Micrometer copper columns (roughly 50 μm in diameter) were fabricated by a patented process named as micro anode guided electroplating (MAGE). In this process, a micro anode (made of Pt wire 125μm in diameter) was controlled to depart from the cathode intermittently (1×1 cm^2 silicon coated with 1.8μm copper) under optimed biases to fabricate copper micro-columns in an acidic CuSO4 bath(CuSO4•5H2O 200 g/L，H2SO4 65 g/L and 35 g/L, HCl 1mL). The surface morphologies of the copper micro columns, examined by scanning electron microscopy (SEM), depended on the bias applied between the electrodes. The microcolumn obtained at a bias of 2.6 V, displayed uniform diameter and smooth surface. In contrast, the micro column fabricated at a bias of 3.2 V was coralline and displayed rough surface. The sem morphology of microcolumns was also influenced by the gap in each intermittent step. A short gap (e.g. 1 μm) led to nodose microcolumn with rough surface but a long gap (e.g. 40 μm) led to uniform microcolumn with smooth surface. In this work, practical range of bias was chosen from 2.6 to 3.2 V because the growth rate of the microcolumn was to slow under biases less than 2.6 V, and coralline microcolumn was not acceptable under biases greater than 3.2 V. In comparison with the microcolumns fabricated in various conditions, we obtained the optimal conditions to attain the qualified copper microcolumns.