Flow structures for use with an electrochemical cell

What is claimed is: 1. A flow structure for use in an electrochemical cell, comprising: a compacted porous metallic substrate having a void volume greater than about 55% and yield strength greater than about 12,000 psi, wherein the compacted porous metallic substrate is formed by: selecting a porous metallic substrate with a void volume between about 75% and about 98%; and compacting uniformly the porous metallic substrate causing plastic deformation and thereby forming the compacted porous metallic substrate and increasing the yield strength to greater than about 12,000 psi; at least one micro-porous material layer laminated on one side of the compacted porous metallic substrate, wherein an average pore size of the at least one micro-porous material layer is smaller than an average pore size of the compacted porous metallic substrate. 2. The flow structure of claim 1 , wherein a porosity gradient is formed through the flow structure by laminating a plurality of micro-porous material layers on the compacted porous metallic substrate, each micro-porous material layer having a pore size smaller than an immediately preceding layer. 3. The flow structure of claim 1 , wherein pore size of the at least one micro-porous material layer ranges from about 0.5 μm to about 10 μm. 4. The flow structure of claim 1 , wherein the compacted porous metallic substrate comprises a high density region and a low density region, wherein the high density region has lower porosity that the low density region. 5. The flow structure of claim 4 , wherein the high density region has a higher yield strength than the low density region. 6. The flow structure of claim 1 , further comprising one or more fillers laminated to a surface of the compacted porous metallic substrate after compaction, wherein the fillers make the surface substantially smooth and uniform. 7. The flow structure of claim 6 , wherein the surface has a surface flatness of less than about 0.0005 inches. 8. The flow structure of claim 6 , wherein the fillers form a covering on the surface having a thickness between about 0.01 inches to about 0.001 inches. 9. The flow structure of claim 6 , wherein the fillers are formed of at least one of graphite epoxy, carbon black, carbon fibers, graphite beads, or glass beads. 10. The flow structure of claim 6 , wherein the fillers include a binder configured to increase the strength of the fillers. 11. The flow structure of claim 10 , wherein the fillers include additives and the additives include at least one of pore formers, fibers, or powders. 12. An electrochemical cell for use in high differential pressure operations, comprising: a first electrode, a second electrode, and a proton exchange membrane disposed therebetween; a first flow structure in fluid and electrical communication with the first electrode, comprising: a first compacted porous metallic substrate having a void volume greater than about 55% and yield strength greater than about 12,000 psi, wherein the first compacted porous metallic substrate is formed by: selecting a porous metallic substrate with a void volume between about 75% and about 98%; and compacting uniformly the porous metallic substrate causing plastic deformation and thereby forming the first compacted porous metallic substrate and increasing the yield strength to greater than about 12,000 psi; at least one micro-porous material layer laminated on one side of the compacted porous metallic substrate, wherein an average pore size of the at least one micro-porous material layer is smaller than an average pore size of the compacted porous metallic substrate; and a second flow structure comprising a second porous metallic substrate, wherein the second flow structure is in fluid and electrical communication with the second electrode. 13. The electrochemical cell of claim 12 , wherein at least one of the first and the second flow structures comprise a porosity gradient along the flow structure. 14. The electrochemical cell of claim 12 , wherein the first flow structure is compacted to a density level greater than that of the second flow structure.