Abstract: A method for forming silicide contacts in integrated circuits (ICs) is described. A spacer pull-back etch is performed during the salicidation process to reduce the stress between the spacer and source/drain silicide contact at the spacer undercut. This prevents the propagation of surface defects into the substrate, thereby minimizing the occurrence of silicide pipe defects. The spacer pull-back etch can be performed after a first annealing step to form the silicide contacts.

Abstract: A method for fabricating a semiconductor device includes forming an SiGe region. The SiGe region can be an embedded source and drain region, or a compressive SiGe channel layer, or other SiGe regions within a semiconductor device. The SiGe region is exposed to an SC1 solution and excess surface portions of the SiGe region are selectively removed. The SC1 etching process can be part of a rework method in which overgrowth regions of SiGe are selectively removed by exposing the SiGe to and SC1 solution maintained at an elevated temperature. The etching process is carried out for a period of time sufficient to remove excess surface portions of SiGe. The SC1 etching process can be carried out at elevated temperatures ranging from about 25° C. to about 65° C.

Abstract: Large tuning range junction varactor includes first and second junction capacitors coupled in parallel between first and second varactor terminals. First and second plates of the capacitors are formed by three alternating doped regions in a substrate. The second and third doped regions are of the same type sandwiching the first doped region of the second type. A first varactor terminal is coupled to the second and third doped regions and a second varactor terminal is coupled to the first doped region. At the interfaces of the doped regions are first and second depletion regions, the widths of which can be varied by varying the voltage across the terminals from zero to full reverse bias. At zero bias condition, junction capacitance (Cmax) is enhanced due to summation of two junction capacitances in parallel. At reverse bias condition, with the merging of the two junction depletion widths, the capacitor areas are drastically reduced, thereby reducing Cmin significantly.

Abstract: A gain circuit of an oscillator circuit includes an inverter portion having an input IN and an output OUT arranged for connection to an external feedback circuit comprising a pi network. A feedback member having a first resistive element is coupled between the input IN and output OUT. An offset sense and correction block (OSCB) is configured to detect a dc offset potential difference between said input IN and output OUT and to reduce the offset potential by supplying a current to said input IN.

Abstract: Some example embodiments of the invention comprise methods for and semiconductor structures comprised of: a MOS transistor comprised of source/drain regions, a gate dielectric, a gate electrode, channel region; a carbon doped SiGe region that applies a stress on the channel region whereby the carbon doped SiGe region retains stress/strain on the channel region after subsequent heat processing.

Abstract: The present invention relates to the reduction or complete prevention of Cu corrosion during a planarization or polishing process. In one aspect of the invention, RF signal is used to establish a negative bias in front of the wafer surface following polishing to eliminate Cu+ or Cu2+ migrations. In another aspect of the invention, a DC Voltage power supply is used to establish the negative bias.

Abstract: A method of forming a device is disclosed. The method includes providing a substrate on which the device is formed. It also includes forming a test cell on the substrate. The test cell includes a defect programmed into the cell to facilitate defect detection.

Abstract: A method for forming a semiconductor device is disclosed. The method includes providing a substrate prepared with a second gate structure. An inter-gate dielectric is formed on the substrate and over the second gate. A first gate is also formed. The first gate is adjacent to and separated from the second gate by the inter-gate dielectric. The substrate is patterned to form a split gate structure with the first and second adjacent gates. The split gate structure is provided with an e-field equalizer adjacent to the first gate. The e-field equalizer improves uniformity of e-field across the first gate during operation.

Abstract: A method of forming a device is disclosed. The method includes providing a substrate and processing a layer of the device on the substrate. The layer is inspected with an inspection tool for defects. The inspection tool is programmed with an inspection recipe determined from studying defects programmed into the layer at known locations.

Abstract: An example embodiments are structures and methods for forming an FET with embedded stressor S/D regions (e.g., SiGe), a doped layer below the embedded S/D region adjacent to the isolation regions, and a stressor liner over reduced spacers of the FET gate. An example method comprising the following. We provide a gate structure over a first region in a substrate. The gate structure is comprised of gate dielectric, a gate, and sidewall spacers. We provide isolation regions in the first region spaced from the gate structure; and a channel region in the substrate under the gate structure. We form S/D recesses in the first region in the substrate adjacent to the sidewall spacers. We form S/D stressor regions filling the S/D recesses.

Abstract: A testing structure, and method of using the testing structure, where the testing structure comprised of at least one of eight test structures that exhibits a discernable defect characteristic upon voltage contrast scanning when it has at least one predetermined structural defect. The eight test structures being: 1) having an Active Area (AA)/P-N junction leakage; 2) having an isolation region to ground; 3) having an AA/P-N junction and isolation region; 4) having a gate dielectric leakage and gate to isolation region to ground; 5) having a gate dielectric leakage through AA/P-N junction to ground leakage; 6) having a gate dielectric to ground and gate/one side isolation region leakage to ground; 7) having an oversized gate dielectric through AA/P-N junction to ground leakage; and 8) having an AA/P-N junction leakage gate dielectric leakage.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a semiconductor substrate; forming a core region on the semiconductor substrate with the core region having a core side; forming an inner bond pad on the semiconductor substrate with the inner bond pad having an inner core pad and an inner probe pad with the inner probe pad further from the core region than the inner core pad; and forming an outer bond pad on the semiconductor substrate and adjacent the inner bond pad with the outer bond pad having an outer core pad and an outer probe pad with the outer probe pad closer to the core region than the outer core pad, and the inner probe pad and the outer probe pad aligned parallel to the core side.

Abstract: Embodiments of the present disclosure provide stress optimization during manufacturing of dual embedded epitaxially grown (EPI) semiconductor structures using just two masks, such as nFET and pFET open for embedded epitaxial using SiC and SiGe, and separated halo implantation masks for both horizontal and vertical PC

Abstract: A transistor disposed on a substrate includes a gate, spacers on gate sidewalls, and diffusion regions adjacent to the gate. Silicide contacts on the diffusion regions are displaced from the spacers by a distance G. Stressors may be provided in the diffusion region to induce a first stress in the channel region of the transistor.

Abstract: Formation of metal pipes resulting from formation of metal silicide contacts are reduced or avoided. To reduce formation of metal pipes, an epitaxial layer is formed over the diffusion region on which the metal silicide contact is formed. The epitaxial layer reduces defects which enhances diffusion of metal atoms or molecules.

Abstract: A method of forming an integrated circuit structure on a substrate, the substrate includes a primary region and a secondary region. A first layer of a first material of a first thickness is formed over the substrate. A portion of the first layer is removed over the primary region to expose the substrate. The structure is exposed to an oxidizing medium. This forms a second layer, for example, of an oxide material primary region of the substrate. The second layer has a second thickness. Additionally, at least a portion of said first layer is converted to a third layer, for example, of an oxynitride material. The third layer has a third thickness.

Abstract: A method for fabricating a nitrogen-containing dielectric layer and semiconductor device including the dielectric layer in which a silicon oxide layer is formed on a substrate, such that an interface region resides adjacent to substrate and a surface region resides opposite the interface region. Nitrogen is introduced into the silicon oxide layer by applying a nitrogen plasma. After applying nitrogen plasma, the silicon oxide layer is annealed. The processes of introducing nitrogen into the silicon oxide layer and annealing the silicon oxide layer are repeated to create a bi-modal nitrogen concentration profile in the silicon oxide layer. In the silicon oxide layer, the peak nitrogen concentrations are situated away from the interface region and at least one of the peak nitrogen concentrations is situated in proximity to the surface region. A method for fabricating a semiconductor device is incorporating the nitrogen-containing silicon oxide layers also disclosed.

Abstract: A method (and semiconductor device) of fabricating a TFET device provides a source region having at least a portion thereof positioned underneath a gate dielectric. In one embodiment, the TFET includes an N+ drain region and a P+ source region in a silicon substrate, where the N+ drain region is silicon and the P+ source region is silicon germanium (SiGe). The source region includes a first region of a first type (e.g., P+ SiGe) and a second region of a second type (undoped SiGe), where at least a portion of the source region is positioned below the gate dielectric. This structure decreases the tunneling barrier width and increases drive current (Id).

Abstract: A method of fabricating a device is presented. The method includes forming a mask that includes multiple images. A substrate is patterned using the mask. An image of the multiple images corresponds to a respective patterning process. The substrate is processed further to complete the processing of the substrate to form the desired function of the device.

Abstract: An integrated circuit system that includes: providing a first mask including a first feature; exposing the first mask to a radiation source to form an image of the first feature on a photoresist material that is larger than a structure to be formed, the photoresist material being formed over a substrate that includes the integrated circuit system; providing a second mask including a second feature; aligning the second mask over the image of the first mask to form an overlap region; and exposing the second mask to the radiation source to form an image of the second feature on the photoresist material that is larger than the structure to be formed.