Disclosed herein are methods for electroplating which employ seed layer detection. Such methods may operate by selecting a wafer, illuminating one or more points within an interior region of the wafer surface, measuring a first set of one or more in-process color signals from the one or more points within the interior region, illuminating one or more points within an edge region of the wafer surface, measuring a second set of one or more in-process color signals from the one or more points within the edge region, each color signal having one or more color components, calculating a metric indicative of a difference between the color signals in the first and second sets of in-process color signals, determining whether an acceptable seed layer is present on the wafer based on whether the metric is within a predetermined range, and repeating the foregoing for one or more additional wafers.

A pumping line arrangement includes a chamber connecting line which is fluidly connectable to a process chamber that forms part of a semiconductor fabrication tool. The pumping line arrangement also includes a valve module which is fluidly connected to the chamber connecting line. The valve module splits the chamber connecting line into respective first and second pumping lines. The first pumping line is intended to carry a first process flow and the second pumping line is intended to carry a second process flow which is incompatible with the first process flow. At least one of the first pumping line or the second pumping line includes fluidly connected therewithin a pre-abatement module that is configured to remove one or more incompatible constituents from the process flow intended to be carried by the other pumping line.

A method for sawing a semiconductor wafer is provided. The method includes sawing a semiconductor wafer to form a first opening. In addition, the semiconductor wafer includes a dicing tape and a substrate attached to the dicing tape by a die attach film (DAF), and the first opening is formed in an upper portion of the substrate. The method further includes sawing through the substrate and the DAF of the semiconductor wafer from the first opening to form a middle opening under the first opening and a second opening under the middle opening, so that the semiconductor wafer is divided into two dies. In addition, a slope of a sidewall of the middle opening is different from slopes of sidewalls of the first opening and the second opening.

A charge volume configuration for use in delivery of gas to a reactor for processing semiconductor wafers is provided. A charge volume includes a chamber that extends between a proximal end and a distal end. A base connected to the proximal end of the chamber, and the base includes an inlet port and an outlet port. A tube is disposed within the chamber. The tube has a tube diameter that is less than a chamber diameter. The tube has a connection end coupled to the inlet port at the proximal end of the chamber and an output end disposed at the distal end of the chamber.

A pedestal for a substrate processing system includes a pedestal body including a substrate-facing surface. An annular band is arranged on the substrate-facing surface that is configured to support a radially outer edge of the substrate. A cavity is defined in the substrate-facing surface of the pedestal body and is located radially inside of the annular band. The cavity creates a volume between a bottom surface of the substrate and the substrate-facing surface of the pedestal body. A plurality of vents pass through the pedestal body and are in fluid communication with the cavity to equalize pressure on opposing faces of the substrate during processing.

The present disclosure relates to a debonding apparatus. In some embodiments, the debonding apparatus comprises a wafer chuck configured to hold a pair of bonded substrates on a chuck top surface. The debonding apparatus further comprises a pair of separating blades including a first separating blade and a second separating blade placed at edges of the pair of bonded substrates. The first separating blade has a first thickness that is smaller than a second thickness of the second separating blade. The debonding apparatus further comprises a flex wafer assembly configured to pull the pair of bonded substrates upwardly to separate a second substrate from a first substrate of the pair of bonded substrate. By providing unbalanced initial torques on opposite sides of the bonded substrate pair, edge defects and wafer breakage are reduced.

Disclosed herein are a wafer purging-type shelf assembly and a buffer module having the same. The wafer purging-type shelf assembly includes: a shelf formed to support a wafer receiving container; a supply nozzle configured to be connected to an injection port of the wafer receiving container; and a gas supply line configured to supply an inert gas discharged from a factory gas facility to the wafer receiving container through the supply nozzle, wherein the gas supply line includes a proportional pressure control valve unit that adjusts a supply flow rate of the inert gas to the wafer receiving container by an area control method.

An apparatus including a dot matrix transfer head that includes an impact wire housing. A plurality of impact wires are disposed within the impact wire housing and extend out of the impact wire housing. A splaying element attached to a bottom surface of the impact wire housing. The plurality of impact wires extend into and through the splaying element. A guide head attached to a bottom surface of the splaying element. The guide head includes multiple holes that arrange the plurality of impact wires in a matrix configuration. The splaying element is designed to direct the plurality of impact wires toward the multiple holes in the guide head.

A substrate processing system includes a first chamber including a substrate support. A showerhead is arranged above the first chamber and is configured to filter ions and deliver radicals from a plasma source to the first chamber. The showerhead includes a heat transfer fluid plenum including an inlet to receive heat transfer fluid and a plurality of flow channels to direct the heat transfer fluid through a center portion of the showerhead to an outlet to control a temperature of the showerhead, a secondary gas plenum including an inlet to receive secondary gas and a plurality of secondary gas injectors to inject the secondary gas into the first chamber, and a plurality of through holes passing through the showerhead. The through holes are not in fluid communication with the heat transfer fluid plenum or the secondary gas plenum.

A reticle container for containing a reticle including a base plate having one or more windows. Each of the windows can include mounting recess having a recess sidewall including an undercut defined therein. A transparent substrate can be disposed in the mounting recess and is retained therein by a retention member having an arcuate portion extending between a first end portion and a second end portion. At least the first end portion of the retention member can be positioned in the undercut defined in the recess sidewall such that the arcuate portion of the retention member contacts the transparent substrate to retain the transparent substrate in the mounting recess.