An atomic layer deposition apparatus includes a film-forming container 11 in which a film-forming process is performed, a vertically movable stage 14 configured to hold a substrate 100, a susceptor 50 held on the stage 14 and being configured to hold the substrate 100, and a stage stopper 17 configured to stop rising of the stage 14 and, when in contact with the susceptor 50, partitioning a film-forming space S in which the film-forming process is performed and a transporting space in which transport of the substrate 100 is performed. Further, the susceptor 50 includes an upper susceptor substrate holding portion 52B configured to hold the substrate 100, and an upper susceptor peripheral portion 52A arranged in a periphery of the upper susceptor substrate holding portion 52B, wherein a susceptor deposition prevention member 15 is provided on the upper susceptor peripheral portion 52A.

In an embodiment, the a semiconductor processing tool is disclosed. In an embodiment, the semiconductor processing tool comprises a chamber, and a displaceable column that passes through a surface of the chamber. In an embodiment, the column comprises a base plate, an insulator layer over the base plate, a pedestal over the insulator layer, and an edge ring surrounding a perimeter of the ground plate, the insulator and the pedestal. In an embodiment, a fluidic path is provided between the edge ring and the pedestal.

A substrate processing apparatus including a reaction chamber with an inlet opening, an in-feed line to provide a reactive chemical into the reaction chamber via the inlet opening, incoming gas flow control means in the in-feed line, the in-feed line extending from the flow control means to the reaction chamber, the in-feed line in this portion between the flow control means and the reaction chamber having the form of an inlet pipe with a gas-permeable wall, the inlet pipe with the gas-permeable wall extending towards the inlet opening through a volume at least partly surrounding the inlet pipe, and the apparatus (100, 800) being configured to provide fluid to surround and enter the inlet pipe in said portion.

A susceptor can include a face that is configured to support a substrate thereon and a plurality of channels extending into the face and radially outwardly relative to a center of the face. One or more of the plurality of channels may include an elongate portion and a flash-out portion. The elongate portion may have a width less than a threshold width along the entirety of the elongate portion. The flash-out portion may be in fluid communication with the elongate portion and may include a first section having a first width and a second section having a second width greater than the first width. The first section may be disposed radially inward of the second section.

The present invention discloses a coating device including: a first shell, having a top portion and a side portion; and a second shell, accommodated in the first shell and at least partially divergently extending downwards from the top portion of the first shell. The first shell and the second shell define a first space in between, the second shell defines a second space, and the first space surrounds the second space and the two are not in communication.

Embodiments of the present disclosure generally relate to semiconductor processing, and specifically to methods and apparatus for surface modification of substrates. In an embodiment, a substrate modification method is provided. The method includes positioning a substrate within a processing chamber; and depositing a material on a portion of the substrate by a deposition process, wherein the deposition process comprises: thermally heating the substrate to a temperature of less than about 500° C.; delivering a first electromagnetic energy from an electromagnetic energy source to the substrate to modify a first region of the substrate, the first region of the substrate being at or near an upper surface of the substrate; and depositing a first material on the first region while delivering the first electromagnetic energy.

A substrate supporting assembly includes a susceptor plate including at least one substrate seat, and a plurality of gas flow lines for supplying a lifting gas, an acceleration gas, and a deceleration gas to the substrate seat, and at least one satellite on the at least one substrate seat and including an upper surface, and a lower surface where a rotation pattern for receiving a rotational force and a braking force from the acceleration gas and the deceleration gas is provided. The at least one satellite is lifted from the at least one substrate seat by the lifting gas supplied from the at least one substrate seat, is rotated relative to the susceptor plate by the acceleration gas supplied in a forward direction of rotation, to rotate the substrate, and is decelerated or stopped by the deceleration gas supplied in a reverse direction of rotation.

Exemplary semiconductor processing systems may include a chamber body including sidewalls and a base. The system may include a substrate support extending through the base of the chamber body. The chamber body may define an access circumferentially extending about the substrate support at the base of the chamber body. The system may include one or more isolators disposed within the chamber body. The one or more isolators may define an exhaust path between the one or more isolators and the chamber body. The exhaust path may extend to the base of the chamber body. The systems may include a fluid source fluidly coupled with the chamber body at the access extending about the substrate support.

A susceptor including a generally circular body having a face with a radially inward section and a radially outward section proximate a circumference of the body, the radially outward section having at least one ring extending upward for contacting a bottom surface of a substrate, and wherein the radially inward section lacks a ring extending upward from the face.

A film forming method is provided. In the film forming method, a mask is prepared based on a measurement result of a surface state of a substrate. The mask is transferred into a process chamber and the substrate is transferred into the process chamber. Then, a film is formed on a back surface of the substrate while the mask is disposed onto the back surface of the substrate.