Fuel cell stack with improved end cell performance provided by higher modulus of elasticity

What is claimed is: 1. A fuel cell stack comprising: a plurality of fuel cells including at least one end cell at each end of the fuel cell stack; a plurality of flow field plates separating the fuel cells in the fuel cell stack, said flow field plates including flow channels; and a plurality of diffusion media layers positioned adjacent to the flow field plates in the fuel cells, wherein diffusion media material of the diffusion media layers is selected so that the diffusion media material has a lower intrusion into the flow channels of the flow field plates in the at least one end cell at each end of the fuel cell stack than the intrusion into the flow channels of the flow field plates in fuel cells other than the at least one end cell at each end of the fuel cell stack, and wherein the diffusion media material of the diffusion media layers in the at least one end cell at each end of the fuel cell stack has a higher modulus of elasticity than a diffusion media material of the diffusion media layers in the fuel cells other than the at least one end cell at each end of the fuel cell stack; and wherein the diffusion media material of the diffusion media layers in the at least one end cell at each end of the fuel cell stack is different than the diffusion media material of the diffusion media layers in the fuel cells other than the at least one and cell at each end of the fuel cell stack. 2. The fuel cell stack according to claim 1 wherein the at least one end cell is five or less end cells at each end of the stack. 3. The fuel cell stack according to claim 1 wherein the diffusion media layers in the at least one end cell at each end of the fuel cell stack are thinner than the diffusion media layers in the fuel cells other than the at least one end cell at each end of the fuel cell stack. 4. A fuel cell stack comprising a plurality of diffusion media layers positioned adjacent to flow field plates between fuel cells in the stack, wherein diffusion media material of the diffusion media layers is selected so that the diffusion media material has a lower intrusion into the flow channels in the flow field plates in end cells of the fuel cell stack than the intrusion of the diffusion media material into the flow channels of the flow field plates of fuel cells other than the end cells, and wherein the diffusion media material of the diffusion media layers in the end cells has a higher modulus of elasticity than a diffusion media material of the diffusion media layers in the fuel cells other than the end cells; and wherein the diffusion media material of the diffusion media layers in the end cells is different than the diffusion media material of the diffusion media layers in the fuel cells other than the end cells. 5. The fuel cell stack according to claim 4 wherein the number of end cells is five or less end cells at each end of the stack. 6. A method for increasing the stability of end cells in the fuel cell stack of claim 1 comprising selecting the diffusion media for fuel cells in the fuel cell stack so that the intrusion of the diffusion media into flow channels in end cells is less than the intrusion of the diffusion media into flow channels of other fuel cells, wherein the diffusion media in the end cells has a higher modulus of elasticity than the diffusion media in the cells other than the end cells. 7. The method according to claim 6 wherein the diffusion media in the end cells is different than the diffusion media in the cells other than the end cells. 8. The method according to claim 6 wherein the diffusion media in the end cells is thinner than the diffusion media in the cells other than the end cells.