Abstract: Semiconductor devices and methods of manufacturing the same are described. The method includes front side processing to form a source/drain cavity and filling the cavity with a sacrificial layer. The sacrificial layer is then removed during processing of the backside to form a backside power rail via that is filled with a metal fill.

Abstract: Semiconductor devices and methods of manufacturing the same are described. Transistors are fabricated using a standard process flow. A via opening extending from the top surface of the substrate to a bottom surface of the wafer device is formed, thus allowing nano TSV for high density packaging, as well as connecting the device to the backside power rail. A metal is deposited in the via opening, and the bottom surface of the wafer device is bound to a bonding wafer. The substrate is optionally thinned, and a contact electrically connected to the metal is formed.

Abstract: Semiconductor devices and methods of manufacturing the same are described. The method includes forming a bottom dielectric isolation (BDI) layer on a substrate and depositing a template material in the source/drain trench. The template material is etched and then crystallized. Epitaxially growth of the source and drain regions then proceeds, with growth advantageously occurring on the bottom and sidewalls of the source and drain regions.

Abstract: Semiconductor devices and methods of manufacturing the same are described. The method includes front side processing to form a deep source/drain cavity and filling the cavity with a sacrificial material. The sacrificial material is then removed during processing of the backside to form a backside power rail via that is filled with a metal fill.

Abstract: Semiconductor devices and methods of manufacturing the same are described. A silicon wafer is provided and a buried etch stop layer is formed on the silicon wafer. The wafer is then subjected to device and front-end processing. After front-end processing, the wafer undergoes hybrid bonding, and then the wafer is thinned. To thin the wafer, the silicon substrate layer, which has a starting first thickness, is ground to a second thickness, the second thickness less than the first thickness. After grinding, the silicon wafer is subjected to chemical mechanical planarization (CMP), followed by etching and CMP buffing, to reduce the thickness of the silicon to a third thickness, the third thickness less than the second thickness.

Abstract: Embodiments of processing a substrate are provided herein. In some embodiments, a method of processing a substrate includes: depositing, via a first epitaxial growth process, an n-doped silicon material onto a substrate to form an n-doped layer while adjusting a ratio of dopant precursor to silicon precursor so that a dopant concentration of the n-doped layer increases from a bottom of the n-doped layer to a top of the n-doped layer; etching the n-doped layer to form a plurality of trenches having sidewalls that are tapered and a plurality of n-doped pillars therebetween; and filling the plurality of trenches with a p-doped material via a second epitaxial growth process to form a plurality of p-doped pillars.

Abstract: Disclosed are systems, methods, and apparatus of an automated and self-service kiosk that allows customers to select inventory items available from the kiosk and walk or move away with selected inventory item(s) without having to process payment, identify the inventory item(s), or provide any other form of checkout. After a customer has picked one or more items and departed the kiosk, the picked items are determined and the customer charged for the items. For example, one or more of detected weight changes measured at the kiosk and/or images generated at the kiosk may be used to identify items picked by the customer from the kiosk.

Abstract: Exemplary methods of forming a semiconductor structure may include forming a doped silicon layer on a semiconductor substrate. A level of doping may be increased at an increasing distance from the semiconductor substrate. The methods may include etching the doped silicon layer to define a trench extending to the semiconductor substrate. The doped silicon layer may define a sloping sidewall of the trench. The trench may be characterized by a depth of greater than or about 30 ?m. The methods may include lining the trench with a first oxide material. The methods may include depositing a second oxide material within the trench. The methods may include forming a contact to produce a power device.

Abstract: Horizontal gate-all-around devices and methods of manufacturing are described. The hGAA devices comprise a fully-depleted silicon-on-insulator (FD-SOI) under the channel layers in the same footprint as the hGAA. The buried dielectric insulating layer of the FD-SOI comprises one or more of silicon oxide (SiOx), silicon nitride (SiN), silicon carbide (SiC), and a high-k material, and the buried dielectric insulating layer has a thickness in a range of from 0 nm to 10 nm.

Abstract: Processing methods may be performed to form an airgap spacer on a semiconductor substrate. The methods may include forming a spacer structure including a first material and a second material different from the first material. The methods may include forming a source/drain structure. The source/drain structure may be offset from the second material of the spacer structure by at least one other material. The methods may also include etching the second material from the spacer structure to form the airgap. The source/drain structure may be unexposed to etchant materials during the etching.

Abstract: Examples of the present technology include processing methods to incorporate stress in a channel region of a semiconductor transistor. The methods may include depositing a stressed material on an adjacent layer, where the adjacent layer is disposed between the stressed material and semiconductor material having an incorporated dopant. The adjacent layer may be characterized by an increased stress level after the deposition of the stressed material. The method may further include heating the stressed material and the adjacent layer, and removing the stressed material from the adjacent layer. The adjacent layer retains at least a portion of the increased stress after the removal of the stressed material. Examples of the present technology also include semiconductor structures having a conductive layer with first stress, and an intermediate layer with second stress in contact with the conductive layer. The second tensile stress may be at least ten times the first tensile stress.

Abstract: Processing methods may be performed to form an airgap spacer on a semiconductor substrate. The methods may include forming a spacer structure including a first material and a second material different from the first material. The methods may include forming a source/drain structure. The source/drain structure may be offset from the second material of the spacer structure by at least one other material. The methods may also include etching the second material from the spacer structure to form the airgap. The source/drain structure may be unexposed to etchant materials during the etching.

Abstract: Semiconductor structures may include a substrate. The structures may include a gate structure overlying the substrate and formed in a first direction across the substrate. The structures may include a fin overlying the substrate and formed in a second direction across the substrate. The second direction may be orthogonal to the first direction, and the fin may intersect the gate structure. The structures may include a source/drain material formed about the fin. The structures may include a through-contact material extending vertically above the source/drain material. The structures may include a metal material extending vertically above the through-contact material. An interface between the metal material and the through-contact material may be characterized by a non-planar profile.

Abstract: Semiconductor structures may include a substrate. The structures may include a gate structure overlying the substrate and formed in a first direction across the substrate. The structures may include a fin overlying the substrate and formed in a second direction across the substrate. The second direction may be orthogonal to the first direction, and the fin may intersect the gate structure. The structures may include a source/drain material formed about the fin. The structures may include a through-contact material extending vertically above the source/drain material. The structures may include a metal material extending vertically above the through-contact material. An interface between the metal material and the through-contact material may be characterized by a non-planar profile.

Abstract: Aspects of the disclosure provide for reducing a temperature of one or more non-volatile memory (NVM) dies of a solid state drive (SSD). The methods and apparatus detect a temperature of one or more NVM dies of a plurality of NVM dies of the SSD, the plurality of NVM dies including at least one parity NVM die, and determine that the one or more NVM dies is overheated when the detected temperature is at or above a threshold temperature. If the detected temperature is at or above the threshold temperature, the methods and apparatus redirect parity data designated for the at least one parity NVM die to the one or more overheated NVM dies. By repurposing the one more overheated NVM dies to store the parity data, the repurposed dies will experience less activity, and therefore, generate less heat without throttling or reducing the workload capability of the dies.

Abstract: Aspects of the disclosure provide for reducing a temperature of one or more non-volatile memory (NVM) dies of a solid state drive (SSD). The methods and apparatus detect a temperature of one or more NVM dies of a plurality of NVM dies of the SSD, the plurality of NVM dies including at least one parity NVM die, and determine that the one or more NVM dies is overheated when the detected temperature is at or above a threshold temperature. If the detected temperature is at or above the threshold temperature, the methods and apparatus redirect parity data designated for the at least one parity NVM die to the one or more overheated NVM dies. By repurposing the one more overheated NVM dies to store the parity data, the repurposed dies will experience less activity, and therefore, generate less heat without throttling or reducing the workload capability of the dies.

Abstract: Processing methods may be performed to form an airgap spacer on a semiconductor substrate. The methods may include forming a spacer structure including a first material and a second material different from the first material. The methods may include forming a source/drain structure. The source/drain structure may be offset from the second material of the spacer structure by at least one other material. The methods may also include etching the second material from the spacer structure to form the airgap. The source/drain structure may be unexposed to etchant materials during the etching.

Abstract: Data, normally read using a page-by page read process, can be recovered from memory cells connected to a broken word line by performing a sequential read process. To determine whether a word line is broken, both a page-by page read process and a sequential read process are performed. The results of both read processes are compared. If the number of mismatches between the two read processes is greater than a threshold, it is concluded that there is a broken word line.

Abstract: Various aspects of the invention are directed to memory circuits and their implementation. According to an example embodiment, an apparatus includes a channel region between raised source and drain regions which are configured and arranged with respective bandgap offsets relative to the channel region to confine carriers in the channel region. The apparatus also includes front and back gates respectively separated from the channel region by gate dielectrics. The raised source and drain regions have respective portions laterally adjacent the front gate and adjacent the channel region. Carriers are stored in the channel region via application of voltage(s) to the front and back gates, and relative to bias(es) at the source and drain regions.

Abstract: In an embodiment, a semiconductor device is provided. The semiconductor device may include a substrate having a main processing surface, a first source/drain region comprising a first material of a first conductivity type, a second source/drain region comprising a second material of a second conductivity type, wherein the second conductivity type is different from the first conductivity type, a body region electrically coupled between the first source/drain region and the second source/drain region, wherein the body region extends deeper into the substrate than the first source/drain region in a first direction that is perpendicular to the main processing surface of the substrate, a gate dielectric disposed over the body region, and a gate region disposed over the gate dielectric, wherein the gate region overlaps with at least a part of the first source/drain region and with a part of the body region in the first direction.