The friction behavior of single silicon wafer sliding against different ice counterparts
(α-Al2O3, CeO2 and SiO2) at 10±0.5 °C within a velocity of 60 rpm~300 rpm were studied using a
home-made friction and wear testing machine. The morphologies and surfaces roughness of the worn
silicon wafers were observed and examined on a non-contact surface topography instrument (ADE). It
was found that the friction coefficient of the single silicon wafer decreased with the increase of sliding
velocity. Single crystal silicon wafer coupled with α-Al2O3 ice counterpart recorded the highest
friction coefficient and the biggest surface roughness, while it had the lowest friction coefficient and
the smallest surface roughness as with CeO2 ice counterpart. One reason was that a series of
tribochemical reactions occurred at the local contact point between the ice counterpart and the silicon
wafer during sliding. Under alkaline condition, there would be a soft corrosion layer formed on the
surface of the silicon wafer. Another reason was that the hardness of the abrasive particles was
different and this caused different cutting depth of them.