A plasma processing apparatus includes a balun having a first unbalanced terminal, a second unbalanced terminal, a first balanced terminal, and a second balanced terminal, a grounded vacuum container, a first electrode electrically connected to the first balanced terminal, a second electrode electrically connected to the second balanced terminal, and a ground electrode arranged in the vacuum container and grounded.

The present technology encompasses plasma sources including a first plate defining a first plurality of apertures arranged in a first set of rows. The first plate may include a first set of electrodes extending along a separate row of the first set of rows. The plasma sources may include a second plate defining a second plurality of apertures arranged in a second set of rows. The second plate may include a second set of electrodes extending along a separate row of the second set of rows. Each aperture of the second plurality of apertures may be axially aligned with an aperture of the first plurality of apertures. The plasma sources may include a third plate positioned between the first plate and the second plate. The third plate may define a third plurality of apertures.

A plasma processing apparatus is provided. The plasma processing apparatus is provided with an upper electrode, a lower electrode, and an electromagnetic wave emission port. The upper electrode is provided so as to allow discharging a processing gas into a processing container. The lower electrode is provided so as to holding a workpiece in the processing container. The electromagnetic wave emission port is provided at a height position between a height position of the upper electrode and a height position of the lower electrode, and is open toward a center of the processing container.

Systems and methods for increasing peak ion energy with a low angular spread of ions are described. In one of the systems, multiple radio frequency (RF) generators that are coupled to an upper electrode associated with a plasma chamber are operated in two different states, such as two different frequency levels, for pulsing of the RF generators. The pulsing of the RF generators facilitates a transfer of ion energy during one of the states to another one of the states for increasing ion energy during the other state to further increase a rate of processing a substrate.

A control circuit for outputting a direct current (DC) signal in the form of a pulsed signal includes a switch circuit having a first terminal, a second terminal, a third terminal, a fourth terminal, a first control terminal, and a second control terminal, wherein the first terminal and the second terminal are input terminals of the DC signal, the third terminal and the fourth terminal are output terminals of the pulsed signal, the first control terminal and the second control terminal receive a first signal or a second signal to control outputting the pulsed signal, in response to the first control terminal and the second control terminal receiving the first signal, the third terminal and the fourth terminal output the pulsed signal, and in response to the first control terminal and the second control terminal receiving the second signal, the third terminal and the fourth terminal stop outputting the pulsed signal; and an energy storage circuit having two terminals connected to the first terminal and the second terminal of the switch circuit to store residual electric energy of the switch circuit when the switch circuit does not output the pulsed signal. The control circuit reduces the oscillation the voltage of occurred at the end of each pulse, and improving the accuracy of controlling the plasma energy and density used in the semiconductor processes.

There is provided a plasma processing apparatus comprising: a plasma processing chamber; a substrate support disposed in the plasma processing chamber; a lower electrode disposed in the substrate support; a conductive member disposed above the substrate support, the conductive member having at least one coolant inlet and at least one coolant outlet, the conductive member being connected to an RF potential or a DC potential; and an upper electrode assembly including: a conductive plate detachably connected to a bottom surface of the conductive member, the conductive plate having one or more coolant channels communicating with the at least one coolant inlet and the at least one coolant outlet; an electrode plate disposed below the conductive plate; and a conductive bonding sheet disposed between the electrode plate and the conductive plate.

Methods for preparing a void-free protective coating are disclosed herein. The void-free protective coating is used on a dielectric window having a central hole, which is used in a plasma treatment tool. A first protective coating layer is applied to the window, leaving an uncoated annular retreat area around the central hole. The first protective coating layer is polished to produce a flat surface and fill in any voids on the window. A second protective coating layer is then applied upon the flat surface of the first protective coating layer to obtain the void-free coating. This increases process uptime and service lifetime of the dielectric window and the plasma treatment tool.

The inventive concept provides a substrate treating method. The substrate treating method for treating a substrate at which thin films are stacked and a hole is formed thereon including treating the substrate using a first plasma including an ion, which is a first treating step; and treating the substrate using a second plasma removed of an ion, which is a second treating step.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a housing defining a treating space; a chuck supporting a substrate at the treating space and providing a bottom electrode for generating a plasma at the treating space; a top electrode; and an ion blocker positioned between the top electrode and the treating space.

A plasma processing apparatus includes a chamber providing a space for processing a substrate, a substrate stage configured to support the substrate within the chamber and including a lower electrode, an upper electrode facing the lower electrode, a focus ring in or on an upper peripheral region of the substrate stage to surround the substrate, and a plasma adjustment assembly in at least one of a first position between the upper electrode and the lower electrode and a second position between the focus ring and the lower electrode, the plasma adjustment assembly including a photoreactive material layer and a plurality of light sources configured to irradiate light onto a local region of the photoreactive material layer. A capacitance of the local region is changed as the light is irradiated to the local region.