A method of cleaning blind spots around a substrate supporting apparatus by controlling a position of the substrate supporting apparatus includes moving the substrate supporting apparatus relative to a ring and supplying a cleaning gas to an upper space of the substrate supporting apparatus.

Plasma applications are disclosed that operate with argon and other molecular gases at atmospheric pressure, and at low temperatures, and with high concentrations of reactive species. The plasma apparatus and the enclosure that contains the plasma apparatus and the substrate are substantially free of particles, so that the substrate does not become contaminated with particles during processing. The plasma is developed through capacitive discharge without streamers or micro-arcs. The techniques can be employed to remove organic materials from a substrate, thereby cleaning the substrate; to activate the surfaces of materials, thereby enhancing bonding between the material and a second material; to etch thin films of materials from a substrate; and to deposit thin films and coatings onto a substrate; all of which processes are carried out without contaminating the surface of the substrate with substantial numbers of particles.

An apparatus and a method for wafer bonding are provided. The apparatus comprises a transfer module and a plasma module. The transfer module is configured to transfer a semiconductor wafer. The plasma module is configured to perform a plasma operation and a reduction operation to a surface of the semiconductor wafer to convert metal oxides on the surface of the semiconductor wafer to the metal.

A precleaning chamber (100, 200, 300) and a plasma processing apparatus, comprising a cavity (20) and a dielectric window (21, 21) disposed at the top of the cavity (20), a base (22) and a process assembly (24) surrounding the base (22) are disposed in the precleaning chamber (100, 200, 300), and the base (22), the process assembly (24) and the dielectric window (21, 21) together form a process sub-cavity (211) above the base (22); and a space of the cavity (20) located below the base (22) is used as a loading/unloading sub-cavity (202), the precleaning chamber (100, 200, 300) further comprises a gas is device (32), the gas inlet device (32) comprises a gas inlet (323), and the gas inlet (323) is configured to directly transport a process gas into the process sub-cavity (211) from above the process assembly (24). The precleaning chamber (100, 200, 300) not only shortens the gas inlet path of the process gas, but also reach a desired plasma density under the conditions where a relatively small amount of process gas is introduced, thereby reducing the usage cost.

The present disclosure generally relates to methods for removing contaminants and native oxides from substrate surfaces. The method includes exposing a surface of the substrate to first hydrogen radical species, wherein the substrate is silicon germanium having a concentration of germanium above about 30%, then exposing the surface of the substrate to a plasma formed from a fluorine-containing precursor and a hydrogen-containing precursor, and then exposing the surface of the substrate to second hydrogen radical species.

Embodiments described herein relate to oxygen cleaning chambers and a method of atomic oxygen cleaning a substrate. The oxygen cleaning chambers and method of atomic oxygen cleaning a substrate provide for generation of atomic oxygen in situ to oxidize materials on the surfaces of the substrate. The atomic oxygen cleaning chamber includes a chamber body, a chamber lid, a processing volume defined by the chamber body and the chamber lid, an UV radiation generator including one or more UV radiation sources, a pedestal disposed in the processing volume, and a gas distribution assembly. The pedestal has a processing position corresponding to a distance from the UV radiation generator to an upper surface of the pedestal. The gas distribution assembly is configured to be connected to an ozone generator to distribute ozone over the upper surface of the pedestal.

An optical image capturing system comprising, in order from an object side to an image side, a first lens element, a second lens element, a third lens element, a fourth lens element, a fifth lens element, a sixth lens element and a seventh lens element. The first lens element with negative refractive power has a concave image-side surface. The second lens element, the third lens element and the fourth lens element have refractive power. The fifth lens element has refractive power. The sixth lens element with refractive power has an image-side surface being concave in a paraxial region and includes at least one convex shape in an off-axial region, wherein the surfaces thereof are aspheric. The seventh lens element with refractive power has an image-side surface being concave in a paraxial region and includes at least one convex shape in an off-axial region, wherein the surfaces thereof are aspheric.

A substrate processing device includes: a substrate holding member which horizontally holds a substrate; a first supply unit which has a first opening opposed to a lower surface of the substrate held by the substrate holding member and supplies fluid from the first opening toward the lower surface of the substrate; an opposing part having an upper surface opposed to the lower surface of the substrate held by the substrate holding member; and a second supply unit which supplies rinsing liquid from a second opening to a concave surface which is recessed on a central side in the upper surface of the opposing part. A height of the first opening is higher than a height of a liquid surface, of the rinsing liquid supplied to the concave surface, when the rinsing liquid overflows the opposing part. Therefore, the opposing part can be highly accurately cleaned.

The cleaning apparatus includes multiple kinds of cleaning modules each configured to perform a cleaning processing of a substrate, a first accommodating section configured to accommodate the multiple kinds of cleaning modules therein, and a fluid supply section configured to supply a fluid to the cleaning modules accommodated in the first accommodating section through a pipe. Each of the multiple kinds of cleaning modules includes a pipe connection portion having a common connection position to be connected with the pipe.

A controlling method for a wafer transportation part and a load port part on an EFEM includes a fixing step of fixing a container on an installation stand of the load port part, a first cleaning step of connecting a bottom nozzle of the load port part to multiple bottom holes formed on a bottom surface of the container and introducing a cleaning gas into the container and discharging a gas from the container via the nozzle, a connection step of connecting the container and the transportation room, and a wafer transportation step of transporting the wafer from the container to a processing room via the opening and the transportation room and transporting the wafer from the processing room to the container via the transportation room and the opening.