Abstract: An apparatus and methods for plasma-based sputtering deposition using a direct current power supply is disclosed. In one embodiment, a plasma is generated by connecting a plurality of electrodes to a supply of current, and a polarity of voltage applied to each of a plurality of electrodes in the processing chamber is periodically reversed so that at least one of the electrodes sputters material on to the substrate. And an amount of power that is applied to at least one of the plurality of electrodes is modulated so as to deposit the material on the stationary substrate with a desired characteristic. In some embodiments, the substrate is statically disposed in the chamber during processing. And many embodiments utilize feedback indicative of the state of the deposition to modulate the amount of power applied to one or more electrodes.

Abstract: An apparatus and methods for plasma-based sputtering deposition using a direct current power supply is disclosed. In one embodiment, a plasma is generated by connecting a plurality of electrodes to a supply of current, and a polarity of voltage applied to each of a plurality of electrodes in the processing chamber is periodically reversed so that at least one of the electrodes sputters material on to the substrate. And an amount of power that is applied to at least one of the plurality of electrodes is modulated so as to deposit the material on the stationary substrate with a desired characteristic. In some embodiments, the substrate is statically disposed in the chamber during processing. And many embodiments utilize feedback indicative of the state of the deposition to modulate the amount of power applied to one or more electrodes.

Abstract: An apparatus and methods for plasma-based sputtering deposition using a direct current power supply is disclosed. In one embodiment, a plasma is generated by connecting a plurality of electrodes to a supply of current, and a polarity of voltage applied to each of a plurality of electrodes in the processing chamber is periodically reversed so that at least one of the electrodes sputters material on to the substrate. And an amount of power that is applied to at least one of the plurality of electrodes is modulated so as to deposit the material on the stationary substrate with a desired characteristic. In some embodiments, the substrate is statically disposed in the chamber during processing. And many embodiments utilize feedback indicative of the state of the deposition to modulate the amount of power applied to one or more electrodes.

Abstract: An apparatus and methods for plasma-based sputtering deposition using a direct current power supply is disclosed. In one embodiment, a plasma is generated by connecting a plurality of electrodes to a supply of current, and a polarity of voltage applied to each of a plurality of electrodes in the processing chamber is periodically reversed so that at least one of the electrodes sputters material on to the substrate. And an amount of power that is applied to at least one of the plurality of electrodes is modulated so as to deposit the material on the stationary substrate with a desired characteristic. In some embodiments, the substrate is statically disposed in the chamber during processing. And many embodiments utilize feedback indicative of the state of the deposition to modulate the amount of power applied to one or more electrodes.

Abstract: There is provided by this invention an apparatus and method for controlling a dc magnetron plasma processing system that automatically adjusts the control signal to the power supply based upon the dynamic impedance of the load to control the output power to the plasma. The output voltage and the output current of the power supply that supplies power to the plasma is sampled over at a sampling frequency at least four to five times higher than the switching frequency and the dynamic impedance of the plasma is calculated based upon the sampled voltage and current from the algorithm R plasma = ? ? ? V n ? ? ? I n wherein ?Vn and ?In is the maximum difference among samples on one switching cycle. If the dynamic impedance seen is negative in nature then the control signal is compensated accordingly.

Abstract: There is provided by this invention novel magnetron sputtering apparatus that is generally comprised of a pulsed dc power supply capable of delivering peak powers of 0.1 megaWatts to several megaWatts with a peak power density greater than 1 kW/cm2. The power supply has a pulsing circuit comprised of an energy storage capacitor and serially connected inductor with a switching means for disconnecting the pulsing circuit from the plasma and recycling the inductor energy back to the energy storage capacitor at the detection of an arc condition. The energy storage capacitor and the serially connected inductor provide an impedance match to the plasma, limits the current rate of rise and peak magnitude in the event of an arc, and shapes the voltage pulses to the plasma.

Abstract: A magnetron sputtering system is provided comprising a pulsed DC power supply capable of delivering peak powers of 0.1 megawatts to several megawatts with a peak power density greater than 1 kW/cm2. A sputtering plasma in a highly ionized state is created without first adopting an arc discharge state. The power supply has a pulsing circuit comprising an energy storage capacitor and serially connected inductor with a switching means for disconnecting the pulsing circuit from the plasma and recycling the inductor energy back to the energy storage capacitor at the detection of an arc condition. The energy storage capacitor and the serially connected inductor provide an impedance match to the plasma, limits the current rate of rise and peak magnitude in the event of an arc, and shapes the voltage pulses to the plasma.

Abstract: There is provided by this invention novel magnetron sputtering apparatus that is generally comprised of a pulsed dc power supply capable of delivering peak powers of 0.1 megaWatts to several megaWatts with a peak power density greater than 1 kW/cm2. The power supply has a pulsing circuit comprised of an energy storage capacitor and serially connected inductor with a switching means for disconnecting the pulsing circuit from the plasma and recycling the inductor energy back to the energy storage capacitor at the detection of an arc condition. The energy storage capacitor and the serially connected inductor provide an impedance match to the plasma, limits the current rate of rise and peak magnitude in the event of an arc, and shapes the voltage pulses to the plasma.

Abstract: There is provided by this invention a novel method of reactive sputter deposition of a thin film on a substrate (28) utilizing multiphase AC power supplies to drive multiple magnetron targets (22, 24, 26) in a plasma chamber (20) to independently regulate power to each target (22, 24, 26) wherein the voltages on the targets (22, 24, 26) are periodically reversed such that periodically at least one target (22, 24, 26) at a given time acts as an anode collecting electrons when its voltage is positive relative to the plasma (16) while the other targets (22, 24, 26) act as cathodes collecting ions when their voltage is negative relative to the plasma. A DC bias can be connected to the AC power sources wherein by changing the bias, the energy and flux of ions and electrons to the substrate (28) can be changed to increase the density of the deposited film and its refractive index, and alter the morphology and stress of the film.

Abstract: There is provided by this invention an apparatus and method for generating voltage pulses to first and second magnetron devices in a plasma chamber. An isolation transformer is connected to a pulsed DC power supply having a flux sensor, such as a Hall effect sensor, in close proximity to its air gap to monitor the transformer flux. A control circuit is connected to the flux sensor to control the duty cycle of the transformer by controlling the flux of the transformer such that the maximum and minimum peak transformer fluxes are equal in magnitude and opposite in sign to prevent saturation.

Abstract: There is provided by this invention an apparatus and method for generating voltage pulses to first and second magnetron devices in a plasma chamber. An isolation transformer is connected to a pulsed DC power supply having a flux sensor, such as a Hall effect sensor, in close proximity to its air gap to monitor the transformer flux. A control circuit is connected to the flux sensor to control the duty cycle of the transformer by controlling the flux of the transformer such that the maximum and minimum peak transformer fluxes are equal in magnitude and opposite in sign to prevent saturation.

Abstract: Current controlled power sources are disclosed that are capable of generating currents in low resistance, high temperature plasmas that are regulated to prevent the generation of excessive currents in the plasma. Current reversing switches are provided that control the flow of a direct current in a plasma chamber between various electrodes. Multiple power sources are provided in association with shunt switches for delivering a plurality of sources of direct current in various directions between electrodes in a plasma chamber. Inductive impedance can be provided in switch paths to cause a source of direct current to flow through a plasma chamber in various directions between electrodes.

Abstract: Various embodiments of a power supply are disclosed for generating plasmas. Current controlled power sources are disclosed that are capable of generating currents in low resistance, high temperature plasmas that are regulated to prevent the generation of excessive currents in the plasma. Current reversing switches are provided that control the flow of a direct current in a plasma chamber between various electrodes. A single current controlled power source capable of providing a substantially constant direct current can be utilized with various switch configurations to provide current that is delivered through three or more electrodes in a plasma chamber. Multiple power sources are also provided in association with shunt switches for delivering a plurality of sources of direct current in various directions between electrodes in a plasma chamber.

Abstract: A circuit, comprising an amplifier and a transformer is disclosed that produces a high power pulse having a fast response time, and that responds to a digital control signal applied through a digital-to-analog converter. The present invention is suitable for driving a component such as an electro-optic modulator with a voltage in the kilovolt range. The circuit is stable at high frequencies and during pulse transients, and its impedance matching circuit matches the load impedance with the output impedance. The preferred embodiment comprises an input stage compatible with high-speed semiconductor components for amplifying the voltage of the input control signal, a buffer for isolating the input stage from the output stage; and a plurality of current amplifiers connected to the buffer. Each current amplifier is connected to a field effect transistor (FET), which switches a high voltage power supply to a transformer which then provides an output terminal for driving a load.