Three-dimensional ion transport networks and current collectors for electrochemical cells

We claim: 1. An electrode comprising: a. a plurality of layers of a first type comprising an active material, wherein at least two of said layers of the first type include a plurality of ion-conducting conduits, each ion-conducting conduit having a longitudinal axis and being filled with an electrolyte or an electrolyte in a porous carrier material; wherein each of the layers of the first type is provided along a layer alignment axis that is substantially parallel to each other layer alignment axis; and b. at least one layer of a second type comprising additional electrolyte wherein each layer of the first type is separated from each adjacent layer of the first type by at least one layer of the second type; wherein the plurality of layers of the first type and the at least one layer of the second type are substantially parallel to each other; wherein said ion-conducting conduits are in ionic communication with at least one layer of the second type. 2. The electrode of claim 1 , wherein each of said layers of the first type includes a plurality of ion-conducting conduits and said ion-conducting conduits are positioned so that the longitudinal axis of each ion-conducting conduit is aligned with at least one ion-conducting conduit in an adjacent layer. 3. The electrode of claim 1 , wherein each of said layers of the first type includes an array of ion-conducting conduits, the longitudinal axis of each ion conducting conduit of an individual layer of the first type is aligned with the longitudinal axis of an ion-conducting conduit of each of all the other layers of the first type and the longitudinal axes of said ion conducting conduits define an alignment axis. 4. The electrode of claim 1 , wherein each of said layers of the first type further includes an aperture, each of said layers of the second type includes an aperture, said apertures are aligned to form a passage through the layers of the first type and the layers of the second type, an electronically conductive material is located within said passage and the electrode further comprises a current collector in electronic communication with said electronically conductive material. 5. The electrode of claim 4 , wherein said passage has a longitudinal axis, said longitudinal axis being substantially perpendicular to each of said layer alignment axes of said plurality of layers of the first type. 6. The electrode of claim 1 , wherein, the layers of said first type are characterized by a porosity of 20% to 40%. 7. The electrode of claim 1 , wherein the porous carrier material has the same composition of the layers of active material and is characterized by a porosity larger than the porosity of the layers of active material. 8. The electrode of claim 1 , wherein the porous carrier material is characterized by a porosity equal to or greater than 50%. 9. An electrochemical cell comprising: a. a first electrode according to claim 1 ; b. a second electrode; and c. an ionically conducting and electronically insulating separator layer disposed between the first and the second electrode. 10. The electrode of claim 1 , wherein said longitudinal axis of each of said ion-conducting conduit is substantially perpendicular to each of said layer alignment axes. 11. The electrode of claim 1 , wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each other of the layers of the first type to within 25 degrees; and wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each of the at least one layer of the second type to within 25 degrees. 12. The electrode of claim 1 , wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each other of the layers of the first type to within 10 degrees; and wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each of the at least one layer of the second type to within 10 degrees. 13. An electrode comprising: a. a plurality of layers of a first type comprising an active material, wherein at least two of said layers of a first type include a plurality of ion-conducting conduits, each ion-conducting conduit having a longitudinal axis and being filled with an electrolyte or an electrolyte in a porous carrier material; wherein each of the layers of the first type is provided along a layer alignment axis that is substantially parallel to each other layer alignment axis; b. at least one layer of a second type comprising additional electrolyte; wherein the plurality of layers of the first type and the at least one layer of the second type are substantially parallel to each other; and c. at least one layer of a third type comprising a current collector, wherein the current collector is perforated, a mesh or porous wherein each layer of a first type is separated from each adjacent layer of a first type by at least one layer of a second type or at least one layer of a third type and wherein said ion-conducting conduits are in ionic communication at least one layer of a second type. 14. The electrode of claim 13 , wherein each of said layers of a first type includes a plurality of ion-conducting conduits and said ion conducting conduits are positioned so that the longitudinal axis of each ion conducting conduit is aligned with at least one ion conducting conduit in an adjacent layer. 15. The electrode of claim 13 , wherein each of said layers of a first type includes an array of ion-conducting conduits and the longitudinal axis of each ion-conducting conduit of an individual layer of a first type is aligned with an ion-conducting conduit of each of all the other layers of a first type. 16. The electrode of claim 13 , wherein each of said layers of the first type further includes an aperture, each of said layers of the second type includes an aperture and each of the layers of the third type include an aperture, said apertures are aligned to form a passage through the layers of the first type, the second type and the third type, an electronically conductive material is located within said passage and said electronically conductive material is in electronic communication with said at least one layer of a third type. 17. The electrode of claim 16 , wherein said passage has a longitudinal axis, said longitudinal axis being substantially perpendicular to each of said layer alignment axes of said plurality of layers of the first type. 18. The electrode of claim 13 , wherein said longitudinal axis of each of said ion-conducting conduit is substantially perpendicular to each of said layer alignment axes. 19. The electrode of claim 13 , wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each other of the layers of the first type to within 25 degrees; and wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each of the at least one layer of the second type to within 25 degrees. 20. The electrode of claim 13 , wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each other of the layers of the first type to within 10 degrees; and wherein a normal to a surface of each of the layers of the first type is parallel to a normal of a surface of each of the at least one layer of the second type to within 10 degrees.