PECVD methods for depositing a film at a low deposition rate comprising intermittent activation of the plasma are disclosed. The flowable film can be deposited using at least a polysilane precursor and a plasma gas. The deposition rate of the disclosed processes may be less than 500 Å/min.

Methods and systems for forming a structure including a silicon carbide layer and structures formed using the methods and systems are disclosed. Exemplary methods include providing a silicon carbide precursor to the reaction chamber, forming a plasma within the reaction chamber to form an initially flowable, viscous silicon carbide material on a surface of the substrate, wherein the initially viscous carbon material becomes the silicon carbide layer. Exemplary methods can include use of a silicon carbide precursor that includes a carbon-carbon triple bond and/or use of a relatively low plasma power density (e.g., less than 3 W/cm.sup.2).

Provided by the invention disclosure is a coating equipment. The coating equipment comprises a reaction chamber body provided with a reaction chamber, a gas supply part configured to supply gas to the reaction chamber, a pumping device configured to communicate with the reaction chamber, a pulse power supply adapted to provide the reaction chamber body with a pulsed electric field and a radio frequency power supply adapted to provide the reaction chamber body with a radio frequency electric field, wherein the reaction chamber is adapted to accommodate a plurality of workpiece. When the pulse power supply and the radio frequency power supply are turned on, the gas in the reaction chamber body is ionized under the radio frequency electric field and the pulsed electric field to generate plasma, and the plasma is deposited on the surface of the workpieces.

Provided by the invention disclosure is a coating equipment. The coating equipment comprises a reaction chamber body provided with a reaction chamber, a gas supply part configured to supply gas to the reaction chamber, a pumping device configured to communicate with the reaction chamber, a pulse power supply adapted to provide the reaction chamber body with a pulsed electric field and a radio frequency power supply adapted to provide the reaction chamber body with a radio frequency electric field, wherein the reaction chamber is adapted to accommodate a plurality of workpiece. When the pulse power supply and the radio frequency power supply are turned on, the gas in the reaction chamber body is ionized under the radio frequency electric field and the pulsed electric field to generate plasma, and the plasma is deposited on the surface of the workpieces.

A process for producing nanoclusters of silicon and/or germanium exhibiting a permanent magnetic and/or electric dipole moment for adjusting the work function of materials, for micro- and nano-electronics, for telecommunications, for “nano-ovens”, for organic electronics, for photoelectric devices, for catalytic reactions and for fractionation of water.

A process for producing nanoclusters of silicon and/or germanium exhibiting a permanent magnetic and/or electric dipole moment for adjusting the work function of materials, for micro- and nano-electronics, for telecommunications, for “nano-ovens”, for organic electronics, for photoelectric devices, for catalytic reactions and for fractionation of water.

The present disclosure provides an electrode support, a supporting mechanism, a support, a film coating apparatus, and an application. The electrode support is applied to the film coating apparatus. The film coating apparatus allows coating of at least one to-be-coated workpiece. The film coating apparatus comprises a reaction chamber and a pulse power supply; the pulse power supply is used for providing a pulse electric field in the reaction chamber. The electrode support comprises support members arranged in multiple layers; the support member of each layer is separately retained at a preset spacing; at least one layer of the support member is conductively connected to the pulse power supply to serve as a negative electrode of the pulse power supply. The electrode support can uniformly load the to-be-coated workpiece and can be used as an electrode, and wiring between the electrode support and an external power supply is simple.

A plasma-enhanced chemical vapor deposition apparatus for depositing a lithium (Li)-based film on a surface of a substrate includes a reaction chamber, in which the substrate is disposed; a first source supply configured to supply a Li source material into the reaction chamber; a second source supply configured to supply phosphor (P) and oxygen (O) source materials and a nitrogen (N) source material into the reaction chamber; a power supply configured to supply power into the reaction chamber to generate plasma in the reaction chamber; and a controller configured to control the power supply to turn on or off generation of the plasma.

The specific embodiment of the present disclosure provides a protective coating. An anticorrosive coating having a compact rigid molecular structure is formed by plasma polymerization coating of monomers including alicyclic epoxy structural units, and a hydrophobic coating is simultaneously formed by plasma polymerization coating on the anticorrosive coating, thus, coatings with excellent protective performance to the substrate are formed.

A system and method are described for depositing a material onto a receiving surface, where the material is formed by use of a plasma to modify a source material in-transit to the receiving surface. The system comprises a microwave generator electronics stage. The system further includes a microwave applicator stage including a cavity resonator structure. The cavity resonator structure includes an outer conductor, an inner conductor, and a resonator cavity interposed between the outer conductor and the inner conductor. The system also includes a multi-component flow assembly including a laminar flow nozzle providing a shield gas, a zonal flow nozzle providing a functional process gas, and a source material flow nozzle configured to deliver the source material. The source material flow nozzle and zonal flow nozzle facilitate a reaction between the source material and the functional process gas within a plasma region.