Abstract: A system for processing semiconductor wafers has process units on a deck of a frame. The process units and the deck have precision locating features, such as tapered pins, for precisely positioning the process units on the deck. Process units can be removed and replacement process units installed on the deck, without the need for recalibrating the load/unload robot. This reduces the time needed to replace process units and restart processing operations. Liquid chemical consumption during processing is reduced by drawing unused liquid out of supply lines and pumping it back to storage.

Abstract: One embodiment of the present invention provides a system that facilitates routing nets between cells in a circuit layout. During operation, the system receives a circuit design to be routed, wherein the circuit design includes multiple circuit blocks that have been placed at specific locations within the circuit layout. Next, the system determines estimated lengths for nets that couple these circuit blocks together. The system then calculates the delay for the nets that couple the circuit blocks using a class one rule. If the delay in a given net is greater than a specified delay, the system inserts a virtual repeater into the given net to decrease the delay.

Abstract: A disclosed embodiment comprises patterning a conductor in a dielectric in a semiconductor die. The dielectric can be, for example, silicon oxide or a low-k dielectric while the conductor can comprise aluminum, copper, or a copper-aluminum alloy. Thereafter, a blanket of high permeability layer is deposited over the dielectric. The high permeability layer can comprise high permeability materials such as nickel, iron, nickel-iron alloy, or a magnetic oxide. The blanket deposition of the high permeability layer can be accomplished by, for example, a sputtering technique. After depositing the high permeability layer, a portion of the atoms or molecules in the high permeability layer is driven into the underlying dielectric to increase the permeability of the dielectric. As an example, an ion implanter using heavy ions such as silicon ions or germanium ions can be used to drive some of the atoms or molecules in the high permeability layer into the underlying dielectric.

Abstract: A method for processing a semiconductor wafer or similar article includes the step of spinning the wafer and applying a fluid to a first side of the wafer, while it is spinning. The fluid flows radially outwardly in all directions, over the first side of the wafer, via centrifugal force. As the fluid flows off of the circumferential edge of the wafer, it is contained in an annular reservoir, so that the fluid also flows onto an outer annular area of the second side of the wafer. An opening allows fluid to flow out of the reservoir. The opening defines the location of a parting line beyond which the fluid will not travel on the second side of the wafer. An apparatus for processing a semiconductor wafer or similar article includes a reactor having a processing chamber formed by upper and lower rotors. The wafer is supported between the rotors. The rotors are rotated by a spin motor. A processing fluid is introduced onto the top or bottom surface of the wafer, or onto both surfaces, at a central location.

Abstract: A method of fabricating a FET having a gate electrode with reduced susceptibility to the carrier depletion effect, includes increasing the amount of n-type dopant in the gate electrode of an n-channel FET. In one embodiment of the present invention, an integrated circuit including NFETs and PFETs is produced with increased n-type doping in the n-channel FET gate electrodes without the use of additional photomasking operations. Prior to polysilicon patterning, a phosphorus doped silica glass (PSG) is deposited over the polysilicon. Subsequent to patterning of the polysilicon, NFET areas are masked, and exposed PFET areas subjected to source/drain extension implant operations. During this sequence, the PSG is removed from PFET areas but remains in the NFET areas. An anneal is performed to drive the phosphorus from the PSG into the NFET gate electrodes. NFET source/drain extensions are formed, and conventional MOSFET processing operations may then be performed to complete the integrated circuit.

Abstract: The present invention is directed to a method of forming conductive interconnections in an integrated circuit device to optimize or at least maintain the speed at which signals propagate throughout the integrated circuit device. In one embodiment, the method comprises determining any variation in the size of a contact, as compared to its design size, and varying the size of a conductive line to be coupled to the contact based upon the variation in the size of the contact.

Abstract: The present invention is directed to a method of forming conductive interconnections in an integrated circuit device. In one embodiment, the method comprises forming a dielectric stack comprised of multiple layers, and determining a thickness ratio of the layers of the stack. The method further comprises determining an etching process to be performed on the dielectric stack to define an opening for a conductive interconnection based upon the determined thickness ration, and performing the determined etch process on the dielectric stack.

Abstract: Electro-optical device characterized by having been formed into an individual unit with an integral optical element, and method to form the device. An optical element, for instance a length of cylindrical microlens, is aligned with a diode strip having a plurality of diodes, for instance laser diodes, and attached to the lens. Subsequent to this attachment, the composite structure consisting of the diode strip having attached to it the lens is sectioned into individual diodes, each of which has a integral lens attached thereto.