Nerve and blister agents are among the deadliest chemicals posing a major threat to the society, and the development of materials that can rapidly decontaminate them under solvent-free ambient conditions is a major societal challenge. In this paper, layered double hydroxides (ZnAlxZr1−x-LDH) with varying Zr4+ doping content were synthesized and the decontamination properties of nerve and blister agents were investigated under ambient conditions. The results show that, compared to ZnAl-LDH, the ZnAl0.4Zr0.6-LDH with the highest amount of Zr4+ dopant reduced the decontamination reaction half-life of sarin (GB) and soman (GD) by 10 and 9 times, respectively. Mechanism studies revealed that ZnAl0.4Zr0.6-LDH employs the synergistic effect of Lewis acid-base sites to catalyze the decomposition of GB and GD into hydrolysis products and surface-bound hydrolysis products. The study also showed that under ambient conditions, ZnAl0.4Zr0.6-LDH demonstrated superior decontamination performance for the sulfur mustard (HD) simulant 2-chloroethyl ethyl sulfide (CEES) compared to ZnAl-LDH, effectively catalyzing the detoxification of CEES into dehydrohalogenation (EVS) and 1,2-bis-(ethylthio) ethane (BETE). ZnAl0.4Zr0.6-LDH also had satisfactory decontamination performance against HD. This work provides not only a green and efficient catalyst with potential for practical applications but also new insights for constructing broad-spectrum, highly efficient self-detoxifying materials.
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