Density Functional Theory Study of Superalkali NLi₄-Decorated Graphdiyne Nanosheets as Hydrogen Storage Materials

Abstract: The properties and mechanism of adsorption of hydrogen molecules on NLi4-decorated graphdiyne nanosheets (NLi4-GDY) were investigated based on the density functional theory. Accordingly, the 76 hydrogen storage configurations of NLi4-SGDY, NLi4-GDY-A, and NLi4-SGDY-A were constructed by nonmetallic B/N substitution and A (A = B, N, Si, P) adsorption. The electronic structure of each configuration and the structure with the desired high hydrogen storage capacity were explored. The results showed that the charge… Show more

“…From Figure , it is noteworthy that no apparent orbital overlap is present between H­(1s) and Li­(2s) orbitals, which signifies that the primary mechanism by which H 2 molecules interact is not the orbital hybridization between H 2 molecules and Li atoms. This finding is consistent with the previously reported literature , and further confirmed by the noncovalent interaction calculation. Moreover, on the successive adsorption of H 2 , the electronic states of the H­(1s) orbital split because of repulsive interaction.…”

“…On decoration, NLi 4 can easily transfer electronic charge to the electron unsaturated substrates, resulting in enhanced positive charge on Li atoms. Subsequently, a local electrostatic field is generated, which effectively strengthens the interactions between Li and H 2 , thereby refining storage capacity, which is particularly significant in designing hydrogen storage materials . Onward this trend, Wang et al effectively employed a DFT study and proved that the NLi 4 cluster improves the hydrogen-storing capacity of h-BN nanosheets .…”

“…Subsequently, a local electrostatic field is generated, which effectively strengthens the interactions between Li and H 2 , thereby refining storage capacity, which is particularly significant in designing hydrogen storage materials. 54 Onward this trend, Wang et al effectively employed a DFT study and proved that the NLi 4 cluster improves the hydrogen-storing capacity of h-BN nanosheets. 49 Gao et al reported that the NLi 4 -decorated graphene nanoribbon exhibits a H 2 -storage capacity of 11.2 wt %.…”

Reversible Hydrogen Storage in a Superalkali NLi₄-Decorated Biphenylene Monolayer: Insights from a First-Principles Study

“…From Figure , it is noteworthy that no apparent orbital overlap is present between H­(1s) and Li­(2s) orbitals, which signifies that the primary mechanism by which H 2 molecules interact is not the orbital hybridization between H 2 molecules and Li atoms. This finding is consistent with the previously reported literature , and further confirmed by the noncovalent interaction calculation. Moreover, on the successive adsorption of H 2 , the electronic states of the H­(1s) orbital split because of repulsive interaction.…”

“…On decoration, NLi 4 can easily transfer electronic charge to the electron unsaturated substrates, resulting in enhanced positive charge on Li atoms. Subsequently, a local electrostatic field is generated, which effectively strengthens the interactions between Li and H 2 , thereby refining storage capacity, which is particularly significant in designing hydrogen storage materials . Onward this trend, Wang et al effectively employed a DFT study and proved that the NLi 4 cluster improves the hydrogen-storing capacity of h-BN nanosheets .…”

“…Subsequently, a local electrostatic field is generated, which effectively strengthens the interactions between Li and H 2 , thereby refining storage capacity, which is particularly significant in designing hydrogen storage materials. 54 Onward this trend, Wang et al effectively employed a DFT study and proved that the NLi 4 cluster improves the hydrogen-storing capacity of h-BN nanosheets. 49 Gao et al reported that the NLi 4 -decorated graphene nanoribbon exhibits a H 2 -storage capacity of 11.2 wt %.…”

Reversible Hydrogen Storage in a Superalkali NLi₄-Decorated Biphenylene Monolayer: Insights from a First-Principles Study

Properties, Synthesis and Emerging Applications of Graphdiyne: A Journey Through Recent Advancements

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