Plasmonic Chiral Switching via Sub-10-nm Gap Engineering in a Fiber-Taper-Silver Nanowire Hybrid System.

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Bibliographic Details
Title: Plasmonic Chiral Switching via Sub-10-nm Gap Engineering in a Fiber-Taper-Silver Nanowire Hybrid System.
Authors: Chen, Yifan1 (AUTHOR), Zhang, Fuping1 (AUTHOR), Wang, Huijie1 (AUTHOR), Dai, Wei1 (AUTHOR), Guan, Zhiqiang1,2 (AUTHOR) zhiqiang.guan@whu.edu.cn, Xu, Hongxing1 (AUTHOR)
Source: Chinese Physics Letters. 2026, Vol. 43 Issue 4, p1-7. 7p.
Subjects: Plasmonics, Optical switches, Finite difference time domain method, Polaritons, Near-field microscopy, Nanophotonics
Abstract: The nanoscale generation and manipulation of chiral surface plasmon polaritons are pivotal for advancing near-field optics and chiral biosensing, yet the microscopic coupling mechanisms governing chiral switching in hybrid plasmonic systems remain incompletely understood. Here, we report an ultra-sensitive chiral switch realized in a fiber-taper-silver nanowire hybrid structure, in which the handedness of guided SPPs is completely reversed by sub-10 nm variations of the coupling gap. Three-dimensional finite-difference time-domain simulations demonstrate a clear chirality inversion as the gap increases from 0 to 10 nm. By combining coupled-mode theory with a transfer-matrix approach, we elucidate the origin of the ultra-low-threshold chiral switching. We find that the switching is governed by a gap-induced accumulation of the relative phase between the HE+1 and HE−1 modes exceeding π /2. This effect arises from operating the mode converter in the vicinity of a phase singularity. The system exhibits an exceptional phase-sensitivity figure of merit of ∼0.12 π /nm. Our findings establish nanogap engineering as a powerful and hitherto overlooked control parameter for chiral plasmonics, offering a straightforward route for ultra-sensitive probing and active manipulation of chiral optical fields at deep-subwavelength scales. [ABSTRACT FROM AUTHOR]
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Database: Engineering Source
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