Method for manufacturing anodic metal oxide nanoporous templates

What is claimed is: 1. A method for manufacturing anodic metal-oxide nanoporous templates, the method comprising: simultaneously anodizing multiple surfaces of a metal specimen to form nanoporous anodic oxide layer on each surface by applying forward bias to the metal specimen; and simultaneously detaching the nanoporous anodic oxide layers from the metal specimen, wherein the detaching of the nanoporous anodic oxide layers from the metal specimen comprises applying a stair-like reverse bias to the metal specimen; wherein the anodizing and detaching steps are performed in the same acidic electrolyte; and wherein, when the forward bias is +25 V, the stair-like reverse bias is applied in three stairs of −15 V, −16 V and −17 V. 2. The method of claim 1 , wherein the simultaneous anodizing of the metal specimen comprises: simultaneously pre-anodizing the metal specimen by dipping more than one surface of the metal specimen in an acidic electrolyte and by applying a forward bias for anodization of the metal specimen; simultaneously main-etching the metal specimen to remove more than one of the pre-anodized oxide layers that are generated by the pre-anodizing; and simultaneously main-anodizing the metal specimen to form main-anodized oxide layers by dipping in an acidic electrolyte more than one surface of the metal specimen, which is textured through the main etching, and by reapplying a forward bias for anodization to the textured metal specimen. 3. The method of claim 2 , further comprising, after simultaneously detaching the main-anodized oxide layers from the metal specimen, sub-etching the metal specimen to simultaneously remove remaining residual oxide layers from more than one surface of the metal specimen. 4. The method of claim 3 , wherein the simultaneous pre-anodizing, the simultaneous main-etching, the simultaneous main-anodizing, the simultaneous detaching of the main-anodic oxide layer, and the simultaneous sub-etching are repeated at least two or more times. 5. The method of claim 1 , further comprising: before the simultaneous anodizing of the metal specimen, simultaneously electro-polishing more than one surface of the metal specimen. 6. A method for manufacturing anodic metal-oxide nanoporous templates, the method comprising: providing an aluminum specimen; simultaneously electro-polishing surfaces of the aluminum specimen in a solution containing perchloric acid and ethanol; simultaneously pre-anodizing the electro-polished aluminum specimen by dipping the electro-polished metal specimen in a sulfuric acid solution and applying a forward bias for anodization to the electro-polished aluminum specimen; simultaneously main-etching pre-anodic aluminum oxide (pre-AAO) layers, which are generated by the pre-anodizing, in a chromic acid solution; simultaneously main-anodizing the aluminum specimen to form main-AAO layers by dipping more than one surface of the aluminum specimen, which is textured through the main etching, in a sulfuric acid solution and reapplying a forward bias for anodization to the textured aluminum specimen; and applying a stair-like reverse bias to the aluminum specimen to simultaneously detach main-AAO layers, which are generated by the main anodizing, from the aluminum specimen; wherein the anodizing and detaching steps are performed in the same acidic electrolyte; and wherein, when the forward bias is +25 V, the stair-like reverse bias is applied in three stairs of −15 V, −16 V and −17 V. 7. The method of claim 6 , further comprising: after applying the reverse bias to the aluminum specimen, sub-etching the aluminum specimen to simultaneously remove remaining residual oxide layers from more than one surface of the metal specimen. 8. The method of claim 7 , wherein the steps from pre-anodizing through sub-etching are repeated at least two or more times. 9. The method of claim 1 , wherein −15 V is applied for 600 seconds, and −16 V is applied for 500 seconds. 10. The method of claim 6 , wherein −15 V is applied for 600 seconds, and −16 V is applied for 500 seconds.