Techniques are disclosed for an electron cyclotron rotation (ECR)-enhanced hollow cathode plasma source (HCPS). A cylindrical magnet is placed around the neck of a hollow cathode under the influence of an RF field. A plasma gas is introduced in the hollow cathode that undergoes phase transition to a plasma containing free electrons and gas ions. The magnetic field of the magnet causes ECR that confines free electrons to a narrow spiraling beam traveling down the body of the hollow cathode. Unlike traditional methods, the present ECR-enhanced design confines the electrons and ions to a narrow path away from the walls of the cathode. The high-density, stable plasma is available at the distal end of the hollow cathode. A multicavity design utilizes multiple cavities with multiple aligned magnets in a single reactor suitable for various processes including, PECVD, PEALD, ALE, etc.

A remote plasma source (RPS) for generating etchants leverages symmetrical hallow cathode cavities to increase etchant rates. The RPS includes an upper electrode with a first hollow cavity configured to induce a hollow cathode effect within the first hollow cavity, a lower electrode with a second hollow cavity configured to induce a hollow cathode effect within the second hollow cavity, wherein the first hollow cavity and the second hollow cavity are symmetrical, a first gap positioned between and electrically separating the upper electrode and the lower electrode, and an annular dielectric cover in direct contact with the lower electrode in the first gap and forms a second gap between an uppermost surface of the annular dielectric cover and a lowermost surface of the upper electrode. The annular dielectric cover fills approximately 50% to approximately 95% of a height of the first gap.

The disclosure pertains to a capacitively coupled plasma source in which VHF power is applied through an impedance-matching coaxial resonator having a symmetrical power distribution.

Provided herein are approaches for controlling radicals in proximity to a wafer. In some embodiments, a system may include a radical source operable to generate radicals in proximity to the wafer, and a filter positioned between the radical source and the wafer, wherein the filter includes a first plate operable to control radicals generated by the radical source. The system may further include an ion source operable to deliver an ion beam to the wafer, wherein the ion beam passes outside the filter.

A substrate processing apparatus including an inner chamber formed by an upper portion and a lower portion, a substrate support to support a substrate within the upper portion of the inner chamber, a plasma system to provide the inner chamber with plasma species from the top side of the inner chamber, and an outer chamber surrounding the upper portion of the inner chamber. The lower portion of the inner chamber extends to the outside of the outer chamber and remains uncovered by the outer chamber.

The present invention resides in the unifying idea of synchronizing a positive voltage pulse supplied to an electrically conductive or ferromagnetic tube and a exciting negative voltage pulse on a hollow cathode induced on the background of a high-frequency capacitive discharge.

In one embodiment, the invention relates to a method of generating low-temperature plasma in a vacuum chamber comprising a hollow cathode and an electrode, the method comprising the step of igniting the pulsed DC discharge in the hollow cathode wherein the positive voltage pulse at least partially overlaps with the negative voltage pulse, and the positive voltage pulse at least partially overlaps with the negative voltage pulse on the hollow cathode.

In another embodiment, the present invention relates to a method of coating the inner walls of hollow tubes which utilizes the above-mentioned low-temperature plasma generation process.

In another embodiment, the invention relates to a low-temperature plasma generating device comprising a hollow cathode located in the vacuum chamber, a RF plasma source, a pulse DC burst source, and a bipolar pulse source.

In another embodiment, an object of the invention is an apparatus adapted to coat the inner sides of hollow tubes comprising a low-temperature plasma generating device.

A hollow cathode includes an insulation plate having cathode holes. Bottom electrodes are below the insulation plate. The bottom electrodes define first holes having a width greater than a width of the cathode holes. Top electrodes are at an opposite side of the insulation plate from the bottom electrodes. The top electrodes define second holes aligned with the first holes along a direction orthogonal to the upper surface of the insulation plate.

Disclosed are a plasma processing apparatus and a method of manufacturing a semiconductor device using the same. The plasma processing apparatus comprises a chamber, an electrostatic chuck in the chamber and loading a substrate, a plasma electrode generating an upper plasma on the electrostatic chuck; and a hollow cathode between the plasma electrode and the electrostatic chuck, wherein the hollow cathode generates a lower plasma below the upper plasma. The hollow cathode comprises cathode holes each having a size less than a thickness of a plasma sheath of the upper plasma.

The embodiments herein relate to methods and apparatus for performing ion etching on a semiconductor substrate, as well as methods for forming such apparatus. In some embodiments, an electrode assembly may be fabricated, the electrode assembly including a plurality of electrodes having different purposes, with each electrode secured to the next in a mechanically stable manner. Apertures may be formed in each electrode after the electrodes are secured together, thereby ensuring that the apertures are well-aligned between neighboring electrodes. In some cases, the electrodes are made from degeneratively doped silicon, and the electrode assembly is secured together through electrostatic bonding. Other electrode materials and methods of securing may also be used. The electrode assembly may include a hollow cathode emitter electrode in some cases, which may have a frustoconical or other non-cylindrical aperture shape. A chamber liner and/or reflector may also be present in some cases.

A system includes a structure including an upper chamber linked to a lower chamber, the upper chamber including a gas inlet configured to enable a gas to enter the upper chamber, the lower chamber including a plasma outlet, a microwave generator configured to deliver a microwave to the upper chamber causing atoms in the gas to ionize to generate a charged particle microwave plasma, a hollow cathode centrally positioned within the lower chamber and an anode surrounding an interior wall of the lower chamber, and a power source for generating power, the power flowing between the anode and the hollow cathode causing atoms in the gas to ionize to generate a charged particle hollow cathode plasma.