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- Title
Mending cracks atom-by-atom in rutile TiO<sub>2</sub> with electron beam radiolysis.
- Authors
Guo, Silu; Yun, Hwanhui; Nair, Sreejith; Jalan, Bharat; Mkhoyan, K. Andre
- Abstract
Rich electron-matter interactions fundamentally enable electron probe studies of materials such as scanning transmission electron microscopy (STEM). Inelastic interactions often result in structural modifications of the material, ultimately limiting the quality of electron probe measurements. However, atomistic mechanisms of inelastic-scattering-driven transformations are difficult to characterize. Here, we report direct visualization of radiolysis-driven restructuring of rutile TiO2 under electron beam irradiation. Using annular dark field imaging and electron energy-loss spectroscopy signals, STEM probes revealed the progressive filling of atomically sharp nanometer-wide cracks with striking atomic resolution detail. STEM probes of varying beam energy and precisely controlled electron dose were found to constructively restructure rutile TiO2 according to a quantified radiolytic mechanism. Based on direct experimental observation, a "two-step rolling" model of mobile octahedral building blocks enabling radiolysis-driven atomic migration is introduced. Such controlled electron beam-induced radiolytic restructuring can be used to engineer novel nanostructures atom-by-atom. Radiolysis is known for damaging crystals. Here, using STEM, researchers observed radiolysis-driven bond-breakage, atomic movements, & crystal restructuring in rutile TiO2, and proposed a "2-step rolling" model of building blocks. These results open possibilities for constructive use of radiolysis.
- Subjects
ELECTRON energy loss spectroscopy; ELECTRON beams; SCANNING transmission electron microscopy; RADIOLYSIS; RUTILE; ELECTRONIC probes
- Publication
Nature Communications, 2023, Vol 14, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-023-41781-x