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电拉伸手性光子凝胶的宽带波长调谐

Broadband wavelength tuning of electrically stretchable chiral photonic gel.

作者信息

Nam Seungmin, Wang Dahee, Lee Gyubin, Choi Su Seok

机构信息

Department of Electrical Engineering, Pohang University of Science and Technology (POSTECH), 77 Cheongam-Ro, Nam Gu, Pohang, Gyeongbuk 37673, Republic of Korea.

出版信息

Nanophotonics. 2022 Jan 4;11(9):2139-2148. doi: 10.1515/nanoph-2021-0645. eCollection 2022 Apr.

DOI:10.1515/nanoph-2021-0645
PMID:39633916
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11501980/
Abstract

Chiral photonic-band structure provides technical benefits in the form of a self-assembled helical structure and further functional wavelength tunability that exploits helical deformation according to pitch changes. The stopband wavelength control of the chiral photonic-band structure can be obtained by individual electrical methods or mechanical stretching deformation approaches. However, research on combined electric control of stretchable chiral photonic-band wavelength control while ensuring optical stability during the tuning process has remained limited till now. In this study, using the hybrid structure of elastomeric mesogenic chiral photonic gels (CPGs) with an electrically controlled dielectric soft actuator, we report the first observation of electrically stretchable CPGs and their electro-mechano-optical behaviors. The reliable wavelength tuning of a CPG to a broadband wavelength of ∼171 nm changed with high optical stability and repeated wavelength transitions of up to 100 times. Accordingly, for the first time, electrical wavelength tuning method of stretchable chiral liquid crystal photonicband structure was investigated.

摘要

手性光子带结构以自组装螺旋结构的形式提供技术优势,并具有进一步的功能波长可调性,该可调性可根据螺距变化利用螺旋变形。手性光子带结构的阻带波长控制可通过单独的电学方法或机械拉伸变形方法实现。然而,迄今为止,关于在调谐过程中确保光学稳定性的同时对可拉伸手性光子带波长控制进行组合电控制的研究仍然有限。在本研究中,利用弹性体介晶手性光子凝胶(CPG)与电控介电软致动器的混合结构,我们首次观察到了可电拉伸的CPG及其机电光行为。CPG能够可靠地将波长调谐至约171 nm的宽带波长,具有高光学稳定性且波长可重复转换多达100次。因此,首次对手性液晶光子带结构的电波长调谐方法进行了研究。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/aeb7930de788/j_nanoph-2021-0645_fig_005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/a524fca7afc6/j_nanoph-2021-0645_fig_001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/674a573c84c2/j_nanoph-2021-0645_fig_002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/8ce16b53f56a/j_nanoph-2021-0645_fig_003.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/d1d34a310425/j_nanoph-2021-0645_fig_004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/aeb7930de788/j_nanoph-2021-0645_fig_005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/a524fca7afc6/j_nanoph-2021-0645_fig_001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/674a573c84c2/j_nanoph-2021-0645_fig_002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/8ce16b53f56a/j_nanoph-2021-0645_fig_003.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/d1d34a310425/j_nanoph-2021-0645_fig_004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2adf/11501980/aeb7930de788/j_nanoph-2021-0645_fig_005.jpg

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