Abstract: A method of performing a function on a three-dimensional semiconductor chip package as well as on individual chips in the package is disclosed. That method involves the creation of an operative relationship between a function performer and an edge feature on the chip or chips wherein the edge feature consists of one or more of an electrically conductive pad, thermally conductive pad, a probe pad, a fuse, a resistor, a capacitor, an inductor, an optical emitter, an optical receiver, a test pad, a bond pad, a contact pin, a heat dissipator, an alignment marker, a metrology feature and a function performer may be any one or more of a test probe, the laser, a programming device, an interrogation device, a loading device or a tuning device. In addition, a chip per se with edge features is disclosed along with a three-dimensional stack of such chips in either of several different configurations.

Abstract: An apparatus for providing an electrical bias to a substrate in a processing system is described. The apparatus generally includes a conductive annular body defining a central opening. The conductive annular body may have a substrate seating surface adapted to receive the substrate and a plurality of scallops formed on a surface opposing the substrate seating surface. A plurality of electrical contacts may be formed on the substrate seating surface opposite the plurality of scallops. The electrical contacts may be adapted to engage a plating surface of the substrate.

Abstract: A method of planarizing a metal conductive layer on a substrate is provided. In one embodiment, a substrate having a metal conductive layer disposed on a top surface of the substrate is provided on a substrate support. The substrate support is rotated and the top surface of the substrate is contacted with a liquid etching composition. The metal conductive layer is then exposed to an etchant gas in order to planarize the top surface of the metal conductive layer. Also provided is an apparatus for etching a metal conductive layer on a substrate. The apparatus comprises a container, a substrate support disposed in the container, a rotation actuator attached to the substrate support, and a fluid delivery assembly disposed in the container.

Abstract: An apparatus for providing an electrical bias to a substrate in a processing system is described. The apparatus generally includes a conductive annular body defining a central opening. The conductive annular body may have a substrate seating surface adapted to receive the substrate and a plurality of scallops formed on a surface opposing the substrate seating surface. A plurality of electrical contacts may be formed on the substrate seating surface opposite the plurality of scallops. The electrical contacts may be adapted to engage a plating surface of the substrate.

Abstract: Method and apparatus for electrodepositing a metal onto a substrate. An oxide treatment process is performed on a substrate prior to making electrical contact between a seed layer of the substrate and a conductive contact element which provides a current. In one embodiment, the pressure at the interface between the seed layer and the conductive contact element is controlled to avoid detrimentally affecting a material(s) of the substrate.

Abstract: A method of planarizing a metal conductive layer on a substrate is provided. In one embodiment, a substrate having a metal conductive layer disposed on a top surface of the substrate is provided on a substrate support. The substrate support is rotated and the top surface of the substrate is contacted with a liquid etching composition. The metal conductive layer is then exposed to an etchant gas in order to planarize the top surface of the metal conductive layer. Also provided is an apparatus for etching a metal conductive layer on a substrate. The apparatus comprises a container, a substrate support disposed in the container, a rotation actuator attached to the substrate support, and a fluid delivery assembly disposed in the container.

Abstract: A method in a plasma processing chamber for etching through a selected portion of a metallization layer of a wafer's layer stack. The method includes the step of etching at least partially through the metallization layer of the layer stack with an etchant source gas that consists essentially of chlorine and nitrogen. In another embodiment, the metallization layer comprises aluminum, and the flow ratio of the chlorine to the nitrogen ranges from about 1:1 to about 10:1. More preferably, the flow ratio of the chlorine to the nitrogen ranges from about 1:1 to about 4:1 and preferably ranges from about 1:1 to about 2:1.

Abstract: A method of etching a multicomponent alloy on a substrate, without forming etchant residue on the substrate, is described. In the method, the substrate is placed in a process chamber comprising a plasma generator and plasma electrodes. A process gas comprising a volumetric flow ratio V.sub.r of (i) a chlorine-containing gas capable of ionizing to form dissociated Cl.sup.+ plasma ions and non-dissociated Cl.sub.2.sup.+ plasma ions, and (ii) an inert gas capable of enhancing dissociation of the chlorine-containing gas, in introduced into the process chamber. The process gas is ionized to form plasma ions that energetically impinge on the substrate by (i) applying RF current at a first power level to the plasma generator, and (ii) applying RF current at a second power level to the plasma electrodes. The combination of (i) the volumetric flow ratio V.sub.r of the process gas and (ii) the power ratio P.sub.