Tunable van der Waals interactions in low-dimensional nanostructures

Non-covalent van der Waals interactions play a major role at the nanoscale, and even a slight change in their asymptotic decay could produce a major impact on surface phenomena, self-assembly of nanomaterials, and biological systems. By a full many-body description of vdW interactions in coupled carbyne-like chains and graphenic structures, here, we demonstrate that both modulus and a range of interfragment forces can be effectively tuned, introducing mechanical strain and doping (or polarizability change). This result contrasts with conventional pairwise vdW predictions, where the two-body approximation essentially fixes the asymptotic decay of interfragment forces. The present results provide viable pathways for detailed experimental control of nanoscale systems that could be exploited both in static geometrical configurations and in dynamical processes.

Automated summary

By providing a full many-body description of van der Waals interactions in coupled carbyne-like chains and graphenic structures, this study demonstrates the effective tuning of modulus and a range of interfragment forces, leading to the introduction of mechanical strain and doping. This contrasts with conventional pairwise van der Waals predictions, offering viable pathways for detailed experimental control of nanoscale systems.