Mesoscopic structural phase progression in photo-excited VO2 revealed by time-resolved x-ray diffraction microscopy

Dynamical phase separation during a solid-solid phase transition poses a challenge for understanding the fundamental processes in correlated materials. Critical information underlying a phase transition, such as localized phase competition, is difficult to reveal by measurements that are spatially a...

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Bibliographic Details
Published in:Scientific reports 2016-02, Vol.6 (1), p.21999-21999, Article 21999
Main Authors: Zhu, Yi, Cai, Zhonghou, Chen, Pice, Zhang, Qingteng, Highland, Matthew J., Jung, Il Woong, Walko, Donald A., Dufresne, Eric M., Jeong, Jaewoo, Samant, Mahesh G., Parkin, Stuart S. P., Freeland, John W., Evans, Paul G., Wen, Haidan
Format: Article
Language:English
Subjects:
639/301/119/2795
639/766/119/2795
Competition
Diffraction
Humanities and Social Sciences
MATERIALS SCIENCE
Microscopy
multidisciplinary
Phase transitions
phase transitions and critical phenomena
Science
X-ray diffraction
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Summary:Dynamical phase separation during a solid-solid phase transition poses a challenge for understanding the fundamental processes in correlated materials. Critical information underlying a phase transition, such as localized phase competition, is difficult to reveal by measurements that are spatially averaged over many phase separated regions. The ability to simultaneously track the spatial and temporal evolution of such systems is essential to understanding mesoscopic processes during a phase transition. Using state-of-the-art time-resolved hard x-ray diffraction microscopy, we directly visualize the structural phase progression in a VO 2 film upon photoexcitation. Following a homogenous in-plane optical excitation, the phase transformation is initiated at discrete sites and completed by the growth of one lattice structure into the other, instead of a simultaneous isotropic lattice symmetry change. The time-dependent x-ray diffraction spatial maps show that the in-plane phase progression in laser-superheated VO 2 is via a displacive lattice transformation as a result of relaxation from an excited monoclinic phase into a rutile phase. The speed of the phase front progression is quantitatively measured, and is faster than the process driven by in-plane thermal diffusion but slower than the sound speed in VO 2 . The direct visualization of localized structural changes in the time domain opens a new avenue to study mesoscopic processes in driven systems.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep21999