Embodiments disclosed herein include an abatement system for abating compounds produced in semiconductor processes. The abatement system includes an exhaust cooling apparatus located downstream of a plasma source. The exhaust cooling apparatus includes a plate and a cooling plate disposed downstream of the plate. During operation, materials collected on the plate react with cleaning radicals to form a gas. The temperature of the plate is higher than the temperature of the cooling plate in order to improve the reaction rate of the reaction of the cleaning radicals and the materials on the plate.

There is provision of a plasma processing apparatus including a chamber; a gas inlet for supplying a first gas containing fluorine and supplying a second gas into the chamber; a plasma generator configured to generate a plasma from the first gas and the second gas supplied into the chamber; an optical emission spectrometer (OES) configured to measure light emission intensities of first radicals and second radicals in the plasma, the first radicals originating from the first gas, the second radicals originating from the second gas; an expendable part disposed in the chamber; and a processor configured to determine a wastage rate of the expendable part based on the measured light emission intensities of the first radicals and the second radicals.

A cleaning method is provided. In the cleaning method, a cleaning gas is supplied into a processing chamber, a radio frequency (RF) power for plasma generation is applied to one of a first electrode on which a substrate is to be mounted and a second electrode disposed to be opposite to the first electrode in the processing chamber, and a negative voltage is applied to an edge ring disposed to surround the substrate. Further, plasma is generated from the cleaning gas and a cleaning process using the plasma is performed.

A single plasma nozzle of a plasma treatment station is used to treat the card surface prior to performing drop-on-demand printing on the card surface. The single plasma nozzle has a plasma discharge width that is less than the width of the card. The card and the plasma nozzle are moved relative to one another using a two direction control scheme during plasma treatment in order to be able to plasma treat a desired area of the card surface. The card and the plasma nozzle may also be moveable toward or away from one another to change the distance therebetween.

The present invention provides a plasma generating system that includes: a programmable logic controller (PLC) and a plurality of reactor systems coupled to the PLC by a daisy chain network. Each of the plurality of reactor systems include: a microwave generator for generating microwave energy; and a power supply for providing electrical power to the microwave generator and including a controller, where the controller comprises: at least one microprocessor; and a module communicatively coupled to the at least one processor and including at least one of digital input-output (DIO) and analogue input-output (AIO).

A precleaning apparatus includes a chamber having an internal space in which a substrate is cleaned, a substrate support disposed in the chamber and configured to support the substrate, a plasma generation unit disposed in the chamber and configured to generate plasma gas, a heating unit configured to heat the substrate on the substrate support, a cleaning gas supply unit configured to supply gas for oxide etching to the internal space of the chamber, and a hydrogen gas supply unit configured to supply hydrogen gas to the internal space of the chamber.

Methods of dicing semiconductor wafers, each wafer having a plurality of integrated circuits, are described. A method includes forming a mask above the semiconductor wafer, the mask including a layer covering and protecting the integrated circuits. The mask and a portion of the semiconductor wafer are patterned with a laser scribing process to provide a patterned mask and to form trenches partially into but not through the semiconductor wafer between the integrated circuits. Each of the trenches has a width. The semiconductor wafer is plasma etched through the trenches to form corresponding trench extensions and to singulate the integrated circuits. Each of the corresponding trench extensions has the width.

There is provision of a method of determining wastage including: processing a substrate using a plasma generated by multiple gases including fluorine gas; obtaining light emission intensity of each gas of the multiple gases including fluorine gas from the plasma, by an optical emission spectrometer (OES); and calculating a wastage rate of a particular expendable part from the obtained light emission intensity of each gas of the multiple gases including fluorine gas, with reference to a storage section storing a wastage rate of the particular expendable part in association with the light emission intensity of each gas of the multiple gases including fluorine gas.

Disclosed is a substrate processing system which enables combined static and pass-by processing. Also, a system architecture is provided, which reduces footprint size. The system is constructed such that the substrates are processed therein vertically, and each chamber has a processing source attached to one sidewall thereof, wherein the other sidewall backs to a complementary processing chamber. The chamber system can be milled from a single block of metal, e.g., aluminum, wherein the block is milled from both sides, such that a wall remains and separates each two complementary processing chambers.

A server trains a neural network by feeding a first set of input time-series data of one or more sensors of a first processing chamber that is within specification to the neural network to produce a corresponding first set of output time-series data. The server calculates a first error. The server feeds a second set of input time-series data from corresponding one or more sensors associated with a second processing chamber under test to the trained neural network to produce a corresponding second set of output time-series data. The server calculates a second error. Responsive to the difference between a second error between the second set of input time-series data and the corresponding second set of output time-series data and a first error between the first set of input time-series data and the corresponding first set of output time-series data being equal to or exceeding a threshold amount, the server declares that the second processing chamber under test mismatches the first processing chamber that is within specifications.