A plasma generator is described comprising an elongate member having a distal end, a proximal end, and a lumen extending therethrough, the proximal end configured to be connectable to a source of an inert gas, a plasma generation tip disposed at the distal end of the elongate member, the plasma generation tip configured to be in electrical communication with a power source, and an activation switch configured to control generation of plasma at the plasma generation tip, wherein the plasma generator is configured to be operably connectable to a medical device.

High pressure spatial chemical vapor deposition apparatuses and related process are disclosed for forming thin films on a substrate. An enclosure includes plural process chambers fluidly isolated from each other by radial separating barriers. Each chamber contains a different source gas comprising one or more volatile reactive species. The substrate is supported beneath the chambers on a rotating heated susceptor. Rotation of the susceptor carries the substrate in a path which consecutively exposes the substrate to the volatile reactive species in each process chamber. The gases first mix in the gaseous boundary layer formed adjacent the substrate. A thin film gradually grows in thickness on the substrate with each successive pass and exposure to the volatile reactive species in each of the individual process chambers. The film may be grown at high pressures exceeding 1 atmosphere in some implementations. A modular design includes an outer shell and different interchangeable process inserts.

A plasma generator and a method for the pulsed provision of electrical power having a frequency of at least 40 KHz to at least two process chambers are described. The plasma generator comprises: a control unit configured to obtain and evaluate process data about processes in the at least two process chambers; a controllable power supply having an output, the controllable power supply being configured to output a direct current at a predetermined voltage and/or intensity at its output in response to a control signal from the control unit; and a switching unit having a first input connected to the output of the power supply and having at least two switching unit outputs for respective connection to one of the at least two process chambers. The switching unit is configured to form, from a direct current at the input, an alternating current having a predetermined frequency of at least 40 KHz as an output signal and to selectively output the output signal as a pulse for a predetermined pulse duration to one of the switching unit outputs in response to a control signal from the control unit. The control unit is configured to coordinate power requirements of the at least two process chambers and to drive the power supply and the switching unit such that at the respective switching unit outputs communicating with the process chambers, substantially the power corresponding to the power requirements is provided as pulses over a period of time, wherein the pulses of the respective process chambers are temporally offset from each other such that the process chambers can be operated simultaneously.

IR radiation may be used to examine substrates prior to a fabrication operation in order to adjust processing parameters of the fabrication operation, or to determine features of the substrate. A thermographic image may be collected and provided to a transfer function or machine learning model to determine processing parameters or features. The processing parameters may improve the uniformity of the wafer and/or achieve a desired target feature value.

The invention discloses a semiconductor multi-station processing chamber. Each of the multiple station includes a downward concave accommodation defined by walls and receives a pedestal therein. The pedestal and the walls define a first gap. A showerhead plate mounted on an upper lid above the pedestal to define a processing region. A second gap for supply swiping gas is defined between the showerhead plate and the upper lid. An isolation member is liftable between the downward concave accommodation and the showerhead plate to optionally encircle a processing region defined by the pedestal and the showerhead plate or to retract back into the downward concave accommodation. Such that, when the isolation member surrounds and encircles the processing region, the station is able to be structurally isolated from its neighboring one station.

The vacuum processing apparatus for performing predetermined vacuum processing on a processing surface of a to-be-processed substrate is made up of: a vacuum chamber having disposed therein a to-be-processed substrate and having formed, on an upper wall of the vacuum chamber, a mounting opening facing the processing surface where a direction in which the processing surface looks is defined as an upper side; a processing unit for performing therein vacuum processing; and a communication pipe having a predetermined length and being interposed between the vacuum chamber and the processing unit such that predetermined processing is performed, through the communication pipe, on the to-be-processed substrate inside the vacuum chamber. The processing unit has an engaging means to which is coupled a swing arm for swinging about a rotary shaft extending perpendicularly to a vertical direction for selectively engaging the vacuum chamber and the communication pipe or the processing unit and the communication pipe.

A method of producing hydrogen ions includes generating a diode-type HF plasma PL. This allows to set or adjust the energy of ions output by the plasma source in an improved manner.

A maintenance apparatus includes a case and a maintenance mechanism. The case includes an opening having a size corresponding to a second gate of a vacuum processing apparatus including a processing chamber having a first gate through which a substrate is loaded and unloaded and the second gate different from the first gate. The case is attachable to the second gate while maintaining airtightness. The maintenance mechanism is provided in the case and is configured to perform at least one of an operation of detaching a consumed part in the processing chamber through the opening, an operation of attaching a replacement part in the processing chamber and an operation of cleaning the processing chamber.

Provided are a display panel, a plasma etching method and a system. After patterning a metal film layer on a substrate with a chlorine-containing gas, a post-treatment for suppressing corrosion is implemented by using plasma containing an oxygen-containing gas and a hydrogen-fluoride-containing gas. Thus, the surface of the metal film layer is an aluminum ion-containing crystal, which solves the technical problem of corrosion of the aluminum layer in the plasma etching technology of the prior art.

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.