A method of manufacturing a semiconductor package may include providing a substrate having first and second cutting regions respectively provided along first and second side portions opposite to each other and a mounting region between the first and second cutting regions is provided, disposing at least one semiconductor chip on the mounting region, forming a molding member on the substrate, and removing a dummy curl portion and at least portions of dummy runner portions from the molding member. The molding member may include a sealing portion, the dummy curl portion provided outside the second side portion of the substrate, and the plurality of dummy runner portions on the second cutting region to connect the sealing portion and the dummy curl portion. The substrate may include adhesion reducing pads in the second cutting region, which may contact the dummy runner portions respectively.

A process chamber door for closing or opening an entrance of a process chamber through which a substrate to be process is loaded includes a seal plate including a front surface and a rear surface opposite to each other in a first direction, a connection block connected to the rear surface of the seal plate and including a central portion and two side portions connected to the rear surface of the seal plate, and a shaft connected to the central portion of the connection block. The connection block includes a first hinge groove and a second hinge groove. The first hinge groove is exposed at a bottom surface and a side surface of the connection block and the second hinge groove is exposed at an upper surface and the side surface of the connection block.

A sealing structure of a gas supply line assembly connected to a processing chamber for processing a substrate in a vacuum atmosphere is provided. The sealing structure includes a first pipe member constituting the gas supply line assembly and having an end surface where an opening communicating with the processing chamber is formed, a second pipe member constituting the gas supply line assembly and having a facing surface facing the end surface of the first pipe member, and a sealing member made of an elastomer disposed between the end surface of the first pipe member and the facing surface of the second pipe member to surround the opening. The sealing structure further includes a sheet-shaped porous member disposed between the end surface of the first pipe member and the facing surface of the second pipe member to surround a vicinity of the sealing member.

To provide a highly productive, compact, and inexpensive film deposition apparatus while ensuring the stability of the film deposition quality, the apparatus includes a rotating body configured to be rotatable and provided with a holding unit that holds an object to be transferred in an attachable and detachable manner, the holding unit being provided along an outer peripheral portion of the rotating body; and a transfer mechanism having a gripping mechanism capable of gripping and releasing the object, the transfer mechanism transferring the object held by a predetermined device to the holding unit of the rotating body and transferring another object held by the rotating body to the predetermined device.

A substrate processing apparatus includes an inner chamber formed by an upper portion and a lower portion, a substrate support to support a substrate within the upper portion of the inner chamber, a plasma system to provide the inner chamber with plasma species from the top side of the inner chamber, and an outer chamber surrounding the upper portion of the inner chamber. The lower portion of the inner chamber extends to the outside of the outer chamber and remains uncovered by the outer chamber.

Embodiments of the present disclosure herein include an apparatus for processing a substrate. More specifically, embodiments of this disclosure provide a substrate support assembly that includes an electrostatic chuck (ESC) assembly. The ESC assembly comprises a cooling base having a top surface and an outer diameter sidewall, an ESC having a substrate support surface, a bottom surface and an outer diameter sidewall, the bottom surface of the ESC coupled to the top surface of the cooling base by an adhesive layer. The substrate support assembly includes a blocking ring disposed around the outer diameter sidewalls of the cooling base and ESC, the blocking ring shielding an interface between the bottom surface of the ESC and the top surface of the cooling base.

An embodiment of the present application provides a semiconductor etching device, comprising: an air delivery chamber (21), configured to accommodate a wafer (22) to be etched; an air intake module (23), configured to feed air into the air delivery chamber (21); an air exhaust module, configured to exhaust air in the air delivery chamber (21), the air exhaust module comprising an airlock (27) and a wind speed measurement and control unit (28), the wind speed measurement and control unit (28) being configured to detect an air flow rate in the air delivery chamber (21) and adjust the degree of opening of the airlock (27) based on the air flow rate.

Exemplary substrate processing systems may include a chamber body defining a transfer region. The systems may include a lid plate seated on the chamber body. The lid plate may define a first plurality of apertures and a second plurality of apertures. The systems may include a plurality of lid stacks equal to a number of the first plurality of apertures. Each lid stack may include a choke plate seated on the lid plate along a first surface of the choke plate. The choke plate may define a first aperture axially aligned with an associated aperture of the first plurality of apertures. The choke plate may define a second aperture axially aligned with an associated aperture of the second plurality of apertures. The choke plate may define protrusions extending from each of a top and bottom surface of the choke plate that are arranged substantially symmetrically about the first aperture.

This invention relates to a substrate processing technique for performing a pressure increasing step, a pressure keeping step and a pressure reducing step in this order in a processing container. A flow rate of a processing fluid in a processing space is suppressed to a second flow rate lower than a first flow rate while maintaining the processing space at a first pressure between the pressure increasing step and the pressure keeping step or in an initial stage of the pressure keeping step. In this way, the mutual diffusion between the processing fluid and a liquid in the processing space is promoted. After this diffusion proceeds, the substrate is dried by the discharge of the processing fluid from the processing space.

A reaction chamber may comprise a reaction chamber volume enclosed within the reaction chamber; a susceptor configured to support a substrate disposed in the reaction chamber volume; a reaction space above the susceptor, and a lower chamber space below the susceptor, within the reaction chamber volume; and/or a sealing system causing the reaction space and the lower chamber space to be at least partially fluidly separate. A sealing system may comprise a spacer plate surrounding and coupled to the susceptor; and/or a spring coupled to the spacer plate and the susceptor having a spring bias toward a compressed position or an extended position, such that the spring bias facilitates creation of at least a partial seal between the spacer plate and the susceptor, causing at least partial fluid separation between the reaction space and the lower chamber space as the susceptor moves up and down within the reaction chamber.