Membrane electrode and frame assembly for fuel cell stacks and method for making

What is claimed is: 1. A membrane electrode and frame assembly for a solid polymer electrolyte fuel cell stack comprising: a catalyst coated membrane assembly comprising an anode catalyst layer, a cathode catalyst layer, and a solid polymer membrane electrolyte wherein the anode and cathode catalyst layers are bonded to opposite sides of the solid polymer membrane electrolyte; an anode gas diffusion layer adjacent to the anode catalyst layer of the catalyst coated membrane assembly; a cathode gas diffusion layer adjacent to the cathode catalyst layer of the catalyst coated membrane assembly; a frame; and an adhesive layer that is dimensionally flat; wherein outer perimeters of the catalyst coated membrane, the cathode gas diffusion layer and the adhesive layer are coterminous; wherein: the outer perimeter of the frame extends beyond the outer perimeters of the catalyst coated membrane assembly and the gas diffusion layers; the frame and the adhesive layer are located between the catalyst coated membrane assembly and one of the gas diffusion layers such that the adhesive layer is located adjacent to the catalyst coated membrane assembly and the frame is located adjacent to the one of the gas diffusion layers; the outer perimeter of the other of the gas diffusion layers extends beyond the outer perimeter of the catalyst coated portion of the catalyst coated membrane assembly; the inner perimeter of the adhesive layer extends beyond the inner perimeter of the frame; the outer perimeter of the adhesive layer extends beyond the outer perimeter of the catalyst coated portion of the catalyst coated membrane assembly, wherein the adhesive layer bonds the one of the gas diffusion layers to the catalyst coated membrane assembly, bonds the catalyst coated portion of the catalyst coated membrane assembly to the frame, and bonds either: the other of the gas diffusion layers to the frame, or an uncoated portion of the catalyst coated membrane assembly to the frame. 2. The membrane electrode and frame assembly of claim 1 wherein the one of the gas diffusion layers is the anode gas diffusion layer. 3. The membrane electrode and frame assembly of claim 1 , wherein the anode and cathode gas diffusion layers comprise carbon fibre paper. 4. The membrane electrode and frame assembly of claim 1 , wherein the frame is a polyethylene naphthalate film. 5. The membrane electrode and frame assembly of claim 1 wherein the frame comprises ports for the fluids to be supplied to and the fluids to be removed from the fuel cell stack. 6. The membrane electrode and frame assembly of claim 1 , wherein the adhesive layer comprises a polymer selected from the group consisting of epoxies, urethanes, polyisobutylene, and polyolefins. 7. The membrane electrode and frame assembly of claim 6 wherein the adhesive layer comprises polyethylene and curable cross-linking agents. 8. The membrane electrode and frame assembly of claim 1 , wherein the adhesive layer bonds the other of the gas diffusion layers to the frame. 9. The membrane electrode and frame assembly of claim 1 , wherein the adhesive layer bonds an uncoated portion of the catalyst coated membrane assembly to the frame. 10. The membrane electrode and frame assembly of claim 9 wherein the other of the gas diffusion layers is bonded to an uncoated portion of the catalyst coated membrane assembly. 11. A solid polymer electrolyte fuel cell stack comprising a series stack of a plurality of the membrane electrode and frame assemblies of claim 1 . 12. A method of manufacturing the membrane electrode and frame assembly of claim 1 comprising: obtaining the catalyst coated membrane assembly; obtaining the anode and cathode gas diffusion layers; obtaining the frame and the adhesive layer; stacking the catalyst coated membrane assembly, the anode and cathode gas diffusion layers, the frame, and the adhesive layer such that the frame and the adhesive layer are located between the catalyst coated membrane assembly and one of the gas diffusion layers and such that the adhesive layer is located adjacent to the catalyst coated membrane assembly and the frame is located adjacent to the one of the gas diffusion layers; aligning the catalyst coated membrane assembly, the anode and cathode gas diffusion layers, the frame, and the adhesive layer such that the outer perimeter of the frame extends beyond the outer perimeters of the catalyst coated membrane assembly and the gas diffusion layers, the outer perimeter of the other of the gas diffusion layers extends beyond the outer perimeter of the catalyst coated portion of the catalyst coated membrane assembly, the inner perimeter of the adhesive layer extends beyond the inner perimeter of the frame, and the outer perimeter of the adhesive layer extends beyond the outer perimeter of the catalyst coated portion of the catalyst coated membrane assembly; and activating the adhesive layer such that the adhesive layer bonds the one of the gas diffusion layers to the catalyst coated membrane assembly, bonds the catalyst coated portion of the catalyst coated membrane assembly to the frame, and bonds either: the other of the gas diffusion layers to the frame, or an uncoated portion of the catalyst coated membrane assembly to the frame. 13. The method of claim 12 wherein the one of the gas diffusion layers is the anode gas diffusion layer. 14. The method of claim 12 , wherein the adhesive layer is obtained on a backing layer and the method comprises: removing the backing layer after stacking and aligning the adhesive layer and before activating the adhesive layer. 15. The method of claim 12 comprising: bonding the catalyst coated membrane to the other of the gas diffusion layers before the stacking step; and cutting the outer edge of the bonded catalyst coated membrane and the other of the gas diffusion layers such that the outer perimeters of the catalyst coated membrane and the other of the gas diffusion layers are coterminous.