AI Article Synopsis
- X-rays, discovered in 1895, have diverse applications but typically require large amounts of material for characterization, prompting efforts to reduce material quantity.
- Researchers have developed a method to analyze the elemental and chemical state of individual atoms, using a specialized tip to detect X-ray-excited currents from iron and terbium atoms.
- This technique demonstrates atomically localized detection and combines synchrotron X-rays with quantum tunneling, paving the way for advanced experiments to study materials at the single-atom level.
Article Abstract
Since the discovery of X-rays by Roentgen in 1895, its use has been ubiquitous, from medical and environmental applications to materials sciences. X-ray characterization requires a large number of atoms and reducing the material quantity is a long-standing goal. Here we show that X-rays can be used to characterize the elemental and chemical state of just one atom. Using a specialized tip as a detector, X-ray-excited currents generated from an iron and a terbium atom coordinated to organic ligands are detected. The fingerprints of a single atom, the L and M absorption edge signals for iron and terbium, respectively, are clearly observed in the X-ray absorption spectra. The chemical states of these atoms are characterized by means of near-edge X-ray absorption signals, in which X-ray-excited resonance tunnelling (X-ERT) is dominant for the iron atom. The X-ray signal can be sensed only when the tip is located directly above the atom in extreme proximity, which confirms atomically localized detection in the tunnelling regime. Our work connects synchrotron X-rays with a quantum tunnelling process and opens future X-rays experiments for simultaneous characterizations of elemental and chemical properties of materials at the ultimate single-atom limit.
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| http://dx.doi.org/10.1038/s41586-023-06011-w | DOI Listing |
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