The ozone formation reactivity of ethanol has been studied using chamber experiments and model simulations. The computer simulations are based on the MCM v3.1 mechanism with chamber-dependent auxiliary reactions. Results show that the MCM mechanism can well simulate C 2 H 5 OH-NO x chamber experiments in our experimental conditions, especially on ozone formation. C 2 H 5 OH-NO x irradiations are less sensitive to relative humidity than alkane species under our experimental conditions. In order to well simulate the experiments under high relative humidity conditions, inclusion of N 2 O 5 +H 2 O=2HNO 3 in the MCM mechanism is necessary. Under C 2 H 5 OH-limited conditions, the C 2 H 5 OH/NO x ratio shows a positive effect on d(O 3 -NO)/dt and RO 2 +HO 2 . High C 2 H 5 OH/NO x ratios enhance the production of organoperoxide radical and HO 2 radical concentrations, which leads to a much quicker accumulation of ozone. By using ozone isopleths under typical scenarios conditions, the actual ozone formation ability of ethanol is predicted to be 2.3-3.5 part per billion (ppb) in normal cities, 3.5-146 ppb in cities where ethanol gas are widely used, and 0.2-3.2 ppb in remote areas. And maximum ozone formation potential from ethanol is predicted to be 4.0-5.8 ppb in normal cities, 5.8-305 ppb in cities using ethanol gas, and 0.2-3.8 ppb in remote areas. The ozone formation reactivity of ethanol has been studied using chamber experiments and model simulations. The computer simulations are based on the MCM v3.1 mechanism with chamber-dependent auxiliary reactions. Results show that the MCM mechanism can well simulate C2H5OH- NO x chamber experiments in our experimental conditions, especially on ozone formation. C 2 H 5 OH-NO x irradiations are less sensitive to relative humidity than alkane species under our experimental conditions. In order to well simulate the experiments under high relative humidity conditions, The inclusion of N 2 O 5 + H 2 O = 2HNO 3 in the MCM mechanism is necessary. Under C 2 H 5 OH-limited conditions, the C 2 H 5 OH / NO x ratio shows a positive effect on d (O 3 - NO) / dt and RO 2 + HO 2. High C 2 H 5 OH / NO x ratios enhance the production of organoperoxide radical and HO 2 radical concentrations, which leads to a much quicker accumulation of ozone. By ozone isopleths under 10 conditions, the actual o zone formation ability of ethanol is predicted to be 2.3-3.5 part per billion (ppb) in normal cities, 3.5-146 ppb in cities where ethanol gas are widely used, and 0.2-3.2 ppb in remote areas. ethanol is predicted to be 4.0-5.8 ppb in normal cities, 5.8-305 ppb in cities using ethanol gas, and 0.2-3.8 ppb in remote areas.