Apparatus and method for forming a multilayer extrusion comprising component layers of an electrochemical cell

What is claimed is: 1 . A co-extrusion die configured to produce a multilayer extrusion comprising component layers of an electrochemical cell, the die comprising: a plurality of inlet ports configured to receive a plurality of pressurized fluids comprising at least a first metallic ink, a second metallic ink, and a polymeric ink; a plurality of channels configured to separately transport and shape the plurality of fluids from the plurality of inlet ports to a merge section, such that the plurality of fluids flow together in the merge section to form the multilayer extrusion comprising a polymeric membrane layer disposed between and in contact with a first metallic layer and a second metallic layer, wherein a thickness of each layer within the merge section is controllable by adjustment of a pressure of the plurality of pressurized fluids; and an outlet port fluidically coupled to the merge section, the outlet port configured to output the multilayer extrusion onto a substrate. 2 . The die of claim 1 , wherein: the multilayer extrusion defines layers of a membrane electrode assembly (MEA); the first and second metallic layers define first and second electrode layers of the MEA; and the substrate comprises a gas diffusion layer. 3 . The die of claim 2 , wherein: the plurality of inlets are configured to receive a first microporous layer ink and a second microporous layer ink; and the plurality of channels are configured to separately transport the plurality of fluids including the first microporous layer ink and the second microporous layer ink to the merge section, such that the plurality of fluids flow together in the merge section to form the multilayer extrusion comprising, in order, a first microporous layer, the first electrode layer, the polymeric membrane layer, the second electrode layer, and a second microporous layer. 4 . The die of claim 1 , wherein: the multilayer extrusion defines layers of a proton exchange membrane (PEM); and the first and second metallic layers are configured to have low hydrogen permeability sufficient to reduce an amount of hydrogen crossover at the polymeric membrane layer relative the PEM devoid of the first and second metallic layers. 5 . The die of claim 4 , wherein: the plurality of inlet ports are configured to receive a first electrode ink and a second electrode ink; and the plurality of channels are configured to separately transport the plurality of fluids including the first and second electrode inks from the plurality of inlet ports to the merge section, such that the plurality of fluids flow together in the merge section to form the multilayer extrusion comprising the PEM disposed between and in contact with the first and second metallic layers, a first electrode layer in contact with the first metallic layer, and a second electrode layer in contact with the second electrode layer. 6 . The die of claim 1 , wherein: the multilayer extrusion defines layers of a battery; the polymeric membrane defines a polymeric separator of the battery; the first and second metallic layers define first and second electrodes of the battery; and the substrate comprises a current collector. 7 . The die of claim 1 , wherein: the plurality of inlet ports are configured to receive a plurality of graded first metallic inks having different electrode material loading; and the plurality of channels are configured to separately transport the plurality of fluids including the plurality of graded first metallic inks to the merge section, such that the plurality of fluids flow together in the merge section to form the multilayer extrusion comprising the polymeric membrane layer disposed between a second electrode layer and a plurality of graded first electrode layers. 8 . The die of claim 7 , wherein the plurality of graded first electrode layers are situated relative to the polymeric membrane layer in an order based on electrode material loading, such that a graded first electrode layer with highest electrode material loading is closest to the polymeric membrane layer and a graded first electrode layer with lowest electrode material loading is furthest away from the polymeric membrane layer. 9 . The die of claim 8 , wherein the die comprises at least three inlet ports and at least three channels respectively configured to receive and transport at least three graded first metallic inks to the merge section. 10 . The die of claim 7 , wherein: the plurality of inlet ports are configured to receive a plurality of graded second metallic inks having different electrode material loading; and the plurality of channels are configured to separately transport the plurality of fluids including the plurality of graded second metallic inks to the merge section, such that the plurality of fluids flow together in the merge section to form the multilayer extrusion comprising the polymeric membrane layer disposed between a plurality of graded second electrode layers and the plurality of graded first electrode layers. 11 . The die of claim 10 , wherein the plurality of graded second electrode layers are situated relative to the polymeric membrane layer in an order based on electrode material loading, such that a graded second electrode layer with highest electrode material loading is closest to the polymeric membrane layer and a graded second electrode layer with lowest electrode material loading is furthest away from the polymeric membrane layer. 12 . The die of claim 11 , wherein the die comprises at least three inlet ports and at least three channels respectively configured to receive and transport at least three graded second metallic inks to the merge section. 13 . A co-extrusion die configured to produce a multilayer extrusion comprising layers of an electrochemical cell, the die comprising: a plurality of inlet ports configured to receive a plurality of pressurized fluids comprising at least a polymeric ink, a first microporous layer ink, a second microporous layer ink, a plurality of graded first electrode inks having different electrode material loading, and a plurality of graded second electrode inks having different electrode material loading; a plurality of channels configured to separately transport and shape the plurality of fluids from the plurality of inlet ports to a merge section, such that the plurality of fluids flow together in the merge section to form the multilayer extrusion comprising, in order, a first microporous layer, a plurality of graded first electrode layers, a polymeric membrane layer, a plurality of graded second electrode layers, and a second microporous layer, wherein a thickness of each layer within the merge section is controllable by adjustment of a pressure of the plurality of pressurized fluids; and an outlet port fluidically coupled to the merge section, the outlet port configured to output the multilayer extrusion onto a substrate. 14 . The die of claim 13 , wherein: the plurality of graded first electrode layers are situated relative to the polymeric membrane layer in an order based on electrode material loading, such that a graded first electrode layer with highest electrode material loading is closest to the polymeric membrane layer and a graded first electrode layer with lowest electrode material loading is furthest away from the polymeric membrane layer; and the plurality of graded second electrode layers are situated relative to the polymeric membrane layer in an order based on electrode material loading, such that a graded second electrode layer with highest electrode material loading is closest to the polymeric membrane layer and a gr