In this article, we investigate the contact resistivity of p -type passivating contacts for silicon solar cells. Our contact structures are compatible with firing, a rapid annealing process similar to the one used for sintering of the screen-printed metallization in solar cell manufacturing. We find that the short firing process crystallizes the doped layers and incorporates active boron dopants up to the solubility concentration at the chosen firing temperature. The dependence of our contact resistivities on carrier density and temperature suggest that the hole transport is a combination of tunneling through the oxide at the wafer surface and of thermionic field emission over the Schottky barrier to the metallization. For ideal firing conditions, we find implied open-circuit voltages up to 720 mV and contact resistivities as low as 15 m·Ω·cm2.