Showerhead electrode assemblies for plasma processing apparatuses

What is claimed is: 1. A showerhead electrode assembly, comprising: a showerhead electrode adapted to be mounted in an interior of a vacuum chamber; a thermal control plate attached to the showerhead electrode at multiple contact regions across the showerhead electrode with plenums between the thermal control plate and the showerhead electrode located between the contact regions; and interface members between the showerhead electrode and the thermal control plate, at the contact regions, wherein each interface member comprises a thermally and electrically conductive gasket portion bonded on a periphery by a particle mitigating seal portion. 2. The showerhead electrode assembly of claim 1 , wherein the contact regions comprise spaced apart annular projections on a lower surface of the thermal control plate, the interface members comprising a plurality of annular interface members sized to cover the annular projections, the particle mitigating seal portion bounding the thermally and electrically conductive gasket portion at an outward perimeter and an inward aperture of each interface member. 3. The showerhead electrode assembly of claim 2 , wherein the particle mitigating seal portion located at the outward perimeter has a curved surface and protrudes from the electrically conductive gasket portion and the particle mitigating seal portion located at the inward aperture has a curved surface and protrudes from the thermally and electrically conductive gasket portion. 4. The showerhead electrode assembly of claim 3 , further comprising baffle rings of anodized aluminum in plenums between the annular projections, each baffle ring including a vertical wall adjacent one of the annular projections, the vertical walls including offsets at lower ends thereof adjacent the contact regions, and each particle mitigating seal portion located in one of the offsets so as to form seals on opposite sides of the contact regions. 5. The showerhead electrode assembly of claim 4 , wherein upper ends of the vertical walls of the baffle rings are separated from the lower surface of the thermal control plate by shims having about the same thickness as the thermally and electrically conductive gasket portion of the interface member. 6. The showerhead electrode assembly of claim 1 , wherein the thermal control plate is of non-anodized aluminum, the thermally and electrically conductive gasket portion of the interface member is a laminate of metal and polymer materials, and the particle mitigating seal portion of the interface member comprise an erosion resistant elastomer or polymer. 7. The showerhead electrode assembly of claim 1 , wherein the showerhead electrode comprises an inner electrode and an outer electrode, and the inner electrode is a circular plate of single crystal silicon and the outer electrode is a ring electrode comprised of a plurality of segments of single crystal silicon. 8. The showerhead electrode assembly of claim 1 , further comprising thermal chokes on an upper surface of the thermal control plate. 9. The showerhead electrode assembly of claim 1 , wherein the interface member is free of silver, nickel and copper. 10. The showerhead electrode assembly of claim 1 , wherein the showerhead electrode includes a silicon electrode plate with gas outlets on one side thereof and the opposite side thereof elastomer bonded to a backing plate which is of non-anodized aluminum. 11. The showerhead electrode assembly of claim 1 , wherein: the contact regions comprise surfaces of spaced-apart annular projections provided on a lower surface of the thermal control plate; the interface members comprise an annular interface member located between each of the annular projections and an upper surface of the showerhead electrode; the thermally and electrically conductive gasket portion of the interface members are composed of a laminate of metal and polymer materials free of silver, nickel and copper; and the particle mitigating seal portion of the interface members bounding an outer perimeter and an inner aperture of each thermally and electrically conductive gasket portion, and is comprised of silicone. 12. The showerhead electrode assembly of claim 11 , wherein: the showerhead electrode comprises an inner electrode and an outer electrode, the inner electrode is a circular plate of single crystal silicon and the outer electrode is a ring electrode comprised of a plurality of segments of single crystal silicon; the particle mitigating seal portions of the interface members have a curved surface and protrude from an outward perimeter and inward aperture of each thermally and electrically conductive gasket portion; and the showerhead electrode assembly further comprises: baffle rings of anodized aluminum in plenums between the annular projections, each baffle ring including a vertical wall adjacent one of the annular projections, the vertical walls including offsets at lower ends thereof adjacent the contact regions; and the particle mitigating seal portions located in the offsets so as to form seals on opposite sides of the contact regions, wherein upper ends of the vertical walls of the baffle rings are separated from the lower surface of the thermal control plate by shims having about the same thickness as the thermally and electrically conductive gasket portions of the interface members. 13. The showerhead electrode assembly of claim 11 , wherein the thermal control plate has an anodized outer surface except at the contact regions which are of non-anodized aluminum. 14. The showerhead electrode assembly of claim 1 , further comprising a backing plate attached to an inner electrode of the showerhead electrode, wherein the contact regions cover about 1% to about 30% of a surface area of the backing plate. 15. The vacuum chamber comprising the showerhead electrode assembly of claim 1 , further comprising: a temperature controller controlling a temperature of the showerhead electrode assembly; a power supply adapted to supply power to a heater which heats the thermal control plate in thermal response to the temperature controller; a fluid control adapted to supply fluid to a temperature controlled top wall of the vacuum chamber in response to the temperature controller; and a temperature sensor arrangement adapted to measure a temperature of one or more portions of the showerhead electrode and supply information to the temperature controller, wherein the top wall of the vacuum chamber is optionally electrically grounded. 16. A method of controlling plasma etching in a plasma etching chamber, comprising: supplying process gas to the plasma etching chamber through the showerhead electrode assembly of claim 1 , the process gas flowing into a gap between the showerhead electrode and a bottom electrode on which a semiconductor substrate is supported; and etching the semiconductor substrate in the plasma etching chamber by applying RF power to the showerhead electrode and energizing the process gas into a plasma state, wherein a temperature of the showerhead electrode is controlled by the thermal control plate via enhanced thermal conduction through the thermally and electrically conductive gasket portion of the interface members. 17. The method of claim 16 , further comprising heating the showerhead electrode to a temperature of at least about 80° C. 18. The method of claim 17 , wherein the heating of the showerhead electrode comprises heating and maintaining the showerhead electrode at a temperature of at least about 100° C. 19. The method of claim 17