Reversible CO 2 capture with applied external electric fields on solid adsorbents is a promising approach to reduce CO 2 emissions. However, the strengths of the applied electric fields are too high to be performed in practice. So, it is vital to develop new strategies to reduce the strengths of the electric fields. Through the investigation of CO 2 capture on N/P-doped MoS 2 on the density functional theory (DFT) level, we find that the strengths of the electric fields on N/P-doped MoS 2 can be reduced significantly compared with the system without doping. Moreover, the reversible CO 2 capture on them can be controlled by turning on/off the electric field, which is an exothermic reaction without an energy barrier. Especially for N-doped MoS 2 with a larger partial charge distribution difference, the required external electric field for efficient reversible CO 2 capture is 3–64% of the synthesized two-dimensional (2D) materials such as BN, C 2 N, C 3 N, MoS 2 , and N-doped pentagraphene. Additionally, the materials with an applied electric field can separate CO 2 from pre- and postcombustion gas mixtures (CO 2 , N 2 , CH 4 , and H 2 ). In all, the study provides useful insights that chemical doping on adsorbents is an effective strategy to reduce the required electric field for reversible CO 2 capture and gas separation.

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