This work is an attempt to search for highly selective sensing materials for ethanol vapor. The electrical conductivity response of ZSM-5, Y, and mordenite zeolites towards ethanol vapor have been investigated for the effects of the framework, the charge balancing cation type, and the Si/Al ratio. All zeolites were characterized using XRD, FT-IR, SEM, TGA, BET, and NH 3 -TPD techniques. For the effect of the zeolite framework type, H + Y has a higher electrical conductivity sensitivity value than that of H + MOR because of a greater pore volume and available surface area. For the effect of the charge balancing cation, all NH 4 + ZSM-5 zeolites (Si/Al=23, 50, 80, 280) show negative responses, whereas the H + Y zeolites (Si/Al=30, 60, 80) and the H + MOR zeolites (Si/Al=30, 200) show positive responses. These differing behaviors can be traced to the electrostatic field at the cation sites in zeolite micropores, and their hydrophilic-hydrophobic character, which affect the adsorption properties of the zeolites. For the effect of Si/Al ratio, the electrical conductivity sensitivity towards the ethanol decreases with increasing Si/Al ratio or decreasing Al content, and there is a lesser degree of interaction between ethanol molecules and the active sites of the zeolites due to its higher hydrophobicity and the lower amount of cations. However, the H + Y (Si/Al=5.1) and the H + MOR (Si/Al=19) zeolites have lower conductivity sensitivity than those of H + Y (Si/Al=30) and H + MOR (Si/Al=30), respectively. The interactions between the C 2 H 5 OH molecules and the zeolites with respect to the electrical conductivity sensitivity were investigated and verified through infrared spectroscopy.