predetermined temperature, to close the DI water supply channel, control the polishing slurry supply channel to spray polishing slurry to the polishing pad, and startup the polishing pad conditioner to dress the polishing pad.

Abstract: A method for manufacturing a semiconductor structure comprises: providing a substrate, forming an active region on the substrate, forming a gate stack or a dummy gate stack on the active region, forming a source extension region and a drain extension region at opposite sides of the gate stack or dummy gate stack, forming a spacer on sidewalls of the gate stack or dummy gate stack, and forming a source and a drain on portions of the active region exposed by the spacer and the gate stack or dummy gate stack; removing at least a part of a source-side portion of the spacer, such that the source-side portion of the spacer has a thickness less than that of a drain-side portion of the spacer; and forming a contact layer on portions of the active region exposed by the spacer and the gate stack or dummy gate stack. Correspondingly, the present invention further provides a semiconductor structure.

Abstract: The present invention provides a semiconductor structure with a stressed layer in the channel and method for forming the same. The semiconductor structure comprises a substrate; a gate stack, including a gate dielectric layer formed over the substrate, gate layer formed over the gate dielectric layer, a source region and a drain region formed in the substrate by both sides of the gate stack; one or more spacers formed on both sides of the gate stack; and an embedded stressed layer formed under the gate stack in the substrate. In the embodiments of the present invention, the carrier mobility can be effectively increased by the embedded stressed layer added in the channel under the gate stack, so that the driving current of transistors is improved. Moreover, the technological process for forming this embedded stressed layer in the present invention has a lower thermal budget, which therefore assists in maintaining a higher stress level in the channel region.

Abstract: The invention provides a STI structure and a method for manufacturing the same. The STI includes a semiconductor substrate; a first trench formed on the upper surface of the semiconductor substrate and filled with an epitaxial layer, wherein the upper surface of the epitaxial layer is higher than that of the semiconductor substrate; and a second trench formed on the epitaxial layer and filled with a first dielectric layer, wherein the upper surface of the first dielectric layer is flush with that of the epitaxial layer, and the width of the second trench is smaller than that of the first trench. The invention reduces the influences of divots on performance of the semiconductor device.