Electrochemical cell with adjacent cathodes

What is claimed is: 1. An electrochemical cell comprising: a first cathode, wherein the first cathode includes a first current collector having first and second sides and a first cathode form of active material covering the first and second sides of the first current collector; a second cathode, wherein the second cathode includes a second current collector having first and second sides and a second cathode form of active material covering the first and second sides of the second current collector, wherein the first and second current collectors are each a single layer metallic plate or metallic foil, and wherein the first and second cathodes are adjacent one another in a stacked arrangement to form a cathode stack in the electrochemical cell; an anode adjacent to the cathode stack; and a separator surrounding all sides of the cathode stack, allowing for an electrical connection between the first and second cathode current collectors. 2. The electrochemical cell of claim 1 , wherein the anode is a first anode and the separator is a first separator, the electrochemical cell further comprising: a second anode adjacent to the cathode stack and opposite the first anode relative to the cathode stack. 3. The electrochemical cell of claim 2 , wherein the cathode stack further includes a third cathode such that the third cathode is adjacent the second cathode in the cathode stack, wherein the third current collector is a single layer metallic plate or metallic foil, and wherein the third cathode includes a third current collector and a third cathode form of active material covering the third current collector, wherein the third current collector is electrically connected with the first and second current collector, and wherein the separator surrounds all sides of the cathode stack, allowing for an electrical connection between the first, second and third cathode current collectors. 4. The electrochemical cell of claim 1 , wherein the first cathode has a different active material than the second cathode such that the second cathode has a higher energy density than the first cathode. 5. The electrochemical cell of claim 1 , wherein the second cathode is thicker than the first cathode as measured in a direction about parallel to the thickness of the cathode stack such that the second cathode has a higher energy density than the first cathode. 6. The electrochemical cell of claim 1 , wherein the first cathode is similar to the second cathode. 7. The electrochemical cell of claim 1 , wherein the first cathode includes a first electrically conductive tab extending from the first current collector, wherein the second cathode includes a second electrically conductive tab extending from the second current collector, wherein the first electrically conductive tab is electrically connected with the second electrically conductive tab. 8. A battery comprising a first cathode, wherein the first cathode includes a first current collector having first and second sides and a first cathode form of active material covering the first and second sides of the first current collector; a second cathode, wherein the second cathode includes a second current collector having first and second sides and a second cathode form of active material covering the first and seconds sides of the second current collector, wherein the first and second current collectors are each a single layer metallic plate or metallic foil, and wherein the first and second cathodes are adjacent one another in a stacked arrangement to form a cathode stack in the battery; an anode adjacent to the cathode stack; a separator surrounding all sides of the cathode stack, allowing for an electrical connection between the first and second cathode current collectors; electrolyte; and a battery housing that holds the cathode stack, the anode, the separator, and the electrolyte. 9. The battery of claim 8 , wherein the anode is a first anode and the separator is a first separator, the battery further comprising: a second anode adjacent to the cathode stack and opposite the first anode relative to the cathode stack. 10. The battery of claim 9 , wherein the first cathode is adjacent to the first anode, wherein the second cathode is adjacent to the second anode, wherein the first anode is longer than the second anode as measured in a direction about perpendicular to the thickness of the cathode stack, wherein the first cathode is longer than the second cathode as measured in the direction about perpendicular to the thickness of the cathode stack, wherein a thickness of the battery housing as measured in the direction about perpendicular to the thickness of the cathode stack varies to conform to the different lengths of the first anode and the second anode and the different lengths of the first cathode and the second cathode. 11. The battery of claim 8 , wherein the first cathode has a substantially different active material than the second cathode such that the second cathode has a higher energy density than the first cathode. 12. The battery of claim 8 , wherein the second cathode is thicker than the first cathode as measured in a direction about parallel to the thickness of the cathode stack such that the second cathode has a higher energy density than the first cathode. 13. The battery of claim 8 , wherein the first cathode is similar to the second cathode. 14. A method of manufacture comprising: positioning a first cathode and a second cathode adjacent one another in a stacked arrangement to form a cathode stack, wherein the first cathode includes a first current collector having first and second sides and a first cathode form of active material covering the first and second sides of the first current collector, wherein the second cathode includes a second current collector having first and second sides and a second cathode form of active material covering the first and second sides of the second current collector wherein the first and second current collectors are each a single layer metallic plate or metallic foil; surrounding all sides of the cathode stack with a separator, allowing for an electrical connection between the first and second cathode current collectors, forming a separator-encapsulated cathode stack; positioning an anode adjacent to the separator-encapsulated cathode stack; and electrically connecting the first current collector and the second current collector. 15. The method of claim 14 , further comprising: locating, the anode and the separator-encapsulated cathode stack within a battery housing with the anode adjacent to the cathode stack; and filling the battery housing with electrolyte. 16. The method of claim 15 , further comprising electrically connecting the first current collector and the second current collector to a feedthrough pin that extends through the battery housing to form a positive battery terminal. 17. The method of claim 16 , wherein the battery housing is electrically connected to the anode such that the battery housing serves as a negative battery terminal. 18. An implantable medical device comprising: a hermetically sealed housing; and a battery disposed within the housing for powering the implantable medical device, the battery comprising: a first cathode, wherein the first cathode includes a first current collector having first and second sides and a first cathode form of active material covering the first and seconds sides of the first current collector; a second cathode, wherein the second cathode includes a second current collector