China&#39;s Top 10 Optical Breakthroughs: Research Progress of Photonic Skyrmion

Min Lin; Luping Du; Xiaocong Yuan

doi:10.3788/LOP231925

Journals >Laser & Optoelectronics Progress >Volume 60 >Issue 24 >Page 2400001 > Article

Laser & Optoelectronics Progress
Vol. 60, Issue 24, 2400001 (2023)

China's Top 10 Optical Breakthroughs: Research Progress of Photonic Skyrmion

Min Lin, Luping Du^**, and Xiaocong Yuan^*

Author Affiliations

Nanophotonics Research Centre, Institute of Microscale Optoelectronics, Shenzhen University, Shenzhen 518060, Guangdong, China

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DOI: 10.3788/LOP231925 Cite this Article Set citation alerts

Min Lin, Luping Du, Xiaocong Yuan. China's Top 10 Optical Breakthroughs: Research Progress of Photonic Skyrmion[J]. Laser & Optoelectronics Progress, 2023, 60(24): 2400001 Copy Citation Text

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Abstract

Recently, photonic skyrmion as a topological nontrivial structure has attracted widely research attention. Due to their ultracompact size, high stability, and diversity of topologies, photonic skyrmions have potential value in applications of high-resolution polarization imaging, high-density optical information storage, and high-precision displacement sensing. In this paper, the fundamental mechanisms and the excitation and detection methods of photonic skyrmion are introduced, and the domestic and foreign state-of-the-art studies on the photonic skyrmion in different optical systems are summarized. In view of the deep-subwavelength features of the photonic skyrmion, the recent research progress of the applications of photonic skyrmions is also reviewed, and its future development is analyzed and prospected.

Keywords

deep-subwavelength feature optical spin-orbit coupling photonic skyrmion topological spin texture

n = \frac{1}{4 π} \iint \hat{S} \cdot (\frac{\partial \hat{S}}{\partial x} \times \frac{\partial \hat{S}}{\partial y}) d x d y

，（1）

n = \frac{1}{4 π} \int_{0}^{r_{σ}} d r \int_{0}^{2 π} d ϕ \frac{d β (r)}{d r} \frac{d α (ϕ)}{d ϕ} s i n β (r) = \frac{1}{4 π} {[c o s β (r)]}_{r = 0}^{r = r_{σ}} {[α (ϕ)]}_{ϕ = 0}^{ϕ = 2 π} = p \cdot m

，（2）

S = \frac{1}{2 ω^{2}} \nabla \times P

，（3）

δ 〈J_{S K} \cdot J_{S K}〉 = δ 〈r^{2} \{- Σ \cdot \nabla_{⊥}^{2} Σ - Σ \cdot \frac{\partial^{2}}{\partial n^{2}} Σ + \nabla \cdot [Σ \times (\nabla \times Σ)]\}〉

，（4）

S_{z} = \frac{ε}{4 ω i} \frac{k_{r}^{2}}{k_{z}^{2}} (E_{x}^{*} E_{y} - E_{y}^{*} E_{x}) = \frac{ε}{4 ω} \frac{k_{r}^{2}}{k_{z}^{2}} (I_{R C P} - I_{L C P})

，（5）

(\begin{matrix} S_{0} \\ S_{1} \\ S_{2} \\ S_{3} \end{matrix}) = (\begin{matrix} {|E_{x}|}^{2} + {|E_{y}|}^{2} \\ {|E_{x}|}^{2} - {|E_{y}|}^{2} \\ 2 R e [{E_{x}}^{*} E_{y}] \\ - 2 I m [{E_{x}}^{*} E_{y}] \end{matrix}) = (\begin{matrix} I \\ I c o s 2 ψ c o s 2 χ \\ I s i n 2 ψ c o s 2 χ \\ I s i n 2 χ \end{matrix})

，（6）

Min Lin, Luping Du, Xiaocong Yuan. China's Top 10 Optical Breakthroughs: Research Progress of Photonic Skyrmion[J]. Laser & Optoelectronics Progress, 2023, 60(24): 2400001

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