Isopropanol (IPA) is widely used in different industries. With the development of industrial and high-tech industries, the problem of wastewater containing isopropanol (IPA) has become increasingly serious; moreover, acetone, which is produced during the oxidation process will also cause another environmental problem. The electrochemical oxidation technique has the advantages of efficiency, easy to operate, clean and has been successfully applied to treating a variety of organic pollutants. In this study, an electrochemical oxidation method is used to conduct a batch experiment of isopropanol oxidation with a self-made closed electrochemical reaction tank connected to a mass spectrometer. By analyzing products and intermediate products, the differences of the oxidation of isopropanol under chlorine (sodium chloride) and non-chlorine (sodium sulfate) systems are explored. Electrochemical parameters (electrolyte type. current intensity, chloride ion concentration and initial pH value) are also changed to study the effects of chlorine-containing species to the oxidation mechanism of isopropanol. The cyclic voltammetry curves showed that the oxidation current peak of isopropanol was 2 mA / cm2 in a chlorine-free system, which was about twice the chlorine-containing system, and the acetone produced by oxidation would continue to be oxidized on the electrode surface, in contrast, acetone oxidation peak was unobvious in chloride system. In the chloride-free system with 0.25 A, 500 ppm of isopropanol was oxidized to acetone and carbon dioxide after electrolysis and the removal rate reached to 100.0 %. Under the same electrochemical conditions, isopropanol was oxidized to formic acid and acetic acid in the chloride system, with a removal rate of 89.0 %. Batch experiments showed that in the chloride system, the removal efficiency of isopropanol was 93.5 %, 86.8 % and 82.9 % in 20 mM, 100 mM and 150 mM chloride ion concentration respectively. The increased chloride ion containing would increase the amount of organic acid. The removal efficiency of isopropanol was 87.7 %, 82.9 % and 85.3 % at the initial pH 5, pH 6.5 and pH 9 respectively. The lower the pH, the more organic acid content. According to the results, isopropanol has different oxidation mechanisms in the two major systems. When the electrolyte environment contains chloride ions, active chlorine species react with isopropanol in the solution and further oxidized acetone to an organic acid, therefore, the acetone concentration in the solution was no longer being increasing. In a chloride-free system, the hydroxyl radical is the main active specie, which oxidizes isopropanol to acetone and carbon dioxide. This study can establish information on the treatment of isopropanol-containing wastewater and oxidation products by electrochemical oxidation.