A plasma processing apparatus includes a microwave introducing module provided at a ceiling portion of a processing chamber and configured to introduce a microwave for generating plasma of a gas into the processing chamber; and a plurality of gas supply holes formed at the ceiling portion of the processing chamber and configured to introduce the gas into a plasma processing space. Each of the plurality of gas supply holes includes a fine hole and a cavity that is expanded from the fine hole and opened to the plasma processing space. A diameter of the cavity on the plasma processing space side is 3 mm or more and is ⅛ or less of a wavelength of a surface wave of a microwave in the plasma.

Provided are a surface coupling induced ionization method, and a plasma device. The method includes the following steps: (1) feeding a first electromagnetic wave beam to a material via a free space or waveguide to excite surface plasma waves; where target molecules to be ionized are introduced to a surface of the material, and electrons of the target molecules are coupled with surface plasmons on the material under interaction control to induce the ionization of the target molecules; (2) feeding second and subsequent electromagnetic wave beams to an ionization area of the target molecules on the surface of the material synchronously via the free space or waveguide, such that the ionized target molecules absorb the electromagnetic waves to improve the degree of ionization of the target molecules; and (3) releasing the target molecules in the form of bulk phase plasma to realize surface coupling induced ionization.

The present invention relates to a process, reactor and system to produce self-standing two-dimensional nanostructures, using a microwave-excited plasma environment. The process is based on injecting, into a reactor, a mixture of gases and precursors in stream regime. The stream is subjected to a surface wave electric field, excited by the use of microwave power which is introduced into a field applicator, generating high energy density plasmas, that break the precursors into its atomic and/or molecular constituents. The system comprises a plasma reactor with a surface wave launching zone, a transient zone with a progressively increasing cross-sectional area, and a nucleation zone. The plasma reactor together with an infrared radiation source provides a controlled adjustment of the spatial gradients, of the temperature and the gas stream velocity.

An electric field sensor includes a probe, a cylindrical probe guide, an insulating member, a preload spring and a connector. The probe serves as an inner conductor of a coaxial transmission path and has a portion forming a monopole antenna at a tip end to be in constant contact with a microwave transmission window by a pressing force of a built-in spring thereof. The probe guide is disposed at an outer side of the probe and serves as an outer conductor of the coaxial transmission path. The insulating member is disposed between the probe and the probe guide. The preload spring preloads the probe guide downward and presses the probe guide so that the tip end of the probe guide comes in constant contact with the planar slot antenna. The connector is connected to the probe and the probe guide to connect coaxial signal cables for extracting signals.

The present invention relates to a process, reactor and system to produce self-standing two-dimensional nanostructures, using a microwave-excited plasma environment. The process is based on injecting, into a reactor, a mixture of gases and precursors in stream regime. The stream is subjected to a surface wave electric field, excited by the use of microwave power which is introduced into a field applicator, generating high energy density plasmas, that break the precursors into its atomic and/or molecular constituents. The system comprises a plasma reactor with a surface wave launching zone, a transient zone with a progressively increasing cross-sectional area, and a nucleation zone. The plasma reactor together with an infrared radiation source provides a controlled adjustment of the spatial gradients, of the temperature and the gas stream velocity.

An electric field sensor includes a probe, a cylindrical probe guide, an insulating member, a preload spring and a connector. The probe serves as an inner conductor of a coaxial transmission path and has a portion forming a monopole antenna at a tip end to be in constant contact with a microwave transmission window by a pressing force of a built-in spring thereof. The probe guide is disposed at an outer side of the probe and serves as an outer conductor of the coaxial transmission path. The insulating member is disposed between the probe and the probe guide. The preload spring preloads the probe guide downward and presses the probe guide so that the tip end of the probe guide comes in constant contact with the planar slot antenna. The connector is connected to the probe and the probe guide to connect coaxial signal cables for extracting signals.

The present invention relates to a process, reactor and system to produce self-standing two-dimensional nanostructures, using a microwave-excited plasma environment. The process is based on injecting, into a reactor, a mixture of gases and precursors in stream regime. The stream is subjected to a surface wave electric field, excited by the use of microwave power which is introduced into a field applicator, generating high energy density plasmas, that break the precursors into its atomic and/or molecular constituents. The system comprises a plasma reactor with a surface wave launching zone, a transient zone with a progressively increasing cross-sectional area, and a nucleation zone. The plasma reactor together with an infrared radiation source provides a controlled adjustment of the spatial gradients, of the temperature and the gas stream velocity.

Systems and methods are described herein for generating surface-wave plasmas capable of simultaneously achieving high density with low temperature and planar scalability. A key feature of the invention is reduced damage to objects in contact with the plasma due to the lack of an RF bias; allowing for damage free processing. The preferred embodiment is an all-in-one processing reactor suitable for photovoltaic cell manufacturing, performing saw-damage removal, oxide stripping, deposition, doping and formation of hetero structures. The invention is scalable for atomic-layer deposition, etching, and other surface interaction processes.

A plasma post-discharge deposition device for depositing crystalline metal oxide derivative on a substrate, the device comprising a gas source with a substrate inlet, a post-discharge deposition chamber with a substrate outlet, the substrate inlet and the substrate outlet defining a longitudinal central axis, and a dielectric tube placed between the gas source and the deposition chamber on the longitudinal central axis; configured to confine a plasma discharge and comprising a discharge zone lying on the internal surface of the dielectric tube and a central zone centred on the longitudinal central axis. The deposition device is remarkable in that the central zone is located at a distance comprised between 1 mm and 2.5 mm from the internal surface of the dielectric tube. Also a plasma-enhanced chemical vapour deposition method.

A plasma processing apparatus, for converting a gas into plasma by using microwaves microwaves and processing a target object in a processing chamber, includes a microwave introducing surface and a plurality of gas injection holes. Microwaves from a microwave introducing unit are introduced through microwave introducing surface and surface waves of the microwaves propagate on the microwave introducing surface. The gas injection holes are arranged at predetermined intervals within a predetermined range from a boundary line between the microwave introducing surface and a surface of the processing chamber that is adjacent to the microwave introducing surface.