Systems and methods for uniformly heating a honeycomb body

What is claimed is: 1. An electrical heater, comprising: a honeycomb body comprising a plurality of intersecting walls that form a plurality of channels extending along a longitudinal axis, the intersecting walls comprising a conductive material; a plurality of electrically resistive paths, each resistive path of the plurality of resistive paths comprising at least a portion of the plurality of intersecting walls and extending a length across the honeycomb body transverse to the longitudinal axis; and at least one positive electrode and at least one negative electrode in electrical communication with each other via the plurality of resistive paths, the at least one positive electrode and the at least one negative electrode being operatively positioned to generate a respective flow of current through each resistive path; wherein the lengths of at least two of the resistive paths differ from each other; and wherein the resistive paths are configured with respect to the at least one positive electrode and the at least one negative electrode such that the current in each of the resistive paths is substantially equal. 2. The electrical heater of claim 1 , wherein the positive electrode and negative electrode are arranged such that the plurality of resistive paths are mutually electrically parallel, the total resistance of each path being substantially equal. 3. The electrical heater of claim 1 , wherein a width of each resistive path of the plurality of resistive paths is proportional to its length, such that a resistance of each resistive path of the plurality of resistive paths is substantially equal. 4. The electrical heater of claim 1 , wherein one or more of the insulating layers do not extend entirely across the honeycomb body. 5. The electrical heater of claim 4 , further comprising a plurality of conductors associated with the plurality of resistive paths, wherein at least one of the conductors is embedded in the honeycomb structure to promote current flow between each of the resistive paths and the positive electrode, the negative electrode, or both. 6. The electrical heater of claim 5 , wherein the conductors comprise one or more of the channels of the honeycomb body filled with conductive material. 7. The electrical heater of claim 1 , wherein the positive electrode and the negative electrode apply a respective voltage to each resistive path of the plurality of resistive paths, wherein a magnitude of the respective voltage is proportional to a total resistance of the resistive path to which the respective voltage is applied. 8. The electrical heater of claim 7 , wherein the positive electrode comprises a plurality of positive electrodes, each positive electrode of the plurality of positive electrodes being associated with at least one resistive path of the plurality of resistive paths and being configured to apply the respective voltage to the associated resistive path. 9. The electrical heater of claim 1 , wherein each insulating layer is formed by a slot in the honeycomb body. 10. The electrical heater of claim 1 , wherein the plurality of insulating layers are mutually parallel, each insulating layer extending in a respective plane parallel to central axis of the electrical heater. 11. A system for treating exhaust, comprising the electrical heater of claim 1 and an exhaust treatment device, wherein the honeycomb body of the electrical heater is a first honeycomb body and the exhaust treatment device comprises a second honeycomb body, and wherein the electrical heater is positioned upstream of the exhaust treatment device. 12. The system of claim 11 , wherein the first honeycomb body of the electrical heater has a wall thickness that is different than that of the second honeycomb body of the exhaust treatment device. 13. The system of claim 11 , wherein the first honeycomb body of the electric heater has a cells per square inch that is different than that of the second honeycomb body of the exhaust treatment device. 14. The electrical heater of claim 1 , wherein the honeycomb body comprises a plurality of separate blocks or segments of honeycomb structure, wherein each of the resistive paths is formed by one of the separate blocks or segments of honeycomb structure and the separate blocks or segments of honeycomb structure are separated from each other by the plurality of insulating layers. 15. A method for heating a catalyst with a heater comprising a honeycomb body comprising a plurality of intersecting walls and a longitudinal axis, the method comprising: applying a potential difference across an electrode pair comprising a positive electrode and a negative electrode to generate a respective flow of current through each resistive path of a plurality of resistive paths formed between the electrode pair across a cross-section of the honeycomb body of the heater; wherein the resistive paths of the plurality of resistive paths are separated from each other by one or more insulating layers; wherein lengths of at least two of the resistive paths of the plurality of resistive paths are different; and wherein the resistive paths are configured with respect to the electrode pair such that the current in each of the resistive paths is substantially similar. 16. The method of claim 15 , wherein the positive electrode and negative electrode are arranged such that the plurality of resistive paths are mutually electrically parallel, the total resistance of each path being substantially similar. 17. The method of claim 16 , wherein a width of each resistive path of the plurality of resistive paths is proportional to its length, such that a resistance of each resistive path of the plurality of resistive paths is substantially similar. 18. The method of claim 17 , wherein the honeycomb body further comprises an outer skin disposed about at least a portion of the honeycomb body, wherein at least a portion of the outer skin carries an electric charge received from the positive electrode, wherein the honeycomb body defines a first plurality of slots, each slot of the first plurality of slots being in electrical communication with a respective resistive path of the plurality of resistive paths and being in further electrical communication with the at least a portion of the outer skin, such that the electric charge is communicated to the respective resistive path of the plurality of resistive paths. 19. The method of claim 15 , wherein the step of applying a potential difference comprises applying a respective potential difference to each resistive path of the plurality of resistive paths, wherein a magnitude of the respective potential difference is proportional to a total resistance of the resistive path to which the respective potential difference is applied. 20. The method of claim 19 , wherein the positive electrode comprises a plurality of positive electrodes, each positive electrode of the plurality of positive electrodes being associated with at least one resistive path of the plurality of resistive paths and being configured to apply the respective potential difference to the associated resistive path.