Fuel cell interconnect optimized for operation in hydrogen fuel

What is claimed is: 1. A fuel cell interconnect, comprising: fuel ribs disposed on a first side of the interconnect and a least partially defining fuel channels; air ribs disposed on an opposing second side of the interconnect and at least partially defining air channels, fuel holes that extend through the interconnect; and seal regions disposed on the second side of the interconnect and surrounding the fuel holes, wherein: the fuel channels comprise central fuel channels disposed in a central fuel field and peripheral fuel channels disposed in peripheral fuel fields disposed on opposing sides of the central fuel field, the central fuel channels are located between the fuel ribs and have larger cross-sectional areas than the peripheral fuel channels, such that when hydrogen is provided to the fuel channels, a hydrogen mass flow rate through the central fuel channels is higher than a hydrogen mass flow rate though the peripheral fuel channels; the air channels comprise central air channels disposed in a central air field and peripheral air channels disposed in peripheral air fields disposed on opposing sides of the central air field; and some of the peripheral air channels extend from a first peripheral edge of the interconnect to an opposing second peripheral edge of the interconnect and have edge portions, located adjacent to the first and the second peripheral edges of the interconnect, that are bent at an angle of 30 to 60 degrees relative to opposing third and fourth edges of the interconnect and to the central air channels. 2. The interconnect of claim 1 , wherein: widths of the central fuel channels are larger than widths of the peripheral fuel channels; and the cross-sectional areas of the central fuel channels are from 5% to 40% greater than the cross-sectional areas of the peripheral fuel channels. 3. The interconnect of claim 1 , wherein the central fuel channels have shorter lengths than the peripheral fuel channels. 4. The interconnect of claim 1 , further comprising: fuel manifolds formed in the first side of the interconnect and fluidly connected to the fuel channels; and a fuel hole disposed in each of the fuel manifolds and extending through the interconnect. 5. The interconnect of claim 4 , wherein at least some of the peripheral fuel channels and the corresponding fuel ribs extend into the fuel manifolds, such that peripheral fuel channels disposed closer to the central fuel field are shorter than peripheral fuel channels disposed further from the central fuel field. 6. The interconnect of claim 4 , wherein each of the fuel manifolds has a maximum depth adjacent to the fuel hole and a minimum depth adjacent to opposing edges of the interconnect. 7. The interconnect of claim 4 , further comprising fuel bumpers disposed in the fuel manifolds and configured to reduce fuel mass flow through the peripheral fuel channels, wherein the fuel bumpers and the fuel channels extend lengthwise in perpendicular directions. 8. The interconnect of claim 1 , further comprising fuel blockers disposed between the fuel ribs in the peripheral fuel fields, the fuel blockers configured to reduce fuel mass flow through the peripheral fuel channels, wherein the fuel blockers and the peripheral fuel channels extend lengthwise in perpendicular directions. 9. The interconnect of claim 1 , wherein the interconnect comprises a chromium iron alloy comprising from 7 wt. % to 10 wt. % iron and 90 wt. % to 93 wt. % chromium. 10. The interconnect of claim 1 , wherein the central air channels have larger cross-sectional areas than the peripheral air channels. 11. The interconnect of claim 10 , wherein the cross-sectional areas of the central air channels are from 5% to 40% greater than the cross-sectional areas of the peripheral air channels. 12. The interconnect of claim 1 , wherein the central air channels have shorter lengths than the peripheral air channels. 13. The interconnect of claim 12 , wherein end portions of the air ribs which define the bent peripheral air channels partially block air flow to outermost ones of the peripheral air channels. 14. The interconnect of claim 13 , wherein the bent air channels are longer than at least some of the central air channels. 15. The interconnect of claim 1 , wherein: at least one of the central air channels has at least one of a larger cross-sectional area or a shorter length than at least one of the respective peripheral air channels to increase air flow through the central air channels. 16. A fuel cell stack comprising solid oxide fuel cells separated by interconnects of claim 1 . 17. A fuel cell system containing a fuel cell stack of claim 16 , wherein air is provided into the air channels and more of the air flows through the central air channels than through the peripheral air channels. 18. The interconnect of claim 1 , wherein: the fuel ribs comprise central fuel ribs which define the central fuel channels, and peripheral fuel ribs which define the peripheral fuel channels; each of the central fuel channels is located entirely between a respective two of the central fuel ribs; and each of the central fuel ribs is elongated lengthwise along a same lengthwise direction as the central fuel channels. 19. The interconnect of claim 1 , wherein fuel blockers are disposed in the peripheral fuel fields but not in the central fuel field. 20. The interconnect of claim 1 , wherein the first and the second peripheral edges of the interconnect that are bent form air spaces disposed on at least one side of each of the seal regions, and the air spaces are configured to increase air mass flows around the seal regions and through the central air channels. 21. The interconnect of claim 1 , wherein the first and the second peripheral edges of the interconnect that are bent form air spaces disposed on opposing sides of each of the seal regions, and the air spaces are configured to increase air mass flows around the seal regions and through the central air channels.