The invention discloses a gas dispensing apparatus for multiple chemical resources, including: a showerhead assembly having at least two layers of board bodies and a gas mixing chamber defined at a center of the at least two layers of board bodies, and the gas mixing chamber having multiple holes defined thereon; and a pipeline assembly mounted to the showerhead assembly and having a stepped body defining at least two pipelines, the stepped body being configured to connect to the at least two layers of the board bodies to define at least two gas cavities, each of the gas cavities communicating with the corresponding one of the pipelines, each of the gas cavities communicating with the holes defined on the gas mixing chamber.

A thin-film system comprising a microplasma region where sputtered particles are formed, a power supply that supplies power to the microplasma region, gas flow hardware to regulate flow of gas to the microplasma region, a deposition nozzle that forms a thin film on a substrate and a supply line for supplying sputtered particles to the deposition nozzle, wherein the microplasma region is decoupled from the deposition nozzle.

A plasma processing method of processing a substrate with plasma in a plasma processing apparatus. The plasma processing apparatus includes: a chamber configured to accommodate a substrate; an upper electrode structure forming an upper portion of the chamber and including a temperature-controlled plate, an electrode plate disposed below the temperature-controlled plate, and an electrostatic attractor, the electrostatic attractor including a contact surface, an attraction surface, a first electrode, and a second electrode; a power supply configured to apply a voltage to the first and second electrodes; and a temperature obtaining portion configured to acquire a temperature distribution of the electrode plate. The plasma processing method includes: acquiring, by the temperature obtaining portion, the temperature distribution; applying a first voltage to the first electrode and applying a second voltage to the second electrode according to the acquired temperature distribution; and processing the substrate with plasma.

A showerhead with an embedded nut is disclosed. The showerhead comprises an embedded nut within a cavity. The nut may be engaged by a bolt through an opening in the cavity to support the showerhead. The apparatus allows for the support of the showerhead without the potential for metal contamination.

Embodiments described herein generally related to a substrate processing apparatus. In one embodiment, a process kit for a substrate processing chamber disclosed herein. The process kit includes a ring having a first ring component and a second ring component, an adjustable tuning ring, and an actuating mechanism. The first ring component is interfaced with the second ring component such that the second ring component is movable relative to the first ring component forming a gap therebetween. The adjustable tuning ring is positioned beneath the ring and contacts a bottom surface of the second ring component. A top surface of the adjustable tuning ring contacts the second ring component. The actuating mechanism is interfaced with the bottom surface of the adjustable tuning ring. The actuating mechanism is configured to actuate the adjustable tuning ring such that the gap between the first ring component and the second ring component varies.

Examples of a substrate processing device include an annular distribution ring, a plurality of connection plates continued to the distribution ring and having non-uniform impedances, a shower plate electrically connected to the plurality of connection plates, and a stage provided below the shower plate so as to face the shower plate.

Various RF plasma systems are disclosed that do not require a matching network. In some embodiments, the RF plasma system includes an energy storage capacitor; a switching circuit coupled with the energy storage capacitor, the switching circuit producing a plurality of pulses with a pulse amplitude and a pulse frequency, the pulse amplitude being greater than 100 volts; a resonant circuit coupled with the switching circuit. In some embodiments, the resonant circuit includes: a transformer having a primary side and a secondary side; and at least one of a capacitor, an inductor, and a resistor. In some embodiments, the resonant circuit having a resonant frequency substantially equal to the pulse frequency, and the resonant circuit increases the pulse amplitude to a voltage greater than 2 kV.

A thin-film deposition apparatus, related systems and methods are provided. The thin-film deposition apparatus 200 comprises a reaction chamber 201 for accommodating substrates 10 arranged with their side faces adjacent to each other and a fluid distribution device 100 with an expansion region 101 into which precursor fluid(s) enter via a number of inlets 103, and a transition region 102 for mixing said fluids. From the transition region, fluidic flow is directed into the reaction chamber 201 to propagate between the substrates 10 in a strictly laminar manner. By the invention, uniformity of precursor distribution on the substrates can be markedly improved.

Various embodiments include an apparatus to supply precursor gases to a processing tool. In various examples, the apparatus includes a point-of-use (POU) valve manifold that includes a manifold body to couple to a processing chamber of the processing tool. The manifold body has a multiple precursor-gas outlet ports surrounded by an annulus. A purge-gas outlet port of the manifold body is directed substantially toward interior walls of the annulus. For each of multiple precursor gases, the POU-valve manifold further includes: a first valve coupled to the manifold body and a divert valve coupled to the first valve. The first valve can be coupled to a precursor-gas supply and has a separate precursor-gas flow path internal to the manifold body. The divert valve diverts the precursor gas during a period when the precursor gas is not to be directed into the processing chamber by the first valve. Other examples are disclosed.

A thin-film deposition apparatus, related systems and methods are provided. The thin-film deposition apparatus 200 comprises a reaction chamber 201 for accommodating substrates 10 arranged with their side faces adjacent to each other and a fluid distribution device 100 with an expansion region 101 into which precursor fluid(s) enter via a number of inlets 103, and a transition region 102 for mixing said fluids. From the transition region, fluidic flow is directed into the reaction chamber 201 to propagate between the substrates 10 in a strictly laminar manner. By the invention, uniformity of precursor distribution on the substrates can be markedly improved.