Abstract: Semiconductor devices and methods for manufacturing the same are disclosed. In one embodiment, the method comprises: sequentially forming a sacrificial layer and a semiconductor layer on a substrate; forming a first cover layer on the semiconductor layer; forming an opening extending into the substrate with the first cover layer as a mask; selectively removing at least a portion of the sacrificial layer through the opening, and filling an insulating material in a gap due to removal of the sacrificial layer; forming one of source and drain regions in the opening; forming a second cover layer on the substrate; forming the other of the source and drain regions with the second cover layer as a mask; removing a portion of the second cover layer; and forming a gate dielectric layer, and forming a gate conductor in the form of spacer on a sidewall of a remaining portion of the second cover layer.

Abstract: The invention provides a graphene device structure and a method for manufacturing the same, the device structure comprising a graphene layer; a gate region in contact with the graphene layer; semiconductor doped regions formed in the two opposite sides of the gate region and in contact with the graphene layer, wherein the semiconductor doped regions are isolated from the gate region; a contact formed on the gate region and contacts formed on the semiconductor doped regions. The on-off ratio of the graphene device is increased through the semiconductor doped regions without increasing the band gap of the graphene material, i.e., without affecting the mobility of the material or the speed of the device, thereby increasing the applicability of the graphene material in CMOS devices.

Abstract: A method of manufacturing a semiconductor device is provided, in which after forming a gate stack and a first spacer thereof, a second spacer and a third spacer are formed; and then an opening is formed between the first spacer and the third spacer by removing the second spacer. The range of the formation for the raised active area 220 is limited by forming an opening 214 between the first spacer 208 and the third spacer 212. The raised active area 220 is formed in the opening 214 in a self-aligned manner, so that a better profile of the raised active area 220 may be achieved and the possible shorts between adjacent devices caused by an unlimited manner may be avoided. Moreover, based on such a manufacturing method, it is easy to make the gate electrode 204 to be flushed with the raised active area 220, and is also easy to implement the dual stress nitride process so as to increase the mobility of the device.

Abstract: A trench isolation structure and a method of forming the same are provided. The trench isolation structure includes: a semiconductor substrate, and trenches formed in the semiconductor substrate and filled with a dielectric layer, where the material of the dielectric layer is a crystalline material. By using the present invention, the size of the divot can be reduced, and device performances can be improved.

Abstract: The present invention proposes a semiconductor device structure and a method for manufacturing the same, and relates to the semiconductor manufacturing industry. The method comprises: providing a semiconductor substrate; forming gate electrode lines on the semiconductor substrate; forming sidewall spacers on both sides of the gate electrode lines; forming source/drain regions on the semiconductor substrates at both sides of the gate electrode lines; forming contact holes on the gate electrode lines or on the source/drain regions; and cutting off the gate electrode lines to form electrically isolated gate electrodes after formation of the sidewall spacers but before completion of FEOL process for a semiconductor device structure. The embodiments of the present invention are applicable for manufacturing integrated circuits.

Abstract: A method for manufacturing a semiconductor device is disclosed, comprising: providing a substrate, a gate region on the substrate and a semiconductor region at both sides of the gate region; forming sacrificial spacers, which cover a portion of the semiconductor region, on sidewalls of the gate region; forming a metal layer on a portion of the semiconductor region outside the sacrificial spacers and on the gate region; removing the sacrificial spacers; performing annealing so that the metal layer reacts with the semiconductor region to form a metal-semiconductor compound layer on the semiconductor region; and removing unreacted metal layer. By separating the metal layer from the channel and the gate region of the device with the thickness of the sacrificial spacers, the effect of metal layer diffusion on the channel and the gate region is reduced and performance of the device is improved.

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 method for forming a semiconductor device comprises: forming at least one gate stack structure and an interlayer material layer between the gate stack structures on a semiconductor substrate; defining isolation regions and removing a portion of the interlayer material layer and a portion of the semiconductor substrate which has a certain height in the regions, so as to form trenches; removing portions of the semiconductor substrate which carry the gate stack structures, in the regions; and filling the trenches with an insulating material. A semiconductor device is also provided. The area of the isolation regions may be reduced.

Abstract: A semiconductor structure and a method for fabricating the same. A semiconductor structure includes a semiconductor substrate; a channel region formed in the semiconductor substrate; a gate including a dielectric layer and a conductive layer and formed above the channel region; source and drain regions formed at opposing sides of the gate; first shallow trench isolations embedded into the semiconductor substrate and having a length direction parallel to the length direction of the gate; and second shallow trench isolations, each of which abuts the outer sidewall of the source or the drain region and abuts the first shallow trench isolations, in which the source and drain regions include first seed crystal layers abutting the second shallow trench isolations, and the top surfaces of the second shallow trench isolations are higher than or as high as the top surfaces of the source and drain regions.

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 presented application discloses a capacitor structure and a method for manufacturing the same.

Abstract: A semiconductor device and a method of manufacturing the same are provided. The semiconductor device has a metal sidewall spacer on the sidewall of a gate electrode on the drain region side. The metal sidewall spacer is made of such metals as Ta, which has an oxygen scavenging effect and can effectively reduce EOT on the drain region side, and thus the ability to control the short channel is effectively increased. In addition, since EOT on the source region side is larger, the carrier mobility of the device will not be degraded. Moreover, such asymmetric device may have a better driving performance.

Abstract: A stack-type semiconductor device includes a semiconductor substrate; and a plurality of wafer assemblies arranged in various levels on the semiconductor substrate, in which the wafer assembly in each level includes an active part and an interconnect part, and the active part and the interconnect part each have conductive through vias, wherein the conductive through vias in the active part are aligned with the conductive through vias in the interconnect part in a vertical direction, so that the active part in each level is electrically coupled with the active part in the previous level and/or the active part in the next level by the conductive through vias. Such a stack-type semiconductor device and the related methods can be applied in a process after the FEOL or in a semiconductor chip packaging process and provide a 3-dimensional semiconductor device of high integration and high reliability.

Abstract: The present invention discloses a method of manufacturing a fin field effect transistor, which comprises the steps of forming a plurality of first fin structures on a substrate, which extend along a first direction parallel to the substrate; forming a plurality of second fin structures on a substrate, which extend along a second direction parallel to the substrate and the second direction intersecting with the first direction; selectively removing a part of the second fin structures to form a plurality of gate lines; and selectively removing a part of the first fin structures to form a plurality of substrate lines.

Abstract: A method of manufacturing a semiconductor device is provided, in which after forming a gate stack and a first spacer thereof, a second spacer and a third spacer are formed; and then an opening is formed between the first spacer and the third spacer by removing the second spacer. The range of the formation for the raised active area 220 is limited by forming an opening 214 between the first spacer 208 and the third spacer 212. The raised active area 220 is formed in the opening 214 in a self-aligned manner, so that a better profile of the raised active area 220 may be achieved and the possible shorts between adjacent devices caused by an unlimited manner may be avoided. Moreover, based on such a manufacturing method, it is easy to make the gate electrode 204 to be flushed with the raised active area 220, and is also easy to implement the dual stress nitride process so as to increase the mobility of the device.

Abstract: A method for restricting lateral encroachment of the metal silicide into the channel region, comprising: providing a semiconductor substrate, a gate stack being formed on the semiconductor substrate, a source region being formed in the semiconductor on one side of the gate stack, and a drain region being formed in the semiconductor substrate on the other side of the gate stack; forming a sacrificial spacer around the gate stack and on the semiconductor substrate; depositing a metal layer for covering the semiconductor substrate, the gate stack and the sacrificial spacer; performing a thermal treatment on the semiconductor substrate, thereby causing the metal layer to react with the sacrificial spacer and the semiconductor substrate in the source region and the drain region; removing the sacrificial spacer, reaction products of the sacrificial spacer and the metal layer, and a part of the metal layer which does not react with the sacrificial spacer.

Abstract: A trench isolation structure and a method of forming the same are provided. The trench isolation structure includes: a semiconductor substrate, and trenches formed on the surface of the semiconductor substrate and filled with a dielectric layer, wherein the material of the dielectric layer is a crystalline material. By using the present invention, the size of the divot can be reduced, and device performances can be improved.

Abstract: The invention provides a STI structure and method for forming the same. The STI structure includes a semiconductor substrate; a first trench embedded in the semiconductor substrate and filled up with a first dielectric layer; and a second trench formed on a top surface of the semiconductor substrate and interconnected with the first trench, wherein the second trench is filled up with a second dielectric layer, a top surface of the second dielectric layer is flushed with that of the semiconductor substrate, and the second trench has a width smaller than that of the first trench. The invention reduces dimension of divots and improves performance of the semiconductor device.

Abstract: An embodiment of the invention discloses a graphene device comprising a plurality of graphene channels and a gate, wherein one end of all the graphene channels is connected to one terminal, all the graphene channels are in contact with and electrically connected with the gate, and the angles between the graphene channels and the gate are mutually different. Due to a different incident wave angle for a different graphene channel, each of the graphene channels has a different tunneling probability, each of the graphene channels has a different conduction condition, and the graphene device may be used as a device such as a multiplexer or a demultiplexer, etc.

Abstract: The present invention provides a semiconductor FET and a method for manufacturing the same. The semiconductor FET may comprise: a gate wall; a fin outside the gate wall, both ends of the fin being connected with the source/drain regions on both ends of the fin; and a contact wall on both sides of the gate wall, the contact wall being connected with the source/drain regions via the underlying silicide layer, wherein an airgap is provided around the gate wall. Since an airgap is formed around the gate wall, and particularly the airgap is formed between the gate wall and the contact wall, it is possible to decrease the parasitic capacitance between the gate wall and the contact wall. As a result, the problem of excessive parasitic capacitance resulting from use of the contact wall can be effectively alleviated.