Abstract: An ultra-thin body transistor and a method for manufacturing an ultra-thin body transistor are disclosed. The ultra-thin body transistor comprises: a semiconductor substrate; a gate structure on the semiconductor substrate; and a source region and a drain region in the semiconductor substrate and on either side of the gate structure; in which the gate structure comprises a gate dielectric layer, a gate embedded in the gate dielectric layer, and a spacer on both sides of the gate; the ultra-thin body transistor further comprises: a body region and a buried insulated region located sequentially under the gate structure and in a well region; two ends of the body region and the buried insulated region are connected with the source region and the drain region respectively; and the body region is isolated from other regions in the well region by the buried insulated region under the body region. The ultra-thin body transistor has a thinner body region, which decreases the short channel effect.

Abstract: A semiconductor device structure and a method for fabricating the same. A method for fabricating semiconductor device structure includes forming gate lines on a semiconductor substrate; forming gate sidewall spacers surrounding the gate lines; forming respective source/drain regions in the semiconductor substrate and on either side of the respective gate lines; forming conductive sidewall spacers surrounding the gate sidewall spacers; and cutting off the gate lines, the gate sidewall spacers and the conductive sidewall spacers at predetermined positions, in which the cut gate lines are electrically isolated gates, and the cut conductive sidewall spacers are electrically isolated lower contacts. The method is applicable to the manufacture of contacts in integrated circuits.

Abstract: The present invention provides a body contact device structure and a method for manufacturing the same. According to the present invention, an opening is formed by removing one end of a dummy gate stack after forming the dummy gate stack, wherein a residual portion of the dummy gate stack is a body stack comprising a body pile-up layer that directly contacts a substrate. Next, a replacement gate stack is formed in the opening, and then a body contact is formed on the body pile-up layer in the body stack. The body contact device structure formed by the method of the present invention effectively reduces the parasitic effects and the device area, and improves the performance of the device structure.

Abstract: A manufacturing method of a gate stack with sacrificial oxygen-scavenging metal spacers includes: forming a gate stack structure consisting of an interfacial oxide layer, a high-K dielectric layer and a metal gate electrode, on a semiconductor substrate; conformally depositing a metal layer covering the semiconductor substrate and the gate stack structure; and selectively etching the metal layer to remove the portions of the metal layer covering the top surface of the gate stack structure and the semiconductor substrate, so as to only keep the sacrificial oxygen-scavenging metal spacers surrounding the gate stack structure in the outer periphery of the gate stack structure. A semiconductor device manufactured by this process.

Abstract: The invention provides a method for forming a contact hole, 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, a material that the sacrificial sidewall spacer is made of being different from any of materials that the gate, the sidewall spacer and the interlayer dielectric layer are made of; 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: The present application discloses a memory device and a method for manufacturing the same.

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 method of making a device includes forming at least one anodizable metal layer over at least one of an electrode or a semiconductor device, forming a plurality of pores in the anodizable metal layer by anodization of the anodizable metal layer to expose a portion of the electrode or semiconductor device, and filling at least one pore with a rewritable material such that at least some of the rewritable material is in electrical contact with the electrode or semiconductor device.

Abstract: Methods are provided for the fabrication of abrupt and tunable offset spacers for improved transistor short channel control. The methods include the formation of a gate electrode within a dielectric layer, with only a top portion of the gate electrode exposed. Silicon is added on the top portion of the gate electrode, by selective epitaxial growth, for example. Etching of the dielectric layer is performed with added silicon at the top portion of the gate electrode serving as a silicon mask to prevent etching of the dielectric layer directly underneath the silicon mask, which includes overhangs over the gate electrode sidewalls. The etching creates offset spacers in a production-worthy manner, and can be used to form offset spacers that are asymmetrical in width. By running the methodology in a microloading regime, wider offset spacers may be created on narrower polysilicon gate features, thereby improving Vt roll-off.

Abstract: A method for forming raised source and drain regions in a semiconductor manufacturing process employs double disposable spacers. A deposited oxide is provided between the first and second disposable spacers, and serves to protect the gate electrode, first disposable spacers and a cap layer during the dry etching of the larger, second disposable spacers. Mouse ears are thereby prevented, while the use of a second disposable spacer avoids shadow-effects during halo ion-implants.

Abstract: A method of making a device includes forming at least one anodizable metal layer over at least one of an electrode or a semiconductor device, forming a plurality of pores in the anodizable metal layer by anodization of the anodizable metal layer to expose a portion of the electrode or semiconductor device, and filling at least one pore with a rewritable material such that at least some of the rewritable material is in electrical contact with the electrode or semiconductor device.

Abstract: A method for forming a self-aligned, dual stress liner for a CMOS device includes forming a first type stress layer over a first polarity type device and a second polarity type device, and forming a sacrificial layer over the first type nitride layer. Portions of the first type stress layer and the sacrificial layer over the second polarity type device are patterned and removed. A second type stress layer is formed over the second polarity type device, and over remaining portions of the sacrificial layer over the first polarity type device in a manner such that the second type stress layer is formed at a greater thickness over horizontal surfaces than over sidewall surfaces. Portions of the second type stress liner on sidewall surfaces are removed, and portions of the second type stress liner over the first polarity type device are removed.

Abstract: The embodiments of the invention provide SRAM cells with asymmetric floating-body pass-gate transistors. More specifically, a semiconductor device includes an SRAM cell, a first pass-gate transistor, and a second pass-gate transistor. The first pass-gate transistor is connected to a first side of the SRAM cell, wherein the first pass-gate transistor comprises a first drain region and a first source region. The second pass-gate transistor is connected to a second side of the SRAM cell, wherein the second side is opposite the first side. The second pass-gate transistor comprises a second source region and a second drain region. Furthermore, the first source region and/or the second source region comprise a xenon implant. The first drain region and the second drain region each lack a xenon implant.

Abstract: Stressed MOS devices and methods for their fabrication are provided. The stressed MOS device comprises a T-shaped gate electrode formed of a material having a first Young's modulus. The T-shaped gate electrode includes a first vertical portion and a second horizontal portion. The vertical portion overlies a channel region in an underlying substrate and has a first width; the horizontal portion has a second greater width. A tensile stressed film is formed overlying the second horizontal portion, and a material having a second Young's modulus less than the first Young's modulus fills the space below the second horizontal portion. The tensile stressed film imparts a stress on the horizontal portion of the gate electrode and this stress is transmitted through the vertical portion to the channel of the device. The stress imparted to the channel is amplified by the ratio of the second width to the first width.

Abstract: Methods are disclosed for forming self-aligned dual stressed layers for enhancing the performance of NFETs and PFETs. In one embodiment, a sacrificial layer is used to remove a previously deposited stressed layer. A mask position used to pattern the sacrificial layer is adjusted such that removal of the latter deposited stressed layer, using the sacrificial layer, leaves the dual stress layers in an aligned form. The methods result in dual stressed layers that do not overlap or underlap, thus avoiding processing problems created by those issues. A semiconductor device including the aligned dual stressed layers is also disclosed.

Abstract: Stressed MOS devices and methods for their fabrication are provided. The stressed MOS device comprises a T-shaped gate electrode formed of a material having a first Young's modulus. The T-shaped gate electrode includes a first vertical portion and a second horizontal portion. The vertical portion overlies a channel region in an underlying substrate and has a first width; the horizontal portion has a second greater width. A tensile stressed film is formed overlying the second horizontal portion, and a material having a second Young's modulus less than the first Young's modulus fills the space below the second horizontal portion. The tensile stressed film imparts a stress on the horizontal portion of the gate electrode and this stress is transmitted through the vertical portion to the channel of the device. The stress imparted to the channel is amplified by the ratio of the second width to the first width.

Abstract: Methods and systems with one or more mobile transceivers to locate position of radio frequency identification (RFID) tags via radio frequency (RF) technology are disclosed. The systems called RF Locator (RFL) include at least one mobile RF transceiver and other functional components such as, a globe positioning system (GPS), a processor, and a display. Information of space positions, times and physical characteristics related to RF signals are collected sequentially by the mobile transceiver(s) during RFID tag locating process. The processor calculates the location of the RFID tag by using the collected information. Two methods to determine the location of the RFID tag are disclosed in this invention. The first method is to utilize the information of space positions and times. The second method is to use the information of space positions and RF signal characteristics.

Abstract: Methods are provided for the fabrication of abrupt and tunable offset spacers for improved transistor short channel control. The methods include the formation of a gate electrode within a dielectric layer, with only a top portion of the gate electrode exposed. Silicon is added on the top portion of the gate electrode, by selective epitaxial growth, for example. Etching of the dielectric layer is performed with added silicon at the top portion of the gate electrode serving as a silicon mask to prevent etching of the dielectric layer directly underneath the silicon mask, which includes overhangs over the gate electrode sidewalls. The etching creates offset spacers in a production-worthy manner, and can be used to form offset spacers that are asymmetrical in width. By running the methodology in a microloading regime, wider offset spacers may be created on narrower polysilicon gate features, thereby improving Vt roll-off.

Abstract: The method for forming a semiconductor device arrangement with raised source/drains includes depositing a raised source/drain layer on a substrate, followed by a sacrificial layer on the raised source/drain layer. A trench is formed in the sacrificial layer and the raised source/drain layer, and sidewall spacers are formed within the trench. A replacement gate is formed between the sidewall spacers and the sacrificial layer is removed to expose the raised source/drain regions. The sidewall spacers may then be removed from the sidewalls of the replacement gate, leaving the replacement gate a defined distance from the raised source/drain regions.