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A First-Principles Study on Titanium-Decorated Adsorbent for Hydrogen Storage

Kai Ma, Erfei Lv, Di Zheng, Weichun Cui, Shuai Dong, Weijie Yang, Zhengyang Gao, Yu Zhou

2021Energies17 citationsDOIOpen Access PDF

Abstract

Based on density functional theory calculation, we screened suitable Ti-decorated carbon-based hydrogen adsorbent structures. The adsorption characteristics and adsorption mechanism of hydrogen molecules on the adsorbent were also discussed. The results indicated that Ti-decorated double vacancy (2 × 2) graphene cells seem to be an efficient material for hydrogen storage. Ti atoms are stably embedded on the double vacancy sites above and below the graphene plane, with binding energy higher than the cohesive energy of Ti. For both sides of Ti-decorated double vacancy graphene, up to six H2 molecules can be adsorbed around each Ti atom when the adsorption energy per molecule is −0.25 eV/H2, and the gravimetric hydrogen storage capacity is 6.67 wt.%. Partial density of states (PDOS) analysis showed that orbital hybridization occurs between the d orbital of the adsorbed Ti atom and p orbital of C atom in the graphene layer, while the bonding process is not obvious during hydrogen adsorption. We expect that Ti-decorated double vacancy graphene can be considered as a potential hydrogen storage medium under ambient conditions.

Topics & Concepts

GrapheneAdsorptionHydrogen storageVacancy defectDensity functional theoryMaterials scienceHydrogenMoleculeTitaniumOrbital hybridisationAtom (system on chip)Gravimetric analysisHydrogen atomChemical physicsPhysical chemistryNanotechnologyCrystallographyChemistryMolecular orbitalComputational chemistryMetallurgyOrganic chemistryMolecular orbital theoryAlkylComputer scienceEmbedded systemHydrogen Storage and MaterialsGraphene research and applicationsAmmonia Synthesis and Nitrogen Reduction
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