Abstract: A sputtering system and method are disclosed. The system includes first power source coupled to a first magnetron and an anode, and the first power source provides a first anode voltage that alternates between positive and negative during each of multiple cycles. The system also includes a second power source coupled to the second magnetron and the anode, and the second power source provides a second anode voltage that alternates between positive and negative during each of the multiple cycles. A controller of the system controls the first power source and the second power source to phase-synchronize the first anode voltage with the second anode voltage, so both, the first anode voltage and the second anode voltage, are simultaneously negative during a portion of each cycle and simultaneously positive relative to the first and second magnetrons during another portion of each cycle.

Abstract: A sputtering system and method are disclosed. The system includes first power source coupled to a first magnetron and an anode, and the first power source provides a first anode voltage that alternates between positive and negative during each of multiple cycles. The system also includes a second power source coupled to the second magnetron and the anode, and the second power source provides a second anode voltage that alternates between positive and negative during each of the multiple cycles. A controller of the system controls the first power source and the second power source to phase-synchronize the first anode voltage with the second anode voltage, so both, the first anode voltage and the second anode voltage, are simultaneously negative during a portion of each cycle and simultaneously positive relative to the first and second magnetrons during another portion of each cycle.

Abstract: A pulsed direct current sputtering system and method are disclosed. The system has a plasma chamber with two targets, two magnetrons and one anode, a first power source, and a second power source. The first power source is coupled to the first magnetron and the anode, and provides a cyclic first-power-source voltage with a positive potential and a negative potential during each cycle between the anode and the first magnetron. The second power source is coupled to the second magnetron and the anode, and provides a cyclic second-power-source voltage. The controller phase-synchronizes and controls the first-power-source voltage and second-power-source voltage to apply a combined anode voltage, and phase-synchronizes a first magnetron voltage with a second magnetron voltage, wherein the combined anode voltage applied to the anode has a magnitude of at least 80 percent of a magnitude of a sum of the first magnetron voltage and the second magnetron voltage.

Abstract: A pulsed direct current sputtering system and method are disclosed. The system has a plasma chamber with two targets, two magnetrons and one anode, a first power source, and a second power source. The first power source is coupled to the first magnetron and the anode, and provides a cyclic first-power-source voltage with a positive potential and a negative potential during each cycle between the anode and the first magnetron. The second power source is coupled to the second magnetron and the anode, and provides a cyclic second-power-source voltage. The controller phase-synchronizes and controls the first-power-source voltage and second-power-source voltage to apply a combined anode voltage, and phase-synchronizes a first magnetron voltage with a second magnetron voltage, wherein the combined anode voltage applied to the anode has a magnitude of at least 80 percent of a magnitude of a sum of the first magnetron voltage and the second magnetron voltage.