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C3N monolayer decorated with single-atom Y for outstanding and reversible hydrogen storage: A DFT study

Shulin Yang, Can Hu, Gui Lei, Wei Xie, Juan Xiong, Huoxi Xu

2024International Journal of Hydrogen Energy24 citationsDOIOpen Access PDF

Abstract

First-principles density functional theory (DFT) calculations were conducted to investigate the feasibility of single-atom Y decoration on the C 3 N monolayer and its consequent interactions with H 2 molecules. The Y atom preferably and firmly dispersed over a hexatomic-carbon ring within the C 3 N monolayer, exhibiting a high binding energy of −5.124 eV. The Y atom decorated on the C 3 N monolayer demonstrated the capability to adsorb and store one to five H 2 molecules through a typical Kubas interaction, featuring reasonable average adsorption energies ranging from −0.361 eV to −0.265 eV. All the adsorbed H 2 molecules could be fully desorbed from the Y-decorated C 3 N at a temperature approximately reaching 500 K. Moreover, the single-atom Y on the C 3 N showcased a high diffusion energy of 1.976 eV, energetically preventing cluster effects of the dispersed Y atoms. Elevating the number of decorated Y atoms to four on each side of the C 3 N substantially improved the stored H 2 to 40. Consequently, the hydrogen storage capacity of the C 3 N decorated with eight Y atoms surged to an impressive 6.76 wt% with a suitable average adsorption energy of −0.249 eV, meeting the requirements of the U.S. DOE. These results demonstrate that the Y-decorated C 3 N monolayer could be an excellent substrate for exhibiting outstanding and reversible hydrogen storage performance.

Topics & Concepts

MonolayerHydrogen storageAdsorptionDensity functional theoryAtom (system on chip)Substrate (aquarium)MoleculeHydrogenMaterials scienceHydrogen atomCrystallographyBinding energyChemical physicsChemistryNanotechnologyPhysical chemistryComputational chemistryAtomic physicsOrganic chemistryPhysicsOceanographyEmbedded systemComputer scienceGeologyAlkylHydrogen Storage and MaterialsBoron and Carbon Nanomaterials ResearchMXene and MAX Phase Materials
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