Non-equilibrium Pathways to Emergent Polar Supertextures

Overview

Journal Nat Mater

Date 2024 Sep 24

PMID 39317816

Authors

Vladimir A Stoica

Tiannan Yang

Sujit Das

Yue Cao

Huaiyu Hugo Wang

Yuya Kubota

Cheng Dai

Hari Padma

Yusuke Sato

Anudeep Mangu

Quynh L Nguyen

Zhan Zhang

Disha Talreja

Marc E Zajac

Donald A Walko

Anthony D DiChiara

Shigeki Owada

Kohei Miyanishi

Kenji Tamasaku

Takahiro Sato

James M Glownia

Vincent Esposito

Silke Nelson

Matthias C Hoffmann

Richard D Schaller

Aaron M Lindenberg

Lane W Martin

Ramamoorthy Ramesh

Iwao Matsuda

Diling Zhu

Long-Q Chen

Haidan Wen

Venkatraman Gopalan

John W Freeland

Affiliations

Soon will be listed here.

Abstract

Ultrafast stimuli can stabilize metastable states of matter inaccessible by equilibrium means. Establishing the spatiotemporal link between ultrafast excitation and metastability is crucial to understand these phenomena. Here we utilize single-shot optical pump-X-ray probe measurements to capture snapshots of the emergence of a persistent polar vortex supercrystal in a heterostructure that hosts a fine balance between built-in electrostatic and elastic frustrations by design. By perturbing this balance with photoinduced charges, an initially heterogeneous mixture of polar phase disorders within a few picoseconds, leading to a state composed of disordered ferroelectric and suppressed vortex orders. On the picosecond-nanosecond timescales, transient labyrinthine fluctuations develop, accompanied by the recovery of the vortex order. On longer timescales, these fluctuations are progressively quenched by dynamical strain modulations, which drive the collective emergence of a single vortex supercrystal phase. Our results, corroborated by dynamical phase-field modelling, reveal non-equilibrium pathways following the ultrafast excitation of designer systems to persistent metastability.

Citing Articles

Hidden domain boundary dynamics toward crystalline perfection.

Mangu A, Stoica V, Zheng H, Yang T, Zhang M, Wang H Proc Natl Acad Sci U S A. 2025; 122(2):e2407772122.

PMID: 39773030 PMC: 11745343. DOI: 10.1073/pnas.2407772122.

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Qing H, Qi F, Yin J Nat Mater. 2024; 23(10):1315-1317.

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