Litcius/Paper detail

Thermodynamic Preference for Atom Adsorption on versus Intercalation into Multilayer Graphene

Wei Li, Li Huang, Michael C. Tringides, James W. Evans, Yong Han

2020The Journal of Physical Chemistry Letters31 citationsDOIOpen Access PDF

Abstract

The thermodynamic preference of a foreign atom for adsorption on versus intercalation into a graphitic surface is of fundamental and widespread interest. From an exhaustive first-principles density functional theory investigation for 38 typical elements over the periodic table, we reveal a quasilinear correlation between the Shannon effective ionic radius and the chemical-potential difference for a single atom from adsorption to intercalation at multilayer graphene surfaces. A critical Shannon radius is found to be around 0.10 nm, below (above) which intercalation (adsorption) is more favorable for elements with ionic-like bonding after intercalation. Single atoms with van der Waals-biased bonding show some deviation from the linear relationship, while single atoms for the elements with covalent-like bonding do not favor intercalation relative to adsorption. An energy decomposition analysis indicates that the chemical-potential difference determining the thermodynamic preference of a foreign atom for adsorption versus intercalation results from the competition between the electronic and elastic strain effects.

Topics & Concepts

Intercalation (chemistry)AdsorptionIonic radiusGraphenevan der Waals forceDensity functional theoryIonic bondingAtom (system on chip)Chemical physicsMaterials scienceThermodynamicsChemical bondChemistryComputational chemistryMoleculePhysical chemistryInorganic chemistryIonNanotechnologyPhysicsOrganic chemistryEmbedded systemComputer scienceGraphene research and applicationsBoron and Carbon Nanomaterials ResearchMachine Learning in Materials Science
Thermodynamic Preference for Atom Adsorption on versus Intercalation into Multilayer Graphene | Litcius