Abstract: A method of testing integrated circuits for the effect of NBTI degradation. A static DC stress voltage is applied to the voltage supply input of the circuit. This circuit is held at this voltage for a given stress period. The application of the DC voltage is equivalent to applying a negative gate bias, and isolates the effects of NBTI degradation from CHC (channel hot carrier) degradation or other degradation that occurs when the circuit has a clocked input.

Abstract: A method for evaluating a mask pattern for a product that is manufactured by a process that is described at least in part by a mathematical process model includes the steps of: (a) selecting a reference locus; (b) determining a sampling direction from the reference locus; (c) selecting a sampling locus in the sampling direction; (d) evaluating a model factor at the sampling locus; and (e) applying at least one predetermined criterion to the model factor to determine a conclusion. If the conclusion is a first inference, (f) repeating steps (c) through (e). If the conclusion is a second inference, (g) determining whether the evaluation is complete and repeating steps (a) through (g) until the evaluating is complete.

Abstract: A method of forming a semiconductor device includes forming one or more sidewall spacer layers on the outer surface of a gate stack. At least one region of an at least partially formed semiconductor device is doped. First and second sidewall bodies are formed on opposing sides of the gate stack. The formation of the first and second sidewall bodies includes forming a first sidewall-forming layer on the outward surface of the gate stack and the sidewall spacer layers, exposing the semiconductor device to a heating cycle in a single wafer reactor, and forming a second sidewall-forming layer on the outward surface of the first sidewall-forming layer. The formation of the second sidewall-forming layer occurs in an environment that substantially minimizes dopant loss and deactivation in the at least one region of the partially formed semiconductor device.

Abstract: The present invention provides a method for determining resist trim times in an etch process. In one embodiment of the invention, the method for determining resist trim times includes obtaining resist profile data and critical dimension (CD) data of a patterned resist layer using a scatterometer, in a step 520, and then obtaining an estimated trim time of the patterned resist layer using the resist profile data and critical dimension data, in steps 530-550.

Abstract: A method for using alkylsilane precursors during the sidewall formation process in MOS transistor fabrication processes. Alkylsilane precursors are used to form carbon contain silicon oxide layers (110) and carbon containing silicon nitride layers (120) during the sidewall formation process. The carbon containing layers (110) (120) introduce carbon into the extension regions (100) and the gate region (30) during thermal annealing.

Abstract: Correcting a mask pattern includes partitioning the mask pattern to yield templates. The following is repeated for each template to generate correction data: a clip mask is generated for a template selected as a main template; the main template is merged with context templates to yield a merged template; the merged template is divided to yield segments including clip segments, where an intersection of the clip mask and the merged template defines an endpoint of a clip segment; a proximity correction procedure is performed on the segments to yield a corrected template; and correction data of the corrected template is selected according to the clip mask. The correction data for the templates are aggregated to correct the mask pattern.

Abstract: Methods and apparatus are disclosed for selectively inducing stress in a semiconductor device, wherein a first region of a substrate is implanted so as to induce stress in a second region. An electrical device is formed at least partially in the second region, wherein the induced stress therein may improve one or more operational characteristics of the device, such as channel region carrier mobility.

Abstract: The present invention provides, in one embodiment, process of treating a target semiconductor surface. The process includes exposing a test surface to a plasma protocol (110), and measuring chemical changes in discrete locations of the test surface (120). The process further includes preparing a target surface by exposing the target surface to the plasma protocol (140) when a uniformity of the chemical changes are within a performance criterion of the plasma protocol (130). Other embodiments advantageously incorporate this process into methods for making semiconductor devices and integrated circuits.

Abstract: A polysilicon layer (30) is formed on a dielectric region (20). An optional metal silicide layer (50) can be formed on the polysilicon layer. A dielectric layer (60) is formed over the metal silicide layer and a conductive layer (70) formed over the dielectric layer. The formed layers are etched by a combination of multi-step dry and wet process to form high precision integrated circuit capacitors.

Abstract: An electronic device architecture is described comprising a field effect device in an active region 22 of a substrate 10. Channel stop implant regions 28a and 28b are used as isolation structures and are spaced apart from the active region 22 by extension zones 27a and 27b. The spacing is established by using an inner mask layer 20 and an outer mask layer 26 to define the isolation structures.

Abstract: The present invention pertains to formation of a PMOS transistor wherein a layer of silicon or SiGe inhibits p-type dopant from entering into an underlying gate dielectric layer. The p-type dopant can be added to a gate electrode material that overlies the silicon or SiGe layer and can diffuse down toward the silicon or SiGe layer. The layer of silicon or SiGe may be formed to a thickness of about 5 to 120 nanometers and doped with a dopant, such as indium (In), for example, to deter the p-type dopant from passing through the silicon or SiGe layer. The dopant may have a peak concentration within the layer of silicon or SiGe near the interface of the silicon or SiGe layer with the underlying layer of gate dielectric material. Allowing the gate electrode to be doped with the p-type dopant (e.g., boron) facilitates forming the transistor with an associated work function having a desired value (e.g., coincident with a Fermi level of about 4.8 to about 5.6 electron volts).

Abstract: A protection structure (30; 30′; 30″) for safely conducting charge from electrostatic discharge (ESD) at a terminal (IN) is disclosed. The protection structure (30; 30′; 30″) includes a pair of drain-extended metal-oxide-semiconductor (MOS) transistors (32, 34). In a pump transistors (32), the gate electrode (45) overlaps a portion of a well (42) in which the drain (44) is disposed, to provide a significant gate-to-drain capacitance. The drains of the transistors (32, 34) are connected together and to the terminal (IN), while the gates of the transistors (32, 34) are connected together. The source of one transistor (32) is connected to a guard ring (50), of the same conductivity type as the substrate (40) within which the channel region of the other transistors (34) is disposed.

Abstract: A method of forming a semiconductor component having a conductive line (24) and a silicide region (140) that crosses a trench (72). The method involves forming nitride sidewalls (130) to protect the stack during the silicidation process.

Abstract: Using deuterium oxygen during stream oxidation forms an oxidizing vapor. Since deuterium is chemically similar to hydrogen, the oxidation process takes place normally and the silicon-silicon oxide interface is concurrently saturated with deuterium. Saturating the interface with deuterium reduces the interface trap density thereby reducing channel hot carrier degradation.

Abstract: A method is provided for forming dual work function gate electrodes. A dielectric layer is provided outwardly of a substrate. A metal layer is formed outwardly of the dielectric layer. A silicon-germanium layer is formed outwardly of the metal layer. A first portion of the silicon-germanium layer is removed to expose a first portion of the metal layer, with a second portion of the silicon-germanium layer remaining over a second portion of the metal layer. A silicon-germanium metal compound layer is formed from the second portion of the silicon-germanium layer and the second portion of the metal layer. A first gate electrode comprising the first portion of the metal layer is formed. A second gate electrode comprising the silicon-germanium metal compound layer is formed.

Abstract: The present invention provides a capacitor 300, a method of manufacture therefor and an integrated circuit including the same. In one embodiment of the invention, the capacitor 300 includes a first conductive plate 320 located over a semiconductor substrate 310, wherein the first conductive plate 320 has a second conductive plate 340 located thereover. The capacitor 300, in the same embodiment, further includes a dielectric layer 330 located between the first conductive plate 320 and the second conductive plate 340, wherein the dielectric layer 330 includes a Group 17 element.

Abstract: A pnp bipolar junction transistor is formed with improved emitter efficiency by reducing the depth of the p well implant to increase carrier concentration in the emitter and making the emitter junction deeper to increase minority lifetime in the emitter. The high gain BJT is formed without added mask steps to the process flow. A blanket high energy boron implant is used to suppress the isolation leakage in SRAM in the preferred embodiment.

Abstract: The invention describes a method for reducing the leakage current in thin gate dielectric MOS capacitors in integrated circuits. A bias voltage is determined for the MOS capacitor such that the capacitor area and leakage current constraints are satisfied. The MOS capacitor is not biased in inversion.

Abstract: A system for fabricating a mixed voltage integrated circuit is disclosed in which a gate is provided that contains a gate oxide and a gate conductor on a substrate. A first mask is deposited to pattern the length of the gate by etching, and a second mask pattern is deposited and used to etch the width of the gate, with or without a hard mask.

Abstract: A method for measuring a capacitance of a semiconductor is provided that includes positioning a measurement circuit in a scribe line area associated with the semiconductor. The scribe line area is indicative of a delineation that separates one or more portions of the semiconductor. A capacitance of one or more elements included within the one or more portions of the semiconductor is then measured using the measurement circuit. The method also includes comparing the capacitance measurement of the one or more elements included within the one or more portions of the semiconductor to a reference set of capacitance values such that a parameter associated with a manufacturing process that generated the semiconductor may be checked.