Abstract: A method and apparatus for forming a semiconductor sheet suitable for use as a solar cell by depositing an array of solidified drops of a feed material on a sheet support. The desired properties of the sheet fabricated with the teaching of this invention are: flatness, low residual stress, minority carrier diffusion length greater than 40 microns, and minimum grain dimension at least two times the minority carrier diffusion length. In one embodiment, the deposition chamber is adapted to form and process sheets that have a surface area of about 1,000-2,400 cm2.

Abstract: A method and apparatus for forming a semiconductor sheet suitable for use as a solar cell by depositing an array of solidified drops of a feed material on a sheet support. The desired properties of the sheet fabricated with the teaching of this invention are: flatness, low residual stress, minority carrier diffusion length greater than 40 microns, and minimum grain dimension at least two times the minority carrier diffusion length. In one embodiment, the deposition chamber is adapted to form and process sheets that have a surface area of about 1,000-2,400 cm2.

Abstract: An electro-negative cleaning or etchant gas, such as fluorine, that was ionized from a stable supply gas such as NH3 in a secondary chamber and recombined in the primary chamber, is re-ionized within the primary chamber by electron attachment by ionizing an electron donor gas, such as helium, in the primary chamber.

Abstract: An electrical coupler comprises an inner connector having upper and lower ends, an insulative outer connector element circumscribing the inner connector, and a thermally conductive flange disposed over the upper end of the inner connector and the outer connector for conducting heat from the electrical conductor. The electrical conductor may be utilized in a substrate support for semiconductor wafer processing. The substrate support comprises a chuck body having an electrode embedded therein, and an upper male connector coupled to the electrode and protruding from said chuck body. A cooling plate having the electrical coupler is positioned proximate to the chuck body. The upper male connector is inserted in the electrical coupler, and a power source coupled to the lower portion of the electrical coupler chucks and biases a wafer to an upper surface of said chuck. The thermally conductive flange conducts and transfers heat generated from the upper male connector and electrical coupler to the cooling plate.

Abstract: An apparatus for and method of rinsing one side of a two-sided substrate and removing unwanted material from the substrate's edge and/or backside. One embodiment of the method is directed toward rinsing and cleaning a substrate having a front side upon which integrated circuits are to be formed and a backside. This embodiment includes dropping the substrate front side down onto a pool of rinsing liquid in a manner such that the front side of the substrate is in contact with the solution while the substrate is held in suspension by the surface tension of the solution liquid thereby preventing the backside of the substrate from sinking under an upper surface of the pool. Next, while the substrate is in suspension in said rinsing liquid, the substrate is secured by its edge with a first set of fingers and in some embodiments the substrate is subsequently spun. In another embodiment, a method of forming a copper layer on a front side of a substrate is disclosed.

Abstract: A substrate processing chamber has a substrate support to support a substrate, and an exhaust conduit about the substrate support. A first process gas distributor directs a first process gas, such as a non-reactive gas, about the substrate perimeter and toward the exhaust conduit at a first flow rate to form a curtain of non-reactive gas about the substrate. A second process gas distributor directs a second process gas, such as reactive CVD or etchant gas, toward a central portion of the substrate at a second flow rate which is lower than the first flow rate. A gas energizer energizes the first and second process gases in the chamber. A controller operates the substrate support, gas flow meters, gas energizer, and throttle valve, to process the substrate in the energized gas.

Abstract: An electro-negative cleaning or etchant gas, such as fluorine, that was ionized from a stable supply gas such as NH3 in a secondary chamber and recombined in the primary chamber, is re-ionized within the primary chamber by electron attachment by ionizing an electron donor gas, such as helium, in the primary chamber.

Abstract: A substrate processing chamber has a substrate support to support a substrate, and an exhaust conduit about the substrate support. A first process gas distributor directs a first process gas, such as a non-reactive gas, about the substrate perimeter and toward the exhaust conduit at a first flow rate to form a curtain of non-reactive gas about the substrate. A second process gas distributor directs a second process gas, such as reactive CVD or etchant gas, toward a central portion of the substrate at a second flow rate which is lower than the first flow rate. A gas energizer energizes the first and second process gases in the chamber. A controller operates the substrate support, gas flow meters, gas energizer, and throttle valve, to process the substrate in the energized gas.

Abstract: An apparatus for and method of rinsing one side of a two-sided substrate and removing unwanted material from the substrate's edge and/or backside. One embodiment of the method is directed toward rinsing and cleaning a substrate having a front side upon which integrated circuits are to be formed and a backside. This embodiment includes dropping the substrate front side down onto a pool of rinsing liquid in a manner such that the front side of the substrate is in contact with the solution while the substrate is held in suspension by the surface tension of the solution liquid thereby preventing the backside of the substrate from sinking under an upper surface of the pool. Next, while the substrate is in suspension in said rinsing liquid, the substrate is secured by its edge with a first set of fingers and in some embodiments the substrate is subsequently spun. In another embodiment, a method of forming a copper layer on a front side of a substrate is disclosed.

Abstract: Apparatus for securing a substrate in an electrochemical deposition system are provided. In one aspect, an apparatus is provided for securing a substrate in an electrochemical deposition system having a contact ring for contacting a plating surface of the substrate, a thrust plate having an annular shoulder at least partially formed therein, the thrust plate adapted to move axially relative to the contact surface, and a flexible seal disposed on the thrust plate comprising a base portion for attaching to the annular shoulder of the thrust plate and a body portion extending outwardly from the base portion and defining a sealing surface for engaging a back surface of the substrate. The apparatus may be disposed in an electrochemical deposition system.

Abstract: Generally, an electrostatic chuck having a dielectric coating is provided. In one embodiment, an electrostatic chuck includes a support surface, a mounting surface disposed opposite the support surface and at least one side separating the support surface and the mounting surface which defines a support body. One or more conductive members are disposed within the support body to generate an electrostatic attraction between the body and a substrate disposed thereon. A dielectric coating is disposed on the mounting surface of the support body to minimize undesired current leakage therethrough. Optionally, the dielectric coating may be additionally disposed on one or more of the sides and/or the support surface.

Abstract: A ceramic substrate support and methods for fabricating the same are provided. In one embodiment, a ceramic substrate support for supporting a substrate includes a ceramic body and a porous member disposed therein. The ceramic body generally has an upper portion and a lower portion. The upper portion includes a support surface while the lower portion includes a bottom surface. At least one passage is disposed in the lower portion of the ceramic body. A first end of the passage is at least partially closed by the upper portion of the ceramic body. At least one outlet is disposed through the portion of the ceramic body through the upper portion of the ceramic body and fluidly couples the passage to the support surface.