Magnetic induction plasma source for semiconductor processes and equipment

The invention claimed is: 1. A magnetic induction plasma system, comprising: a first plasma source including a plurality of first sections and a plurality of second sections fluidly coupled with each other such that at least a portion of plasma products generated inside the first plasma source circulate through at least one of the plurality of first sections and at least one of the plurality of second sections inside the first plasma source, wherein each of the plurality of second sections comprises a dielectric material, wherein the plurality of first sections and the plurality of second sections are arranged in an alternating manner such that the plurality of first sections are electrically insulated from each other at least in part by the plurality of second sections; a plurality of first magnetic elements, wherein each of the plurality of first magnetic elements defines a closed loop and is positioned around one of the plurality of second sections; and wherein the first plasma source defines a first toroidal shape, the first toroidal shape having a first toroidal extension and a first toroidal axis perpendicular to the first toroidal extension, wherein each of the plurality of first sections includes a first dimension parallel to the first toroidal axis, wherein each of the plurality of second sections includes a second dimension parallel to the first toroidal axis, wherein the first dimension is greater than the second dimension such that the plurality of second sections defines a plurality of annular recesses, wherein each of the plurality of annular recesses is configured to receive one of the plurality of first magnetic elements such that the magnetic induction plasma system is integratable into a semiconductor processing chamber having a gas inlet assembly disposed upstream of the magnetic induction plasma system, wherein the plurality of first sections is configured to support a planar surface of the gas inlet assembly, and wherein the plurality of annular recesses is configured to allow the plurality of magnetic elements to be disposed below the planar surface of the gas inlet assembly without contacting the planar surface of the gas inlet assembly. 2. The magnetic induction plasma system of claim 1 , wherein each of the plurality of first sections comprises a first opening and a second opening, wherein each of the plurality of first sections and the corresponding first and second openings define a flow passage parallel to the first toroidal axis, wherein the first opening of each of the plurality of first sections is configured to receive a precursor into the corresponding first section and generate the plasma products inside the first plasma source, wherein the second opening of each of the plurality of first sections provides access for the generated plasma products to flow from the corresponding first section. 3. The magnetic induction plasma system of claim 1 , further comprising a plurality of first dielectric ring members each positioned at a top rim of one first section of the plurality of first sections and a plurality of second dielectric ring members each positioned at a bottom rim of one first section of the plurality of first sections such that the plurality of first sections are electrically insulated from each other when the magnetic induction plasma system is integrated into the semiconductor processing chamber and positioned between metal components of the semiconductor processing chamber along the first toroidal axis. 4. The magnetic induction plasma system of claim 3 , wherein the semiconductor processing chamber further comprises a gas distribution assembly, wherein the gas distribution assembly is positioned downstream of the magnetic induction plasma system, wherein the plurality of first dielectric ring members defines a first planar supporting surface and is configured to support the planar surface of the gas inlet assembly, and wherein the plurality of second dielectric ring members defines a second planar supporting surface and is configured to be supported by a planar surface of the gas distribution assembly. 5. The magnetic induction plasma system of claim 1 , wherein each of the plurality of first sections includes an arcuate tubular body. 6. The magnetic induction plasma system of claim 1 , wherein each of the plurality of second sections comprises a pair of flanges configured at two opposite ends of each second section and configured to couple each second section with two adjacent first sections. 7. The magnetic induction plasma system of claim 1 , wherein each of the plurality of first sections includes a first extension along the first toroidal extension, wherein each of the plurality of second sections includes a second extension along the first toroidal extension, a ratio of the first extension to the second extension is between about 10:1 and about 2:1 such that circulation of at least a portion of plasma products inside the first plasma source is facilitated. 8. The magnetic induction plasma system of claim 1 , further comprising: a second plasma source defining a second toroidal shape, the second toroidal shape having a second toroidal extension and a second toroidal axis perpendicular to the second toroidal extension, the second toroidal axis aligned with the first toroidal axis, wherein the second plasma source is positioned radially inward from the first plasma source, the second plasma source comprises a third section and a fourth section, at least one of the third section or the fourth section comprises a dielectric material; and at least one second magnetic element defining a closed loop and positioned around at least one of the third section or the fourth section. 9. The magnetic induction plasma system of claim 8 , wherein the at least one second magnetic element is positioned at an azimuthal angle different from an azimuthal angle of each of the plurality of first magnetic elements such that interference between an electric field generated by each of the plurality of first magnetic elements and an electric field generated by the at least one second magnetic element is reduced. 10. The magnetic induction plasma system of claim 8 , wherein the first plasma source and the second plasma source are configured such that the plasma products exiting the first plasma source diffuses onto a first region of a substrate, wherein the first region defines a substantially annular shape, wherein the plasma products exiting the second plasma source diffuses onto a second region of the substrate, wherein the second region defines a substantially circular shape, and the first region and the second region overlap. 11. The magnetic induction plasma system of claim 8 , further comprising: a plurality of electrically coupled first coils each being configured around at least a portion of each of the plurality of first magnetic elements; and a second coil being configured around at least a portion of the at least one second magnetic element, wherein the magnetic induction plasma system is driven by an LLC resonant half bridge circuit, wherein: the LLC resonant half bridge circuit is configured to supply a first current to the plurality of electrically coupled first coils at a frequency that matches a frequency at which the LLC resonant half bridge circuit is configured to supply a second current to the second coil. 12. The magnetic induction plasma system of claim 11 , wherein the LLC resonant half bridge circuit is configured to supply the first current and the second current at a frequency between about 100 kHz and about 20 MHz. 13. The magnetic induction plasma system of claim 11 , wherein the LLC resonant half bridge circuit is conf