Our research has investigated the use of CF<sub>3</sub>I, which has lower Global Warming Potential (GWP), as a substitute gas for SF<sub>6</sub>. The use of pure CF<sub>3</sub>I in gas insulated switchgear (GIS) and gas circuit breakers (GCB) is difficult because liquid CF3I has a high boiling point. We have therefore mixed CF<sub>3</sub>I with CO<sub>2</sub> or N<sub>2</sub>. By investigating the decomposed gas after a current interruption, we have shown that the iodine density from CF<sub>3</sub>I-CO<sub>2</sub>(30%-70%) is about 1/3 of that of pure CF<sub>3</sub>I. In addition, no fluorine was detected from the gas mixture. Our investigation of the breakdown voltage characteristics has shown that the dielectric strength of CF<sub>3</sub>I-CO<sub>2</sub> (30%-70%) is about 0.75 to 0.80 times that of SF<sub>6</sub>. In breaker terminal fault (BTF) and short line fault (SLF) interruption, CF<sub>3</sub>I-CO<sub>2</sub> is superior to CF<sub>3</sub>I-N<sub>2</sub>. Because of the high boiling point of CF<sub>3</sub>I, the proportion of CF<sub>3</sub>I should be small. In BTF interruption, the performance approximates to that of pure CF<sub>3</sub>I when the proportion of CF<sub>3</sub>I exceeds 30%. Similarly, the SLF interruption performance approximates to that of pure CF<sub>3</sub>I when the proportion of CF<sub>3</sub>I exceeds 20%.