Until now, reactions between methane photolysis products (CH 3 • , CH 2 ) and active N atom or reactive NO radical are proposed as routes of HCN formation in the prebiotic Earth. Scientists think that the reducing atmosphere of primitive Earth was made of H 2 , He, N 2 , NO, CH 4 , H 2 O, CO 2 , etc., and there was no molecular oxygen. However, it has been evident from experiments that the vacuum ultraviolet (VUV) photolysis of CO 2 can produce atomic oxygen. Therefore, it can be presumed that atomic oxygen was likely present in early Earth's atmosphere. Was there any impact of atomic oxygen in production of early atmospheric HCN for the emergence of life? To hunt for the answer, we have employed computational methods to study the mechanism and kinetics of CH 3 NO + O( 1 D) and CH 2 NO • + O( 3 P) addition reactions. Current study suggests that the addition of O( 1 D) into nitrosomethane (CH 3 NO) and the addition of O( 3 P) into nitrosomethylene radical (CH 2 NO • ) can efficiently produce HCN through an effectively barrierless pathway. At STP, Bartis−Widom phenomenological loss rate coefficients of O( 1 D) and O( 3 P) are obtained as 2.47 × 10 −12 and 4.67 × 10 −11 cm 3 molecule −1 s −1 , respectively. We propose that addition reactions of atomic oxygen with CH 3 NO and CH 2 NO • might act as a potential source for early atmospheric HCN.