Abstract: A method of processing semiconductor wafers comprises forming a pattern of recesses in an exposed surface of each wafer in a lot, prior to an epitaxy step. At least one recessed test structure is included in the pattern of recesses. At least one dimension of the recessed test structure is determined prior to the epitaxy step, then a corresponding dimension of an epitaxial structure grown above the recessed test structure in the epitaxy step is measured. A deviation between the dimension of the recessed test structure and the dimension of the epitaxial structure is determined and, from the deviation, the process temperature at which the epitaxy step was performed is determined. In case the deviation exceeds a predetermined limit, the temperature in the process chamber is adjusted for a subsequent lot of wafers to be processed.

Abstract: A MOSFET structure including silicate gate dielectrics with nitridation treatments of the gate dielectric prior to gate material deposition.

Abstract: The present invention describes circuitry and a method of providing a low power WRITE mode of operation for an integrated circuit comprising an SRAM memory to provide a reduced IDDQ relative to the IDDQ of a full active mode. In one aspect, the circuitry includes an SRAM memory array, mode control circuitry coupled to the array and configured to alter a supply voltage level to the SRAM array based on a mode of operation. The circuitry also includes control inputs coupled to the mode control circuitry for selecting one of the low power write mode, the full active mode, and optionally a retention mode of operation. The mode control circuitry is configured to receive the control inputs to select one of the three modes of operation, and to alter one or more supply voltage levels to the array, for example, the Vss supply voltage using a Vss supply circuit and the Vdd supply voltage using a Vdd supply circuit, based on the selected mode of operation.

Abstract: The invention relates to a stacked capacitor (10) comprising a silicon base plate (16), a poly-silicon center plate (32) arranged above the base plate (16), a lower gate-oxide dielectric (26) arranged between the base plate (16) and the center plate (32), a cover plate (36) made of a metallic conductor and arranged above the center plate (32), and an upper dielectric (34) arranged between the center plate (32) and the cover plate (36). The cover plate (36) and the base plate (16) are electrically connected to each other and together form a first capacitor electrode. The center plate (32) forms a second capacitor electrode. The invention further relates to an integrated circuit with such a stacked capacitor, as well as to a method for fabrication of a stacked capacitor as part of a CMOS process.

Abstract: The present invention provides a semiconductor device 200 having an angled compensation implant, a method of manufacture therefore and a method of manufacturing an integrated circuit including the angled compensation implant. In one embodiment, the method of manufacturing the semiconductor device 200 includes creating a halo implant 240 in a substrate 210, introducing a compensation implant 260 in the substrate 210 at an angle abnormal to the substrate 210 and forming a source/drain region 250 above the compensation implant 260, the angle reducing a capacitance associated with the halo implant 240 or the source/drain region 250. The method further includes placing a gate structure 230 over the substrate 210.

Abstract: A method of double-exposure photolithography of a semiconductor wafer in the manufacture of integrated circuits is disclosed. The two exposures of the same positive photoresist layer are carried out using a binary photomask (25) having chrome regions (22) that define non-critical dimension features (6c) and also serve as protection for phase shift exposure of critical dimension features (6g). The phase shift photomask (23) includes apertures 200, 20&pgr; that expose the sides of the critical dimension feature (6g) with opposite phase light. The phase shift photomask (23) also includes an additional aperture (30) for double exposure of a region exposed by the binary photomask, for example as between a non-critical dimension feature (6c) and the end of a critical dimension feature (6g).

Abstract: The invention relates to an improved substrate (100) using a layer (112) or region (130) of porous silicon that is created in the bulk silicon substrate material (110) to increase the resistivity of the substrate (100) thus making it suitable for passive component integration directly on the motherboard (200) or chip (230) and useful for high frequency applications due to its low loss, low dielectric properties. One or more passive components such as inductors (214), resistors (212) and capacitors (216) can be integrated on the device (140) over the porous silicon region (130). The high resistivity of the device makes it ideal for integration on a single platform using conventional wafer fab processes since loss at radio frequencies is comparably less when compared to a pure silicon substrate.

Abstract: The invention relates to an improved substrate (100) using a layer (112) or region (130) of porous silicon that is created in the bulk silicon substrate material (110) to increase the resistivity of the substrate (100) thus making it suitable for passive component integration directly on the motherboard (200) or chip (230) and useful for high frequency applications due to its low loss, low dielectric properties. One or more passive components such as inductors (214), resistors (212) and capacitors (216) can be integrated on the device (140) over the porous silicon region (130). The high resistivity of the device makes it ideal for integration on a single platform using conventional wafer fab processes since loss at radio frequencies is comparably less when compared to a pure silicon substrate.