Silicon substrate consisting of nanoporous silicon film could enhance the thermoelectric performance of bulk silicon due to its low thermal conductivity. Metal-assisted chemical etching (MACE) is a wet method for fabricating diverse nano/micro structures, which uses a noble metal as the catalyst for etching of semiconductor material. In this study, we report the thermoelectrical properties of silicon substrates with nanopores in different porosities fabricated by MACE employing Ag nanoparticle as a metal catalyst. Different porosities of the nanoporous silicon layer were obtained by adjusting the deposition time of Ag nanoparticles. The lateral nanopores were found on the surface of vertical nanopores sidewall caused by Ag nanoparticles. With the increase of the porosity, the surface area of nanopores sidewall became rougher. In comparison of single-crystal silicon, silicon substrates with nanopores can enhance the thermoelectric figure of merit, ZT, due to the relativity high Seebeck coefficient and low thermal conductivity. However, lower electrical conductivity limits the enhancement of the ZT value. The porosity effect on the thermoelectrical properties of silicon substrates with nanopores was evaluated. Seebeck coefficient has a maximum value at the porosity of 38% and then decreases at the porosity of 49%, and the electrical conductivity and thermal conductivity decrease with the increase of porosity. At the porosity of 38%, the ZT value of silicon substrates with nanopores can reach to approximately 0.02, which is 7.3 times larger than that of the original high doped single-crystalline silicon. Thus the nanoporous silicon film fabricated by MACE can enhance the thermoelectric performance of the bulk silicon.