Orbitals of Artificial Atoms in a Gapped Two-Dimensional Vacuum
Mong-Wen Gu, Aizhan Sabitova, Taner Esat, Christian Wagner, F. Stefan Tautz + 2 more
TLDR
This paper visualizes artificial atom orbitals in a gapped 2D vacuum, revealing both s/p-like states and entirely new, vacuum-shaped orbitals.
Key contributions
- Visualized artificial atom orbitals in a 2D molecular film using scanning tunnelling microscopy.
- Identified s and p-like orbitals in artificial atoms, mirroring natural atomic bonding.
- Discovered novel quasi-one-dimensional orbitals unique to the gapped 2D electronic vacuum.
Why it matters
This research expands the fundamental understanding of artificial atoms and their electronic states. It introduces a new class of orbitals, opening possibilities for designing novel materials with tailored electronic properties by leveraging the surrounding electronic environment.
Original Abstract
Advances in nanotechnology now allow the creation of artificial atoms - engineered structures whose electronic states closely mimic those of real atoms. Understanding how these artificial atoms interact and bond is key to designing new materials with tailored electronic properties. Here, we use scanning tunnelling microscopy to visualise the bound states of nanostructures patterned in a two-dimensional molecular film featuring a parabolic band with multiple partial energy gaps. The lowest-energy states split off from the bottom of the band and resemble the familiar $s$ and $p$ orbitals of natural atoms, even bonding in the same way. Yet, artificial atoms go beyond this analogy: the gapped two-dimensional vacuum in which they reside gives rise to entirely new orbitals with no counterparts in real atoms. These quasi-one-dimensional localised states enrich the orbital vocabulary of chemistry, adding a new class of orbitals that are predominantly shaped by the surrounding electronic vacuum.
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