Local Aromaticity: An Important Indicator of the Surface Active Sites of Heterocyclic Nanostructures

Abstract: Quick identification of the active sites on the surfaces of nanomaterials is rather critical for disclosing their exact interaction mechanism with various adsorbates in the general adsorption and catalysis processes. In this work, we propose that the local aromaticity of the surface sites (bonds or atoms) of different heterocyclic nanostructures (fullerenes, nanotubes, and nanosheets) could be easily evaluated by averaging the nucleus-independent chemical shifts at the centers of the surrounding rings. Signifi… Show more

“…Recently, we proposed that the local aromaticity is an important indicator of the optimal adsorption site of various heterocyclic nanostructures. 76 One can quickly locate the best active sites on the material surface by nding the sites with the least aromaticity. To this end, we redened the wellknown aromaticity criterion, nucleus-independent chemical shi (NICS, ppm), 77,78 for an atomic site by averaging the NICS values at its surrounding ring centers.…”

Dual-metal atom incorporated N-doped graphenes as oxygen evolution reaction electrocatalysts: high activities achieved by site synergies

“…Recently, we proposed that the local aromaticity is an important indicator of the optimal adsorption site of various heterocyclic nanostructures. 76 One can quickly locate the best active sites on the material surface by nding the sites with the least aromaticity. To this end, we redened the wellknown aromaticity criterion, nucleus-independent chemical shi (NICS, ppm), 77,78 for an atomic site by averaging the NICS values at its surrounding ring centers.…”

Dual-metal atom incorporated N-doped graphenes as oxygen evolution reaction electrocatalysts: high activities achieved by site synergies

Understanding intermediates adsorption in oxygen reduction/evolution reactions from the local aromaticities of catalyst sites

Activity origin of boron doped carbon cluster for thermal catalytic oxidation: Coupling effects of dopants and edges