Equatorial-Axial Conformational Dynamics Enabling Thermoresponsive SHG Switch in a Homochiral Hybrid Compound

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abstract

Switchable second-harmonic-generation (SHG) materials are promising for sensing, imaging, and signal modulation applications. In this work, we designed and synthesized a hybrid salt, (R-3-hydroxypiperidium)2[Fe(CN)5(NO)] (1), by strategically introducing homochirality to drive a unique equatorial-axial conformation-switch mechanism. At room temperature, 1 displays a measured direct band gap of 3.07 eV and SHG signals approximately 0.67 times that of the referential KH2PO4 (KDP), with density functional theory (DFT) calculation yielding a d 35 coefficient of 0.424 pm/V with a band gap of 2.17 eV. Even more striking is its remarkable SHG switching behavior, exhibiting an on/off contrast of nearly 100 triggered by an iso-space-group phase transition at temperatures up to 372 K. This transition, despite involving a change in the molecular conformation, preserves the overall space-group symmetry due to the chiral nature of the material, thus bypassing the typical symmetry-breaking observed in conventional phase transitions. Such anomalous switching was further elucidated through the supercell model with DFT calculations, allowing in-depth investigations of the underlying order-disorder transitions. The key mechanism of the structural transition is attributed to the reversible switching of hydroxyl groups between equatorial and axial positions, accompanied by distinctive thermal expansions. Additionally, analysis of the first hyperpolarizability of the conformational isomers reveals the molecular-level origins behind the dramatic changes in the SHG behavior. Our findings provide a foundational understanding of the relationship between molecular dynamics and SHG modulation, offering valuable guidelines for designing advanced nonlinear optical materials.

keywords

BASIS-SETS; PHASE-TRANSITION; GENERATION; BREAKING; DESIGN

subject category

Materials Science; Optics

authors

Guo, MY; Li, MF; Chen, XX; Xu, WJ; Zhang, WX

our authors

foto Wei-Jian Xu

Wei-Jian Xu

Junior Researcher

Groups

G1 - Porous Materials and Nanosystems

acknowledgements

This work was supported by the NSFC (22071273 and 21821003) and the Fundamental Research Funds for the Central Universities, Sun Yat-sen University (23lgzy001). M.Y. Guo is thankful for the funding from College Students' Innovative and Entrepreneurial Training (No. 31000-11220004). The National Supercomputing Center in Guangzhou (NSCC-GZ, Tianhe-2) is highly appreciated for providing computational resources.

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Publication Details

type
Journal Article
year
2024
journal
ACS APPLIED OPTICAL MATERIALS
volume
2
publisher
AMER CHEMICAL SOC
issn
2771-9855
issue
12
digital object identifier
10.1021/acsaom.4c00431
web of science article identifier
WOS:001372879000001

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