Selectively sealing fuel cell porous plate

The invention claimed is: 1. A fuel cell component for a fuel cell comprising a gas diffusion layer and the fuel cell component, the gas diffusion layer being separate and distinct from the fuel cell component, the fuel cell component comprising: an electrode plate including a porous region having a first porosity and a non-porous region having a second porosity less than the first porosity, wherein the non-porous region includes carbon and is provided in a seal recess that forms a perimeter around the electrode plate to receive an interfacial seal, the seal recess formed on one of opposing sides of the electrode plate, and wherein the electrode plate is one of an anode porous plate and a cathode porous plate and includes a plurality of reactant channels formed on one of the opposing sides that extend only partially through a thickness of the electrode plate to provide a reactant flow field that is perpendicular to a stack direction of the fuel cell, which plurality of reactant channels are configured to be in direct fluid communication with an oxidant source or a fuel source of the fuel cell, and a plurality of coolant channels formed on the other one of the opposing sides of the electrode plate that extend only partially through the thickness of the electrode plate to provide a coolant flow field that is perpendicular to the stack direction of the fuel cell. 2. The fuel cell component according to claim 1 , wherein the electrode plate includes an internal manifold, and the perimeter is arranged outside of the internal manifold. 3. The fuel cell component of claim 1 wherein the electrode plate is a unitary structure. 4. The fuel cell component of claim 1 wherein the electrode plate is in direct contact with the gas diffusion layer. 5. The fuel cell component of claim 1 wherein the seal recess extends only partially through the electrode plate to define an interfacial seal receiving surface which mates with the interfacial seal. 6. The fuel cell component of claim 1 wherein the reactant channels extend in a plane of the electrode plate that is perpendicular to the thickness direction of the electrode plate to distribute oxidant or fuel across a planar area of the electrode plate. 7. The fuel cell component of claim 1 wherein the reactant channels have a depth that is less than the thickness of the electrode plate. 8. The fuel cell component of claim 1 wherein the plurality of coolant channels transport product water, which is used as a coolant within the fuel cell including the electrode plate. 9. The fuel cell component of claim 1 wherein a depth of the plurality of reactant channels is greater than a depth of the seal recess. 10. The fuel cell component of claim 1 wherein the electrode plate includes at least one internal manifold having a manifold recess extending around a perimeter thereof, and wherein a surface of the manifold recess is non-porous. 11. A fuel cell comprising: an electrode assembly including a proton exchange membrane positioned between first and second gas diffusion layers; a cathode plate adjacent the first gas diffusion layer opposite the proton exchange membrane; and an anode plate adjacent the second gas diffusion layer opposite the proton exchange membrane, and wherein at least one of the cathode plate and the anode plate is an electrode plate including a porous region having a first porosity and a non-porous region having a second porosity less than the first porosity, wherein the non-porous region includes carbon and is provided in a seal recess that forms a perimeter around the electrode plate to receive an interfacial seal, the seal recess formed in one of opposing sides of the electrode plate, and wherein the electrode plate includes a plurality of reactant channels formed in one of the opposing sides that extend only partially through a thickness of the electrode plate to provide a reactant flow field that is perpendicular to a stack direction of the fuel cell, which plurality of reactant channels are configured to be in direct fluid communication with an oxidant source or a fuel source of the fuel cell, and a plurality of coolant channels formed on the other one of the opposing sides of the electrode plate that extend only partially through the thickness of the electrode plate to provide a coolant flow field that is perpendicular to the stack direction of the fuel cell. 12. A fuel cell component comprising: an electrode plate including a pair of opposing surfaces, a first one of the pair of opposing surfaces mating with a first gas diffusion layer of an electrode assembly wherein the first gas diffusion layer is separate and distinct from the electrode plate and the electrode assembly includes a proton exchange membrane between the first gas diffusion layer and a second gas diffusion layer opposite the first gas diffusion layer, the electrode plate having a porous internal structure with a first porosity and a non-porous exterior structure having a second porosity less than the first porosity, the non-porous exterior structure including the opposing surfaces, and wherein the non-porous exterior structure includes a seal recess that forms a perimeter around the electrode plate to receive an interfacial seal, the seal recess formed relative to a planar face of one of the pair of opposing surfaces of the electrode plate, and wherein the electrode plate is one of an anode porous plate and a cathode porous plate and includes a plurality of reactant channels formed in one of the pair of opposing surfaces of the electrode plate that extend only partially through a thickness of the electrode plate to provide a reactant flow field, the plurality of reactant channels form through the non-porous exterior structure on the one of the pair of opposing surfaces to expose the porous internal structure of the electrode plate, which reactant channels are configured to be in direct fluid communication with an oxidant source or a fuel source. 13. The fuel cell component of claim 12 wherein the plurality of reactant channels are formed relative to the planar face. 14. The fuel cell component of claim 12 wherein the plurality of reactant channels are substantially parallel to the seal recess. 15. The fuel cell component of claim 12 wherein the electrode plate includes an internal manifold extending through a portion of the seal recess. 16. The fuel cell component of claim 12 further comprising a coolant plate adjacent a second one of the pair of opposing surfaces and having a plurality of coolant channels extending through a thickness of the coolant plate. 17. A fuel cell component comprising: an electrode plate including opposing surfaces, one of the opposing surfaces mating with a gas diffusion layer of an electrode assembly wherein the gas diffusion layer is separate and distinct from the electrode plate, the electrode plate having a porous internal structure with a first porosity and a non-porous exterior structure having a second porosity less than the first porosity, the non-porous exterior structure including the opposing surfaces, and wherein the electrode plate includes a plurality of reactant channels formed through the non-porous exterior structure on one of the opposing surfaces to expose the porous internal structure of the electrode plate and to provide a reactant flow field, which reactant channels are configured to be in fluid communication with an oxidant source or a fuel source. 18. The fuel cell component of claim 17 wherein the non-porous exterior structure surrounds the porous internal structure. 19. The