Abstract: A plasma processing system is provided. The plasma processing system includes a radio frequency (RF) power generator configured to have a tunable frequency power output, the frequency output being adjustable within a range. A processing chamber having a bottom electrode and a top electrode is included. A plasma region being defined between the bottom and top electrodes and the processing chamber receives RF power from the RF power generator. A match network is coupled between the RF power generator and the processing chamber. The match network has a first tunable element and a second tunable element. The first tunable element adjusts a split between a first grounding pathway defined within an inner region of the plasma region and a second grounding pathway defined within an outer region of the plasma region. The second tunable element adjusts a load delivered to the processing chamber from the power generator.

Abstract: A silicon-based showerhead electrode is provided that can include a backside, a frontside, and a plurality of showerhead passages extending from the backside of the silicon-based showerhead electrode to the frontside of the silicon-based showerhead electrode. The silicon-based showerhead electrode can comprise single crystal silicon. The silicon-based showerhead electrode may further include a plurality of partial recesses formed within the single crystal silicon along the backside of the silicon-based showerhead electrode. The plurality of partial recesses can leave a thickness of single crystal silicon between each of the partial recesses and the frontside of the silicon-based showerhead electrode.

Abstract: The present invention relates generally to plasma processing and, more particularly, to plasma processing chambers and electrode assemblies used therein. According to one embodiment of the present invention, an electrode assembly is provided comprising a thermal control plate, a silicon-based showerhead electrode, a thermally conductive gasket, and a plurality of o-rings, wherein respective profiles of a frontside of the thermal control plate and a backside of the showerhead electrode cooperate to define a thermal interface. The thermally conductive gasket and the o-rings are positioned along this thermal interface with the o-rings separating the thermally conductive gasket from the showerhead passages such that the gasket is isolated from the showerhead passages. The gasket may facilitate heat transfer across the thermal interface from the showerhead electrode to the thermal control plate.

Abstract: A silicon-based showerhead electrode is provided that can include a backside, a frontside, and a plurality of showerhead passages extending from the backside of the silicon-based showerhead electrode to the frontside of the silicon-based showerhead electrode. The silicon-based showerhead electrode can comprise single crystal silicon. The silicon-based showerhead electrode may further include a plurality of partial recesses formed within the single crystal silicon along the backside of the silicon-based showerhead electrode. The plurality of partial recesses can leave a thickness of single crystal silicon between each of the partial recesses and the frontside of the silicon-based showerhead electrode.

Abstract: The present invention relates generally to plasma processing and, more particularly, to plasma processing chambers and electrode assemblies used therein. According to one embodiment of the present invention, an electrode assembly is provided comprising a thermal control plate, a silicon-based showerhead electrode, and a thermally conductive gasket, wherein respective profiles of a frontside of the thermal control plate and a backside of the showerhead electrode cooperate to define a disjointed thermal interface comprising portions proximal to showerhead passages of the showerhead electrode and portions displaced from the showerhead passages. The displaced portions are recessed relative to the proximal portions and are separated from the showerhead passages by the proximal portions of the thermal interface.

Abstract: The present invention relates generally to plasma processing and, more particularly, to plasma processing chambers and electrode assemblies used therein. According to one embodiment of the present invention, an electrode assembly is provided comprising a thermal control plate, a silicon-based showerhead electrode, and securing hardware, wherein the silicon-based showerhead electrode comprises a plurality of partial recesses formed in the backside of the silicon-based showerhead electrode and backside inserts positioned in the partial recesses. The thermal control plate comprises securing hardware passages configured to permit securing hardware to access the backside inserts.

Abstract: The present invention relates generally to plasma processing and, more particularly, to plasma processing chambers and electrode assemblies used therein. According to one embodiment of the present invention, an electrode assembly is provided comprising a thermal control plate, a silicon-based showerhead electrode, and a thermally conductive gasket, wherein respective profiles of a frontside of the thermal control plate and a backside of the showerhead electrode cooperate to define a disjointed thermal interface comprising portions proximal to showerhead passages of the showerhead electrode and portions displaced from the showerhead passages. The displaced portions are recessed relative to the proximal portions and are separated from the showerhead passages by the proximal portions of the thermal interface.

Abstract: The present invention relates generally to plasma processing and, more particularly, to plasma processing chambers and electrode assemblies used therein. According to one embodiment of the present invention, an electrode assembly is provided comprising a thermal control plate, a silicon-based showerhead electrode, and securing hardware, wherein the silicon-based showerhead electrode comprises a plurality of partial recesses formed in the backside of the silicon-based showerhead electrode and backside inserts positioned in the partial recesses. The thermal control plate comprises securing hardware passages configured to permit securing hardware to access the backside inserts.

Abstract: The present invention relates generally to plasma processing and, more particularly, to plasma processing chambers and electrode assemblies used therein. According to one embodiment of the present invention, an electrode assembly is provided comprising a thermal control plate, a silicon-based showerhead electrode, a thermally conductive gasket, and a plurality of o-rings, wherein respective profiles of a frontside of the thermal control plate and a backside of the showerhead electrode cooperate to define a thermal interface. The thermally conductive gasket and the o-rings are positioned along this thermal interface with the o-rings separating the thermally conductive gasket from the showerhead passages such that the gasket is isolated from the showerhead passages. The gasket may facilitate heat transfer across the thermal interface from the showerhead electrode to the thermal control plate.

Abstract: A workpiece is processed with a plasma in a vacuum plasma processing chamber by exciting the plasma at several frequencies such that the excitation of the plasma by the several frequencies simultaneously causes several different phenomena to occur in the plasma. The chamber includes central top and bottom electrodes and a peripheral top and/or bottom electrode arrangement that is either powered by RF or is connected to a reference potential by a filter arrangement that passes at least one of the plasma excitation frequencies to the exclusion of other frequencies.

Abstract: A plasma processor processing a workpiece includes sources having frequencies 2 MHz, 27 MHz, and 60 MHz, applied by three matching networks to an electrode in a vacuum chamber including the workpiece. Alternatively 60 MHz is applied to a second electrode by a fourth matching network. The matching networks, substantially tuned to the frequencies of the sources driving them, include series inductances so the 2 MHz inductance exceeds the 27 MHz network inductance, and the 27 MHz network inductance exceeds the inductances of the 60 MHz networks. The matching networks attenuate by at least 26 DB the frequencies of the sources that do not drive them. Shunt inductors between the 27 and 60 MHz sources decouple 2 MHz from the 27 and 60 MHz sources. A series resonant circuit (resonant to about 5 MHz) shunts the 2 MHz network and the electrode to help match the 2 MHz source to the electrode.

Abstract: A workpiece is processed with a plasma in a vacuum plasma processing chamber by exciting the plasma at several frequencies such that the excitation of the plasma by the several frequencies simultaneously causes several different phenomena to occur in the plasma. The chamber includes central top and bottom electrodes and a peripheral top and/or bottom electrode arrangement that is either powered by RF or is connected to a reference potential by a filter arrangement that passes at least one of the plasma excitation frequencies to the exclusion of other frequencies.