Although a semiconductor gas sensor is promising in the future gas sensing technology, the material design for highly sensitive and selective gas sensing is quite challenging. The crystal plane dependence of gas sensing has been studied using various nano-crystal samples with a controlled crystal facet to obtain a clue for designing the sensing material, but the contact effect between nano-crystal particles has often hindered the straightforward analysis. In the present study, the crystal plane dependence of ethanol (EtOH) sensing by ZnO, one of the most widely studied target gas - sensing material combinations, was investigated from an analytical approach. We applied a newly developed low-energy He⁺ ion scattering spectroscopy (He⁺ LEIS) combined with the pulsed jet technique for analyzing the surface structure of ZnO during the EtOH sensing.