Electrochemical layer deposition

1 . (canceled) 2 . (canceled) 3 . The apparatus of claim 21 , wherein each of the plurality of anodes has an exposed surface having a geometric shape chosen from the group consisting of a hexagon, a rectangle, a triangle, a square, or a circle. 4 . (canceled) 5 . The apparatus of claim 21 , wherein the anode array is connected electrically to, or disposed upon an integrated circuit, semiconductor, or combination of conductive and insulative elements meant for biasing the plurality of anodes. 6 . (canceled) 7 . (canceled) 8 . (canceled) 9 . The apparatus of claim 21 , wherein each of the plurality of anodes is constructed out of a material resistant to physical depletion through electrolysis. 10 . (canceled) 11 . (canceled) 12 . (canceled) 13 . (canceled) 14 . (canceled) 15 . The method of claim 26 , wherein the unitary layer to be deposited on the cathode includes depositing at least one material selected from group consisting of gold, silver, zinc, Zn/Fe/Co/Ni alloys, copper, nickel, tin, iron, stainless steel, aluminum, titanium, polypyrrole, silicon, tungsten carbide MMC, PMC, BNNT Reinforced 316L, and SWCNT/Cu matrix. 16 . (canceled) 17 . The method of claim 26 , wherein the electrical current applied to the anode array is maintained between 0.1 A/dm 2 and 1200 A/dm 2 . 18 . (canceled) 19 . (canceled) 20 . (canceled) 21 . An apparatus comprising: (a) an anode array containing a plurality of independently electrically controllable anodes stationary with respect to one another and the plurality of anodes arranged in a two-dimensional array, the anode array configured to be immersed in an electrolyte solution such that each of the plurality of anodes is in fluid contact with the other anodes in the plurality of anodes through the electrolyte solution; (b) a cathode configured to be disposed in the electrolyte solution such that the cathode is in fluid contact with the plurality of anodes through the electrolyte solution; (c) an anode addressing circuit for receiving a signal containing anode address data and for outputting a signal causing an anode array pattern; (d) at least one sensor for individually measuring an electrical power of one of the plurality of anodes; and, (e) a controller configured to be in communication with the addressing circuit, the at least one sensor and the anode array, the controller further configured to electrically control each one of the plurality of anodes in the anode array thereby causing an electrochemical reaction at the cathode to deposit a unitary layer corresponding to the anode array pattern signal received from the addressing circuit. 22 . The apparatus of claim 21 , further comprising a timer for measuring an amount of time that a current flows between at least one of the plurality of anodes and the cathode. 23 . The apparatus of claim 21 , further comprising a system for positioning either the anode array, the cathode, or both, to control a distance between the anode array and the cathode. 24 . The apparatus of claim 23 , wherein the system for positioning is an electro-mechanically controlled system. 25 . The apparatus of claim 21 , wherein the plurality of anodes is arranged in rows in the two-dimensional array. 26 . A method comprising: (a) immersing an anode array and a cathode in an electrolyte solution such that the anode array and the cathode are in fluid contact with each other through the electrolyte solution; (b) in response to an anode array pattern signal based upon layer slice information about a single layer, electrically controlling each anode of a plurality of anodes in the anode array to fabricate the single layer; (c) causing an electrochemical reaction at the cathode that deposits a unitary layer in response to the anode array pattern signal; and, (d) using at least one sensor, individually monitoring an electrical power of each of the plurality of anodes to detect when a deposited layer reaches a target layer thickness at each of the plurality of anodes to cause the deposition of a unitary layer. 27 . The method of claim 26 , further comprising, measuring an amount of time during which an electrodeposition current flows between at least one of the plurality of anodes and the cathode. 28 . The method of claim 26 , further comprising adjusting a position of either the anode array, the cathode, or both, to control a distance between the anode array and the cathode. 29 . The method of claim 28 , where the adjusting is performed by an electro-mechanically controlled system.