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Leveraging Curvature on N‐Doped Carbon Materials for Hydrogen Storage

Peter S. Rice, Gabriel Lee, Brayden Schwartz, Tom Autrey, Bojana Ginovska

2024Small21 citationsDOIOpen Access PDF

Abstract

Abstract Carbon sorbent materials have shown great promise for solid‐state hydrogen (H 2 ) storage. Modification of these materials with nitrogen (N) dopants has been undertaken to develop materials that can store H 2 at ambient temperatures. In this work density functional theory (DFT) calculations are used to systematically probe the influence of curvature on the stability and activity of undoped and N‐doped carbon materials toward H binding. Specifically, four models of carbon materials are used: graphene, [5,5] carbon nanotube, [5,5] D 5d ‐C 120, and C 60 , to extract and correlate the thermodynamic properties of active sites with varying degrees of sp 2 hybridization (curvature). From the calculations and analysis, it is found that graphitic N‐doping is thermodynamically favored on more pyramidal sites with increased curvature. In contrast, it is found that the hydrogen binding energy is weakly affected by curvature and is dominated by electronic effects induced by N‐doping. These findings highlight the importance of modulating the heteroatom doping configuration and the lattice topology when developing materials for H 2 storage.

Topics & Concepts

Hydrogen storageHeteroatomMaterials scienceGrapheneDopingDensity functional theoryCarbon fibersDopantCurvatureHydrogenCarbon nanotubeNanotechnologyBinding energyChemical physicsChemical engineeringComputational chemistryChemistryAtomic physicsOrganic chemistryComposite materialGeometryPhysicsOptoelectronicsEngineeringComposite numberRing (chemistry)MathematicsHydrogen Storage and MaterialsGraphene research and applicationsBoron and Carbon Nanomaterials Research
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