Abstract: The present invention generally comprises one or more cooled anodes shadowing one or more gas introduction tubes where both the cooled anodes and the gas introduction tubes span a processing space defined between one or more sputtering targets and one or more substrates within a sputtering chamber. The gas introduction tubes may have gas outlets that direct the gas introduced away from the one or more substrates. The gas introduction tubes may introduce reactive gas, such as oxygen, into the sputtering chamber for depositing TCO films by reactive sputtering. During a multiple step sputtering process, the gas flows (i.e., the amount of gas and the type of gas), the spacing between the target and the substrate, and the DC power may be changed to achieve a desired result.

Abstract: A physical vapor deposition (PVD) apparatus and a PVD method are disclosed. Extending an anode across the processing space between the target and the substrate may increase deposition uniformity on a substrate. The anode provides a path to ground for electrons that are excited in the plasma and may uniformly distribute the electrons within the plasma across the processing space rather than collect at the chamber walls. The uniform distribution of the electrons within the plasma may create a uniform deposition of material on the substrate. The anodes may be cooled with a cooling fluid to control the temperature of the anodes and reduce flaking. The anodes may be disposed across the process space perpendicular to the long side of a magnetron that may scan in two dimensions across the back of the sputtering target. The scanning magnetron may reduce localized heating of the anode.