Embodiments disclosed herein generally relate to a system and, more specifically, a substrate processing system. The substrate processing system includes one or more cooling systems. The cooling systems are configured to lower and/or control the temperature of a body of the substrate processing system. The cooling systems include features to cool the body disposed in the substrate processing system using gas and/or liquid cooling systems. The cooling systems disclosed herein can be used when the body is disposed at any height.

A first x-y translation stage, a second x-y translation stage, and a chuck are disposed in a chamber. The chuck is situated above and coupled to the second x-y translation stage, which is situated above and coupled to the first x-y translation stage. The chuck is configured to support a substrate and to be translated by the first and second x-y stages in x- and y-directions, which are substantially parallel to a surface of the chuck on which the substrate is to be mounted. A first barrier and a second barrier are also disposed in the chamber. The first barrier is coupled to the first x-y translation stage to separate a first zone of the chamber from a second zone of the chamber. The second barrier is coupled to the second x-y translation stage to separate the first zone of the chamber from a third zone of the chamber.

A wafer placement table is a wafer placement table that includes a refrigerant flow channel through which refrigerant is flowed and includes a top base including a ceramic base incorporating an electrode and having a wafer placement surface on a top surface of the ceramic base, a bottom base on a top surface of which a flow channel groove defining a side wall and a bottom of the refrigerant flow channel is provided, and a seal member disposed between the top base and the bottom base so as to seal the refrigerant flow channel from an outside.

The inventive concept provides an apparatus for treating a substrate. A substrate treatment apparatus according to an embodiment includes a housing having a treatment space in which the substrate is treated, a support unit that supports the substrate in the treatment space, and a gas supply unit that supplies a gas to the treatment space, wherein a heat transfer flow path that supplies a heat transfer medium to the substrate supported by the support unit, a pin hole defining an elevation path of a lift pin that elevates the substrate supported by the support unit, and a connection portion allowing the heat transfer flow path and the pin hole to be in communication with each other are formed inside the support unit, and the connection portion includes a porous structure.

A sample holder for electron microscopy of air-sensitive samples for use in electron microscopy incorporates a housing and a closure assembly. The closure assembly comprises a lid comprising at least one closure arm receiving portions recessed within a flat, planar upper surface thereof. The housing comprises one or more closure arm(s) corresponding to one or more closure arm receiving portion(s). In a fully closed position, the closure arm(s) share contact with the closure arm receiving portion(s). The lid is flexibly coupled to a motor cover plate which can be actuated by a motor assembly configured to open and close the lid. The sample holder also includes an elevator assembly with a vertically adjustable sample stage which sits below the lid. The sample stage is vertically adjusted by actuation of a bellows assembly which sits beneath the sample stage.

Embodiments disclosed herein generally relate to a system and, more specifically, a substrate processing system. The substrate processing system includes one or more cooling systems. The cooling systems are configured to lower and/or control the temperature of a body of the substrate processing system. The cooling systems include features to cool the body disposed in the substrate processing system using gas and/or liquid cooling systems. The cooling systems disclosed herein can be used when the body is disposed at any height.

A sample holder for electron microscopy of air-sensitive samples for use in electron microscopy incorporates a housing and a closure assembly. The closure assembly comprises a lid comprising at least one closure arm receiving portions recessed within a flat, planar upper surface thereof. The housing comprises one or more closure arm(s) corresponding to one or more closure arm receiving portion(s). In a fully closed position, the closure arm(s) share contact with the closure arm receiving portion(s). The lid is flexibly coupled to a motor cover plate which can be actuated by a motor assembly configured to open and close the lid. The sample holder also includes an elevator assembly with a vertically adjustable sample stage which sits below the lid. The sample stage is vertically adjusted by actuation of a bellows assembly which sits beneath the sample stage.

An ion beam etching system includes an etching cavity, an etching electrode, and an electrode displacement apparatus used for enabling the electrode to change a working position in the etching cavity. The electrode displacement apparatus includes a dynamic sealing mechanism, a dynamic electrode balance counterweight mechanism, an electrode displacement transmission mechanism, and an electrode displacement driving mechanism. The etching cavity includes a cavity and a cavity cover connected with the cavity. The cavity is of an irregular shape. The cavity includes a partial cylindrical body, a side plate, a tapered transition portion, and a bottom plate. The partial cylindrical body is laterally sealed by means of the side plate. The bottom plate is connected to an end of the partial cylindrical body by means of the tapered transition portion and seals the end of the partial cylindrical body.

A sample holder for electron microscopy of air-sensitive samples for use in electron microscopy incorporates a housing and a closure assembly. The closure assembly comprises a lid comprising at least one closure arm receiving portions recessed within a flat, planar upper surface thereof. The housing comprises one or more closure arm(s) corresponding to one or more closure arm receiving portion(s). In a fully closed position, the closure arm(s) share contact with the closure arm receiving portion(s). The lid is flexibly coupled to a motor cover plate which can be actuated by a motor assembly configured to open and close the lid. The sample holder also includes an elevator assembly with a vertically adjustable sample stage which sits below the lid. The sample stage is vertically adjusted by actuation of a bellows assembly which sits beneath the sample stage.

A device for supporting a substrate having a thermal expansion coefficient, includes: a base; an electrostatic chuck disposed on the base and having a substrate supporting region, the electrostatic chuck having a thermal expansion coefficient different from the thermal expansion coefficient of the substrate; and an annular elastic seal disposed on the substrate supporting region so as to make contact with the substrate supported on the substrate supporting region.