Abstract: In one embodiment, a SRAM cell may include a substrate and a first Fin Field Effect Transistor (FinFET) and a second FinFET formed on the substrate. The first FinFET may include a first fin which is formed in a semiconductor layer provided on the substrate and abuts the semiconductor layer, and the second FinFET may include a second fin which is formed in the semiconductor layer and abuts the semiconductor layer. The semiconductor layer may include a plurality of semiconductor sub-layers. The first and second fins can include different number of the semiconductor sub-layers and have different heights from each other.

Abstract: The present invention provides a method for manufacturing a semiconductor structure, which comprises: a) forming gate lines extending in a direction on a substrate; b) forming a photoresist layer that covers the semiconductor structure; patterning the photoresist layer to form openings across the gate lines; c) narrowing the openings by forming a self-assembly copolymer inside the openings; and d) cutting the gate lines via the openings to make the gate lines insulated at the openings. Through forming an additional layer on the inner wall of the openings of the photoresist layer, the method for manufacturing a semiconductor structure provided by the present invention manages to reduce the distance between the two opposite walls of the openings in the direction of gate width, namely, the method manages to reduce the distance between the ends of electrically isolated gates located on the same line where it is unnecessary to manufacture a cut mask whose lines are extremely fine.

Abstract: A MOSFET structure and a method for manufacturing the same are disclosed. The method comprises: a. providing a substrate (100); b. forming a silicon germanium channel layer (101), a dummy gate structure (200) and a sacrificial spacer (102); c. removing the silicon germanium channel layer and portions of the substrate which are not covered by the dummy gate structure (200) and located under both sides of the dummy gate structure 200, so as to form vacancies (201); d. selectively epitaxially growing a first semiconductor layer (300) on the semiconductor structure to fill bottom and sidewalls of the vacancies (201); and e. removing the sacrificial spacer (102) and filling a second semiconductor layer (400) in the vacancies which are not filled by the first semiconductor layer (300). In the semiconductor structure of the present disclosure, carrier mobility in the channel can be increased, negative effects induced by the short channel effects can be suppressed, and device performance can be enhanced.

Abstract: A FinFET device and a method for manufacturing the same. The FinFET device includes a plurality of fins each extending in a first direction on a substrate; a plurality of gate stacks each being disposed astride the plurality of fins and extending in a second direction; a plurality of source/drain region pairs, respective source/drain regions of each source/drain region pair being disposed on opposite sides of the each gate stack in the second direction; and a plurality of channel regions each comprising a portion of a corresponding fin between the respective source/drain regions of a corresponding source/drain pair, wherein the each fin comprises a plurality of protruding cells on opposite side surfaces in the second direction.

Abstract: A method for manufacturing a semiconductor device is provided. The method includes forming, on a substrate, a plurality of fins extending along a first direction; forming, on the fins, a dummy gate stack extending along a second direction; forming a gate spacer on opposite sides of the dummy gate stack in the first direction; epitaxially growing raised source/drain regions on the top of the fins on opposite sides of the gate spacer in the first direction; performing lightly-doping ion implantation through the raised source/drain regions with the gate spacer as a mask, to form source/drain extension regions in the fins on opposite sides of the gate spacer in the first direction; removing the dummy gate stack to form a gate trench; and forming a gate stack in the gate trench.

Abstract: There is provided a method of manufacturing a Fin Field Effect Transistor (FinFET). The method may include: forming a fin on a semiconductor substrate; forming a dummy device including a dummy gate on the fin; forming an interlayer dielectric layer to cover regions except for the dummy gate; removing the dummy gate to form an opening; implanting ions to form a Punch-Though-Stop Layer (PTSL) in a portion of the fin directly under the opening, while forming reflection doped layers in portions of the fin on inner sides of source/drain regions; and forming a replacement gate in the opening.

Abstract: The present invention provides a method for manufacturing a semiconductor structure, comprising: a) forming metal interconnect liners on a substrate; b) forming a mask layer to cover the metal interconnect liners and forming openings, which expose the metal interconnect liners, on the mask layer; c) etching and disconnecting the metal interconnect liners via the openings, thereby insulating and isolating the metal interconnect liners. The present invention further provides a semiconductor structure, which comprises a substrate and metal interconnect liners, wherein ends of the metal interconnect liners are disconnected by insulating walls formed within the substrate. The structure and the method provided by the present invention are favorable for shortening distance between ends of adjacent metal interconnect liners, saving device area and suppressing short circuits happening to metal interconnect liners.

Abstract: The present invention provides a semiconductor structure comprising: a semiconductor base located on an insulating layer, wherein the insulating layer is located on a semiconductor substrate; source/drain regions, which are in contact with first sidewalls of the semiconductor base opposite to each other; gates located on second sidewalls of the semiconductor base opposite to each other; an insulating via located on the insulating layer and embedded into the semiconductor base; and an epitaxial layer sandwiched between the insulating via and the semiconductor base. The present invention further provides a method for manufacturing a semiconductor structure comprising: forming an insulating layer on a semiconductor substrate; forming a semiconductor base on the insulating layer; forming a void within the semiconductor base, wherein the void exposes the semiconductor substrate; forming an epitaxial layer in the void through selective epitaxy; and forming an insulating via within the void.

Abstract: An CMOS device comprises a plurality of NMOS transistors and a plurality of PMOS transistors, each of which comprises a gate stack constituted of a gate insulating layer and a gate metal layer on a substrate, a source/drain region in the substrate on both sides of the gate stack and a channel region below the gate stack, wherein the gate metal layer of each NMOS transistor comprising a first barrier layer, an NMOS work function adjusting layer, a second barrier layer, and a filling layer, and wherein the gate metal layer of each PMOS transistor comprising a first barrier layer, a PMOS work function adjusting layer, an NMOS work function adjusting layer, a second barrier layer, and a filling layer, and wherein the first barrier layer in the gate metal layer of the NMOS transistor and the first barrier layer in the gate metal layer of the PMOS transistor contain a doping ion to finely adjust the work function.

Abstract: A semiconductor structure is provided, comprising a substrate (130), a support structure (131), a base region (100), a gate stack, a spacer (240), and a source/drain region, wherein the gate stack is located above the base region (100), and the base region (100) is supported above the substrate (130) by the support structure (131), wherein the support structure (131) has a sigma-shaped lateral cross-section; an isolation structure (123) is formed below edges on both sides of the base region (100), wherein a portion of the isolation structure (123) is connected to the substrate (130); a cavity (112) is formed between the isolation structure (123) and the support structure (131); and a source/drain region is formed on both sides of the base region (100) and the isolation structure (123). Accordingly, a method for manufacturing the semiconductor structure is also provided.

Abstract: The present invention relates to enhancing MOSFET performance with the corner stresses of STI.

Abstract: Provided are semiconductor devices and methods for manufacturing the same. An example method may include: forming a first semiconductor layer and a second semiconductor layer sequentially on a substrate; patterning the second semiconductor layer and the first semiconductor layer to form a fin; forming an isolation layer on the substrate, wherein the isolation layer exposes a portion of the first semiconductor layer; implanting ions into a portion of the substrate beneath the fin, to form a punch-through stopper; forming a gate stack crossing over the fin on the isolation layer; selectively etching the second semiconductor layer with the gate stack as a mask, to expose the first semiconductor layer; selectively etching the first semiconductor layer, to form a void beneath the second semiconductor layer; and forming a third semiconductor layer on the substrate, to form source/drain regions.

Abstract: A Sigma-Delta modulator and an analog-to-digital converter. The Sigma-Delta modulator comprises a quantizer, a correction module and an RC integrator. The correction module comprises a predetermined resistance through which a correction level is generated. The correction module is used to compare the correction level with a predetermined reference voltage by using a comparator in the quantizer, so as to generate a digital correction signal, based on which the resistance in a resistance correction array in the RC integrator is corrected. The predetermined resistance is of the same type as the resistance in the resistance correction array in the RC integrator. The Sigma-Delta modulator and the analog-to-digital converter can correct the resistance deviation in the RC integrator.

Abstract: The present invention provides a method of manufacturing a fin structure of a FinFET, comprising: providing a substrate (200); forming a first dielectric layer (210); forming a second dielectric layer (220), the material of the portion where the second dielectric layer is adjacent to the first dielectric layer being different from that of the first dielectric layer (210); forming an opening (230) through the second dielectric layer (220) and the first dielectric layer (2100, the opening portion exposing the substrate; filling a semiconductor material in the opening (230); and removing the second dielectric layer (220) to form a fin structure. In the present invention, the height of the fin structure in the FinFET is controlled by the thickness of the dielectric layer. The etching stop can be controlled well by using the etching selectivity between different materials, which can achieve etching uniformity better compared to time control.

Abstract: A method for manufacturing a semiconductor device comprises, including forming a plurality of fins on a substrate, forming, a dummy gate stack on the fins forming a gate spacer on opposite sides of the dummy gate stack, forming source/drain trenches by etching the fins with the gate spacer and the dummy gate stack as a mask, forming source/drain extension regions on the bottom and sides of the trenches by performing lightly-doping ion implantation; and by performing epitaxial growth in and/or on the source/drain trenches, removing the dummy gate stack to form a gate trench; and forming a gate stack in the gate trench.

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

Abstract: A method for manufacturing a dummy gate structure. The method may include: forming a dummy gate oxide layer and a dummy gate material layer on a semiconductor substrate sequentially; forming an ONO structure on the dummy gate material layer; forming a top amorphous silicon layer on the ONO structure; forming a patterned photoresist layer on the top amorphous silicon layer; etching the top amorphous silicon layer with the patterned photoresist layer as a mask, the etching being stopped on the ONO structure; etching the ONO structure with the patterned photoresist layer and a remaining portion of the top amorphous silicon layer as a mask, the etching being stopped on the dummy gate material layer; removing the patterned photoresist layer; and etching the dummy gate material layer, the etching being stopped at the dummy gate oxide layer to form a dummy gate structure.

Abstract: A method for manufacturing a MOSFET, including: performing ion implantation, via a shallow trench surrounding an active region in a semiconductor substrate, into a first sidewall of the active region and into a second sidewall of the active region opposite to the first sidewall to form a first heavily doped region in the first sidewall and a second heavily doped region in the second sidewall; filling the shallow trench with an insulating material, to form a shallow trench isolation; forming a gate stack and an insulating layer on the substrate, wherein the insulating layer surrounds and caps the gate stack; forming openings in the substrate using the shallow trench isolation, the first and second heavily doped regions, and the insulating layer as a hard mask; and epitaxially growing a semiconductor layer with a bottom surface and sidewalls of each of the openings as a seed layer.

Abstract: Semiconductor devices and methods for manufacturing the same are disclosed. In one embodiment, the method comprises: forming a first shielding layer on a substrate, and forming a first spacer on a sidewall of the first shielding layer; forming one of source and drain regions with the first shielding layer and the first spacer as a mask; forming a second shielding layer on the substrate, and removing the first shielding layer; forming the other of the source and drain regions with the second shielding layer and the first spacer as a mask; removing at least a portion of the first spacer; and forming a gate dielectric layer, and forming a gate conductor in the form of spacer on a sidewall of the second shielding layer or on a sidewall of a remaining portion of the first spacer.

Abstract: A low-noise and big tuning range voltage-controlled oscillator. Wherein a current source circuit is used for generating working current of the voltage-controlled oscillator, a resonance circuit is used for generating an oscillating signal of the voltage-controlled oscillator, the resonance circuit is an inductance and capacitance type resonance circuit, wherein capacitance adopts a metal oxide semiconductor (MOS) capacitive reactance tube or a reverse diode to increase the tuning range of the circuit, a negative resistance circuit is used for generating negative resistance to counteract positive resistance generated by the resonance circuit, and a feedback circuit is used for feeding back the oscillating signal generated by the resonance circuit to the current source circuit to add a new current to the current source.