Inductively coupled RF plasma source with magnetic confinement and faraday shielding

Abstract

Disclosed is an inductively coupled RF plasma source that provides both magnetic confinement to reduce plasma losses and Faraday shielding to suppress parasitic capacitive components. The inductively coupled RF plasma system comprises an RF power source, plasma chamber, an array of permanent magnets, and an antenna array. The plasma chamber is comprised of walls and a dielectric window having an inner and outer surface wherein the inner surface forms a wall of the plasma chamber. The array of parallel conductive permanent magnets is electrically interconnected and embedded within the dielectric window walls proximate to the inner surface and coupled to ground on one end. The permanent magnet array elements are alternately magnetized toward and away from plasma in the plasma chamber to form a multi-cusp magnetic field. The antenna array may be comprised of parallel tubes through which an RF current is circulated. The antenna array is oriented perpendicular to the permanent magnet array.

Description

BACKGROUND OF THE INVENTION[0001]1. Field of the Invention[0002]Embodiments of the invention relate to the field of semiconductor device fabrication. More particularly, the present invention relates to an inductively coupled RF plasma generating apparatus that is capable of providing both magnetic confinement and Faraday shielding.[0003]2. Discussion of Related Art[0004]Plasmas are used in a variety of ways in semiconductor processing to implant wafers or substrates with various dopants, to deposit or to etch thin films. Such processes involve the directional deposition or doping of ions on or beneath the surface of a target substrate. Other processes include plasma etching where the directionality of the etching species determines the quality of the trenches to be etched.[0005]Generally, plasmas are generated by supplying energy to a neutral gas introduced into a chamber to form charged carriers which are implanted into the target substrate. For example, plasma doping (PLAD) system...

AI Technical Summary

Benefits of technology

The patent describes an inductively coupled RF plasma system that provides both magnetic confinement to reduce plasma losses and Faraday shielding to suppress parasitic capacitive components. The system includes an RF power source, a plasma chamber, an array of permanent magnets, and an antenna array. The plasma chamber has a magnetic field formed by the magnets to confine the plasma and suppress instability. The antenna array is positioned perpendicular to the magnets to create an electric field to ionize the gas. The system has greater stability, efficiency, and control over plasma production compared to previous systems.

Problems solved by technology

Moreover, ion impact to the electrode or dielectric causes an undesirable sputtering of the surface impacted.

Capacitively coupled RF plasma sources also suffer from other disadvantages.

In addition, capacitively coupled RF plasma sources provide low plasma density therefore are less suitable for ion sources applications.

This creates the aforementioned undesirable additional power dissipation and material sputtering.

Internal antenna configurations allow better magnetic confinement than external antenna configurations but preclude the use of a Faraday shield.

External antenna configurations place the antenna behind a dielectric window which interferes with the application of multi-cusp magnetic confinement on a significant portion of the plasma chamber surface area (i.e., the dielectric window).

Thus, a trade-off exists between internal and external antenna configurations in that an external antenna configurations allows the use of a Faraday shield inside the plasma chamber, but does not allow for magnets to provide plasma confinement and an internal antenna configuration allows the use of magnets for better plasma confinement, but does not provide for a Faraday shield.

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