The present disclosure relates to the technical field of semiconductors, and proposes a semiconductor chip container and a fixture. The container is placed in a containing device with a chemical reagent, and the container includes a main body and partition plates, where the main body has an accommodating space; the partition plates are arranged in the accommodating space and divide the accommodating space into a plurality of independent accommodating chambers; the plurality of accommodating chambers are respectively used for placing a plurality of independent semiconductor chips; the main body is provided with first through holes; the first through holes are used for allowing the chemical reagent to enter the accommodating space; the main body and the partition plates are used for preventing the semiconductor chip from being separated from the corresponding accommodating chamber under the action of the chemical reagent.

A wafer support table includes a ceramic base having a wafer placement surface and including an RF electrode and a heater electrode embedded, the RF electrode being closer to the wafer placement surface; a hole extending from a surface of the ceramic base opposite the wafer placement surface toward the RF electrode; and an RF rod through having a top end joined to the RF electrode or joined to a conductive member connected to the RF electrode, wherein the RF rod is a hybrid rod including a first rod member that is made of Ni and constitutes a portion of the RF rod from the top end to a predetermined position and a second rod member that is joined to the first rod member and constitutes a portion of the RF rod from the predetermined position to the base end and is made of a non-magnetic material.

A wafer placement table includes a ceramic base, a first cooling base, and a second cooling base. The ceramic base has a wafer placement surface and incorporates a wafer attracting electrode and a heater electrode. The first cooling base is bonded via a metal bonding layer to a surface of the ceramic base on a side opposite to the wafer placement surface and has a first refrigerant flow channel capable of switching between supply and stop of supply of first refrigerant. The second cooling base is attached via a space layer, capable of supplying heat-transfer gas, to a surface of the first cooling base on a side opposite to the metal bonding layer and has a second refrigerant flow channel capable of switching between supply and stop of supply of second refrigerant.

A plasma processing apparatus comprising: a plasma processing chamber; a substrate support disposed in the plasma processing chamber, and including a lower electrode, an electrostatic chuck, and an edge ring disposed to surround a substrate mounted on the electrostatic chuck; a driving device; an upper electrode disposed above the substrate support. In an example, the apparatus further comprises a source RF power supply; a bias RF power supply configured to supply bias RF power to the lower electrode; at least one conductor; a DC power supply; an RF filter electrically; and a controller configured to control the driving device and the at least one variable passive element, and adjust an incident angle of an ion in the plasma with respect to an edge area of the substrate mounted on the electrostatic chuck.

A base plate has one surface and the other surface opposite to the one surface. An electrostatic chuck is capable of being mounted on the one surface. The base plate includes a refrigerant flow path provided therein. An inner wall of the refrigerant flow path has an upper surface convex toward the one surface in a longitudinal sectional view in a direction intersecting with a direction in which refrigerant flows. An unevenness is formed on the upper surface.

A substrate processing system includes a substrate support and a power supply circuit. The substrate support is configured to support a substrate, wherein the substrate support comprises one or more heating elements. The power supply circuit includes: a direct current-to-alternating current converter configured to convert a first direct current voltage to a first alternating current voltage, where the direct current-to-alternating current converter comprises at least one switch; and an isolation circuit comprising one of a coupled inductor or a transformer. The one of the coupled inductor or the transformer is configured to convert the first alternating current voltage to and second alternating current voltage and isolate the one or more heating elements from an earth ground. The power supply circuit is configured to provide an output voltage to the one or more heating elements based on the second alternating current voltage.

A substrate cleaning method includes: supplying a gas mixture of a cluster forming gas for forming a cluster by adiabatic expansion and a carrier gas having a smaller molecular weight or atomic weight than the cluster forming gas to a nozzle; forming the cluster by injecting the gas mixture from the nozzle; removing particles adhering to the substrate by the cluster; and continuously supplying the carrier gas to the nozzle for a set time period from an end time of the supply of the cluster forming gas to the nozzle.

A multi-zone heater with a plurality of thermocouples such that different heater zones can be monitored for temperature independently. The independent thermocouples may have their leads routed out from the shaft of the heater in a channel that is closed with a joining process that results in hermetic seal adapted to withstand both the interior atmosphere of the shaft and the process chemicals in the process chamber. The thermocouple and its leads may be enclosed with a joining process in which a channel cover is brazed to the heater plate with aluminum.

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 plurality of apertures. The systems may include a plurality of lid stacks equal to a number of the plurality of apertures. The systems may include a plurality of substrate support assemblies equal to the number of apertures defined through the lid plate. Each assembly may be disposed in one of the processing regions and may include an electrostatic chuck body defining a substrate support surface that defines a substrate seat. Each assembly may include a heater embedded within the chuck body. Each assembly may include bipolar electrodes between the heater and the substrate support surface. Each assembly may include a conductive mesh embedded within the body between the heater and bipolar electrodes.

An AlN joined body includes a first AlN member and a second AlN member that are joined together. The content of yttria in the first AlN member is equal to or below the detection limit. The second AlN member contains yttria.