Abstract: A gas injection system for a chemical vapor deposition system includes a gas manifold comprising a plurality of valves where each of the plurality of valves has an input that is coupled to a process gas source and an output for providing process gas. Each of a plurality of gas injectors has an input that is coupled to the output of one of the plurality of valves and an output that is positioned in one of a plurality of zones in a chemical vapor deposition reactor. A controller having a plurality of outputs where each of the plurality of outputs is coupled to a control input of one of the plurality of valves. The controller instructs at least some of the plurality of valves to open at predetermined times to provide a desired gas flow to each of the plurality of zones in the chemical vapor deposition reactor.

Abstract: A linear cluster deposition system includes a plurality of reaction chambers positioned in a linear horizontal arrangement. First and second reactant gas manifolds are coupled to respective process gas input port of each of the reaction chambers. An exhaust gas manifold having a plurality of exhaust gas inputs is coupled to the exhaust gas output port of each of the plurality of reaction chambers. A substrate transport vehicle transports at least one of a substrate and a substrate carrier that supports at least one substrate into and out of substrate transfer ports of each of the reaction chambers. At least one of a flow rate of process gas into the process gas input port of each of the reaction chambers and a pressure in each of the reaction chambers being chosen so that process conditions are substantially the same in at least two of the reaction chambers.

Abstract: A stressor layer is applied to a semiconducting stack in order to separate the semiconducting stack at a predetermined depth. Tensile force is applied to the stressor layer, fracturing the semiconducting stack at the predetermined depth and allowing the resulting upper portion of the semiconducting stack to be used in manufacturing a semiconducting end-product (e.g., a light-emitting diode). The resulting lower portion of the semiconducting stack may be reused to grow a new semiconducting stack thereon.

Abstract: An ion etch assisted deposition apparatus deposits a thin film upon a substrate having a three dimensional feature, using an ion etching source and deposition source arranged at similar angles relative to the substrate and at an angle ? relative to each other. The angle ? is selected to be substantially equal the supplement of the angle ?? formed between the three dimensional feature on the substrate and the substrate surface. In this configuration the relative flux of energetic etch ions and deposition atoms is adjusted to prevent the growth of poor quality deposited material.

Abstract: A method of modifying a substrate carrier to improve process performance includes depositing material or fabricating devices on a substrate supported by a substrate carrier. A parameter of layers deposited on the substrate is then measured as a function of their corresponding positions on the substrate carrier. The measured parameter of at least some devices fabricated on the substrate or a property of the deposited layers is related to a physical characteristic of substrate carrier to obtain a plurality of physical characteristics of the substrate carrier corresponding to a plurality of positions on the substrate carrier. The physical characteristic of the substrate carrier is then modified at one or more of the plurality of corresponding positions on the substrate carrier to obtain desired parameters of the deposited layers or fabricated devices as a function of position on the substrate carrier.

Abstract: Wafer treatment process and apparatus is provided with a wafer carrier arranged to hold wafers and to inject a fill gas into gaps between the wafers and the wafer carrier. The apparatus is arranged to vary the composition, flow rate, or both of the fill gas so as to counteract undesired patterns of temperature non-uniformity of the wafers.

Abstract: A gas injection system for a chemical vapor deposition system includes a gas manifold comprising a plurality of valves where each of the plurality of valves has an input that is coupled to a process gas source and an output for providing process gas. Each of a plurality of gas injectors has an input that is coupled to the output of one of the plurality of valves and an output that is positioned in one of a plurality of zones in a chemical vapor deposition reactor. A controller having a plurality of outputs where each of the plurality of outputs is coupled to a control input of one of the plurality of valves. The controller instructs at least some of the plurality of valves to open at predetermined times to provide a desired gas flow to each of the plurality of zones in the chemical vapor deposition reactor.

Abstract: Method and apparatus for processing a substrate with an energetic particle beam. Features on the substrate are oriented relative to the energetic particle beam and the substrate is scanned through the energetic particle beam. The substrate is periodically indexed about its azimuthal axis of symmetry, while shielded from exposure to the energetic particle beam, to reorient the features relative to the major dimension of the beam.

Abstract: An MOCVD reactor such as a rotating disc reactor (10) is equipped with a gas injector head having diffusers (129) disposed between adjacent gas inlets. The diffusers taper in the downstream direction. The injector head desirably has inlets (117) for a first gas such as a metal alkyl disposed in radial rows which terminate radially inward from the reactor wall to minimize deposition of the reactants on the reactor wall. The injector head desirably also has inlets (125) for a second gas such as ammonia arranged in a field between the rows of first gas inlets, and additionally has a center inlet (135) for the second gas coaxial with the axis of rotation.

Abstract: Wafer carrier arranged to hold a plurality wafers and to inject a fill gas into gaps between the wafers and the wafer carrier for enhanced heat transfer and to promote uniform temperature of the wafers. The apparatus is arranged to vary the composition, flow rate, or both of the fill gas so as to counteract undesired patterns of temperature non-uniformity of the wafers. In various embodiments, the wafer carrier utilizes at least one plenum structure contained within the wafer carrier to source a plurality of weep holes for passing a fill gas into the wafer retention pockets of the wafer carrier. The plenum(s) promote the uniformity of the flow, thus providing efficient heat transfer and enhanced uniformity of wafer temperatures.

Abstract: A method of modifying a substrate carrier to improve process performance includes depositing material or fabricating devices on a substrate supported by a substrate carrier. A parameter of layers deposited on the substrate is then measured as a function of their corresponding positions on the substrate carrier. The measured parameter of at least some devices fabricated on the substrate or a property of the deposited layers is related to a physical characteristic of substrate carrier to obtain a plurality of physical characteristics of the substrate carrier corresponding to a plurality of positions on the substrate carrier. The physical characteristic of the substrate carrier is then modified at one or more of the plurality of corresponding positions on the substrate carrier to obtain desired parameters of the deposited layers or fabricated devices as a function of position on the substrate carrier.

Abstract: Wafer carriers and methods for moving wafers in a reactor. The wafer carrier may include a platen with a plurality of compartments and a plurality of wafer platforms. The platen is configured to rotate about a first axis. Each of the wafer platforms is associated with one of the compartments and is configured to rotate about a respective second axis relative to the respective compartment. The platen and the wafer platforms rotate with different angular velocities to create planetary motion therebetween. The method may include rotating a platen about a first axis of rotation. The method further includes rotating each of a plurality of wafer platforms carried on the platen and carrying the wafers about a respective second axis of rotation and with a different angular velocity than the platen to create planetary motion therebetween.

Abstract: A gas flow flange includes a first and a second section. The first section includes a plurality of first gas channels positioned inside and parallel to a top surface. A plurality of second gas input channels are positioned perpendicular to the top surface and extending from the top surface to the bottom surface. Each of the plurality of first gas input channels are aligned with an output of a corresponding one of the plurality of first gas input channels. The second section includes a plurality of second gas input channels that are positioned perpendicular to and extending from the top surface to the bottom surface of the second section. Each of the plurality of second gas input channels are aligned with a corresponding one of the plurality of second gas input channels. Fluid cooling conduits are positioned perpendicular to the top surface of the second section.

Abstract: A method of in-situ temperature measurement for a wafer treatment reactor such as a chemical vapor deposition reactor desirably includes the steps of heating the reactor until the reactor reaches a wafer treatment temperature and rotating a wafer support element within the reactor about a rotational axis. The method desirably further includes, while the wafer support element is rotating about the rotational axis, obtaining first operating temperature measurements using a first operating pyrometer that receives radiation from a first portion of the wafer support element, and obtaining first wafer temperature measurements using a wafer temperature measurement device that receives radiation from at least one wafer, the wafer temperature measurement device located at a first position.

Abstract: The present invention provides deposition sources that can efficiently and controllably provide vaporized material for deposition of thin film materials. Deposition sources described herein can be used to deposit any desired material and are particularly useful for depositing high melting point materials at high evaporation rates. An exemplary application for deposition sources of the present invention is deposition of copper, indium, and gallium in the manufacture of copper indium gallium diselenide based photovoltaic devices.

Abstract: In a sputter deposition tool (100) of the type in which an ion source (101) generates a beam directed at a sputtering target, the sputtering target comprises an elongated exterior skirt (102) and a generally circular insert (103) positioned within the skirt, the surfaces of the skirt and insert being relatively coplanar and forming the surface of the target, with the elongated dimension of the skirt being axially oriented toward the ion source. The insert is rotated within the skirt to one of several positions during use of the target by the sputter deposition tool, to distribute wear of the target around the rotating insert and thus increase the utilization and useful life of the overall target assembly.

Abstract: An apparatus and method for controlling stray radiation within a CVD chamber. A heater array disposed beneath a wafer carrier for radiatively heating of the wafer carrier includes a peripheral or outermost heating element or elements. Scattered radiation originating from a designated segment of the peripheral heating element(s) can be reduced locally by one of several mechanisms, including reducing the emission (e.g., operating temperature) of the designated segment, or capturing or deflecting a portion of the radiation originating from the designated segment. In one embodiment, an electrical connector on a resistance heating element provides the reduced emission from the designated segment. It has been found that radiation thermometers fixed proximate an axis that extends from the center of the wafer carrier and across the designated segment is subject to less stray radiation, thus providing a more reliable temperature reading in the optical wavelengths.

Abstract: The present invention provides deposition sources, systems, and related methods that can efficiently and controllably provide vaporized material for deposition of thin-film materials. The deposition sources, systems and related methods described herein can be used to deposit any desired material and are particularly useful for depositing high vapor pressure materials such as selenium in the manufacture of copper indium gallium diselenide based photovoltaic devices.