Dual-plenum showerhead with interleaved plenum sub-volumes

What is claimed is: 1. An apparatus comprising: an outer wall, the outer wall substantially axially symmetric about a first axis; a first inlet; a second inlet; and a dual plenum volume substantially defined by the outer wall, the dual plenum volume divided into an even number of sub-volumes by radial barriers substantially extending from locations proximate to the first axis to the outer wall, wherein: the sub-volumes include a set of first sub-volumes and a set of second sub-volumes, each first sub-volume is interposed between neighboring second sub-volumes of the set of second sub-volumes, each second sub-volume is interposed between neighboring first sub-volumes of the set of first sub-volumes, each sub-volume has a plurality of plenum gas distribution holes passing through a bottom portion of the outer wall, the first sub-volumes form a first plenum volume, the second sub-volumes form a second plenum volume, the first inlet is configured to supply a first process gas to the first sub-volumes, the second inlet is configured to supply a second process gas to the second sub-volumes, the first plenum volume is fluidically isolated from the second plenum volume between the plenum gas distribution holes and the first inlet, and the second plenum volume is fluidically isolated from the first plenum volume between the plenum gas distribution holes and the second inlet. 2. The apparatus of claim 1 , wherein the sub-volumes are all substantially the same size and overall shape. 3. The apparatus of claim 1 , wherein one or more of the sub-volumes is further partitioned into two or more sub-sub-volumes by one or more additional radial barriers and wherein each of the sub-sub-volumes of a sub-volume is configured to be supplied the same process gas. 4. The apparatus of claim 1 , further comprising: a first gas feed tube with a first interior volume, and a second gas feed tube, wherein: the first gas feed tube is concentric with the second gas feed tube, thereby creating an annular, second interior volume between the first gas feed tube and the second gas feed tube, the first interior volume is configured to convey the first process gas from the first inlet to the first sub-volumes, and the second interior volume is configured to convey the second process gas from the second inlet to the second sub-volumes. 5. The apparatus of claim 4 , wherein the first gas feed tube includes a stepped-up region where the diameter of the first gas feed tube is larger than the diameter of the first gas feed tube. 6. The apparatus of claim 5 , wherein the stepped-up region includes channels that extend in a direction parallel to the first axis, wherein: each channel is in fluidic communication with the second interior volume, and each channel serves as a fluidic connection between the second interior volume and one of the second sub-volumes. 7. The apparatus of claim 6 , wherein the stepped-up region includes slots that extend radially from the first interior volume and through the first gas feed tube, wherein: each slot is in fluidic communication with the first interior volume, and each slot serves as a fluidic connection between the first interior volume and one of the first sub-volumes. 8. The apparatus of claim 7 , wherein each slot is interposed between neighboring channels and each channel is interposed between neighboring slots. 9. The apparatus of claim 1 , wherein the sub-volumes decrease in height along the first axis as a function of radial position with respect to the first axis. 10. The apparatus of claim 1 , wherein the sub-volumes increase in height along the first axis as a function of radial position with respect to the first axis. 11. The apparatus of claim 1 , wherein there are at least 10 sub-volumes. 12. The apparatus of claim 1 , wherein the number of sub-volumes is an even number of sub-volumes greater than or equal to 10 sub-volumes and less than or equal to 24 sub-volumes. 13. The apparatus of claim 1 , further comprising a faceplate, wherein the faceplate includes a plurality of gas distribution holes through the faceplate and is positioned such that openings of the gas distribution holes face the plenum gas distribution holes in the outer wall. 14. A semiconductor processing tool comprising: a semiconductor processing chamber; and a dual-plenum showerhead, the dual-plenum showerhead including: an outer wall, the outer wall substantially axially symmetric about a first axis; a first inlet; a second inlet; and a dual plenum volume substantially defined by the outer wall, the dual plenum volume divided into an even number of sub-volumes by radial barriers substantially extending from locations proximate to the first axis to the outer wall, wherein: the sub-volumes include a set of first sub-volumes and a set of second sub-volumes, each first sub-volume is interposed between neighboring second sub-volumes of the set of second sub-volumes, each second sub-volume is interposed between neighboring first sub-volumes of the set of first sub-volumes, each sub-volume has a plurality of plenum gas distribution holes passing through a bottom portion of the outer wall, the first sub-volumes form a first plenum volume, the second sub-volumes form a second plenum volume, the first inlet is configured to supply a first process gas to the first sub-volumes, the second inlet is configured to supply a second process gas to the second sub-volumes, the first plenum volume is fluidically isolated from the second plenum volume between the plenum gas distribution holes and the first inlet, the second plenum volume is fluidically isolated from the first plenum volume between the plenum gas distribution holes and the second inlet, and the dual-plenum showerhead is configured to deliver the first process gas and the second process gas to a semiconductor wafer when the semiconductor wafer within the semiconductor processing chamber. 15. The semiconductor processing tool of claim 14 , wherein the faceplate is offset from the outer wall in a direction parallel to the first axis by a gap. 16. The apparatus of claim 14 , wherein the sub-volumes are all substantially the same size and overall shape. 17. The apparatus of claim 14 , wherein one or more of the sub-volumes is further partitioned into two or more sub-sub-volumes by one or more additional radial barriers and wherein each of the sub-sub-volumes of a sub-volume is configured to be supplied the same process gas. 18. The apparatus of claim 1 , wherein the sub-volumes decrease in height along the first axis as a function of radial position with respect to the first axis. 19. The apparatus of claim 1 , wherein the sub-volumes increase in height along the first axis as a function of radial position with respect to the first axis. 20. The apparatus of claim 1 , wherein the number of sub-volumes is an even number of sub-volumes greater than or equal to 10 sub-volumes and less than or equal to 24 sub-volumes.