Nanopillar structures are fabricated on nanoporous TiO2 by inductively coupled plasma (ICP) etching using silver-shrunk nanodot shadow masks. The dye-sensitized solar cell (DSSC) conversion efficiency is highly related to the etching time. Dye-sensitized solar cells are made with nanopillar nanoporous TiO2 photoanodes. Experiments are conducted in following conditions. (1) The shrunk silver nanodot shadow masks are retained on the surface of nanoporous TiO2 photoanodes after ICP etching. The reference sample conversion efficiency is 4.67% (without silver nanodot and ICP etching), and the cell efficiency rises to the highest efficiency of 5.25% after 1 minute dry etching with silver nanodot shadow masks. Then the efficiency reduces again when etching time exceeds 1 minute. (2) The silver nanodot shadow masks are removed by the HNO3:H2O=1:10 solution after the ICP etching process. The cell efficiency rises to 5.14% after 30 second ICP etching. Then the efficiency drops to 4.72% after 5 minutes of ICP etching. (3) The nanoporous TiO2 are directly treated using ICP plasma without silver sphere mask. The conversion efficiency is reduced monotonically from 4.67% (reference sample) to 3.62%(after etching 1 minute). From the experiments, the enhanced cell efficiency is due to the nanopillar structure instead of the plasma treatment. The nanopillar structure would increase the light scattering, thereby improving the photocurrent and the conversion efficiency. When the etching time is too long, the thickness of nanoporous TiO2 is reduced, leading to the decrease of total amount of absorbed dyes and the light being absorbed by the dyes, thereby reducing the cell photocurrent and efficiency.