Cooperative physisorption and chemisorption of hydrogen on vanadium-decorated benzene

3d TM-decorated carbon composites have been proved to be a new generation of hydrogen storage materials. However, detailed hydrogen storage mechanisms are still unclear. Investigation of the H(2) dissociation and H migration on the 3d TM-decorated six-membered carbocycles is very critical for better understanding the hydrogen storage mechanism. In this paper, the processes of chemisorption and physisorption of multiple H(2) molecules on synthesized VC(6)H(6) were simultaneously investigated for the first time. The Gibbs free energy calculations show that the optimal chemisorption pathway with the hydrogen storage capacity of 5.97 wt% is exothermic by 2.83 kcal mol(−1). Both the continuous hydrogenation giving the product of VC(6)H(11)–3H and reverse dehydrogenation could run smoothly at room temperature. The physisorption with a hydrogen storage capacity of 4.48 wt% will be exothermic by 13.49 kcal mol(−1). The H(2) molecules can be physisorbed at any temperature under 416 K and readily desorbed above 480 K at 1 atm. In summary, physisorption and chemisorption synergistically boost the hydrogen storage property of complex VC(6)H(6). Our study provides a comprehensive picture of the interaction between hydrogen and VC(6)H(6) and opens a new window for optimizing the future hydrogen storage materials.