一种电光可调的铌酸锂/钠基表面等离子体定向耦合器

马涛; 马家赫; 刘恒; 田永生; 刘少晖; 王芳

doi:10.7498/aps.71.20211217

摘要

为了满足日益增加的集成光子器件设计的需求, 本文研究了一种铌酸锂/钠表面等离子体波导(LiNbO₃/Na surface plasmonic waveguide, LNSPW), 并利用LNSPW构成电光可调的定向耦合器(directional coupling, DC). 利用有限元方法(finite element method, FEM)对波导的模式特性和耦合器的耦合特性进行了分析. 结果表明, 随着波导尺寸的增大, 传播长度可达约200 μm, 归一化有效模场面积小于0.4. 通过调节耦合间距(W_gap)、耦合长度(L_C)和工作波长(λ)等参数, 铌酸锂钠表面等离子体波导构建的定向耦合结构可实现3 dB耦合. 当W_gap = 100 nm和L_C = 17 μm时, DC在V₀ = 53 V时可实现3 dB耦合, 且具有较好的方向性和隔离度. LNSPW的研究为实现可调的DC提供了一种可行的方案, 在集成电光可调器件研究领域有潜在的应用前景. 除此之外, LNSPW还可广泛应用于非线性光学、光信号处理及光全息存储等领域.

关键词:

Abstract

To meet the increasing demand of integrated photonic device design, a LiNbO₃/Na surface plasmonic waveguide (LNSPW) is demonstrated, and a directional coupler (DC) based on the LNSPW is also studied. The mode characteristics of the LNSPW and the coupling performances of the DC are simulated by the finite element method (FEM). There are four modes in the LNSPW when its width (w₁) and the thickness (h₁) are less than 600 nm and 400 nm, respectively. The number of the modes in the LNSPW increases with waveguide size increasing. To achieve the single-mode propagation, w₁ and h₁ are chosen to be 300 nm and 200 nm, respectively. The effective refractive index (n_eff), propagation length (L_p), and normalized effective mode area (A_eff/A₀) are analyzed with different dimensional parameters of the LNSPW. The value of L_p is ~200 μm, and A_eff/A₀ is less than 0.4. In order to demonstrate the electro-optic tunable performance, the normalized output power (P_norm) values of the DC are calculated based on the LNSPWs with different values of coupling interval (W_gap), coupling length (L_C), and operating wavlength (λ). The P_norm values of the output ports (port 2 and port 3) vary with W_gap and L_C. Owing to the electro-optic effect of LiNbO₃ (LN), P_norm of the DC can be adjusted by changing the applied electrostatic voltage (V₀). The influence of V₀ on P_norm increases when W_gap is larger than 100 nm and L_C is greater than 12 μm. The larger the value of L_C and W_gap, the stronger the effect of V₀ on P_norm is, but P_norm values from two output ports decrease with W_gap and L_C increasing. A 3 dB coupler can be achieved by changing V₀ to 53 V when W_gap = ~100 nm, L_C = ~17 μm, and λ = 1.55 μm, and has good directivity and isolation. The LNSPW provides a feasible scheme to realize the tunable DC, and has potential applications in integratable electro-optic tuanble devices, nonlinear optics, optical signal processing, and optical holographic storage.

Keywords:

作者及机构信息

1.
河南师范大学电子与电气工程学院, 河南省光电传感集成应用重点实验室, 新乡　453007

2.
河南省电磁波工程院士工作站, 新乡　453007

通信作者: 刘恒, hengmaggie@163.com

基金项目: 国家自然科学基金(批准号: 62075057)和河南师范大学博士启动课题(批准号: gd17167, 5101239170010)资助的课题

Authors and contacts

1.
Henan Key Laboratory of Optoelectronic Sensing Integrated Application, College of Electronic and Electrical Engineering, Henan Normal University, Xinxiang 453007, China

2.
Academician Workstation of Electromagnetic Wave Engineering of Henan Province, Xinxiang 453007, China

Corresponding author: Liu Heng, hengmaggie@163.com

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 62075057) and the Doctoral Program of Henan Normal University, China (Grant Nos. gd17167, 5101239170010)

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参考文献

[1]	Zhang Q, Li M, Xu J, Lin Z J, Yu H F, Wang M, Fang Z W, Cheng Y, Gong Q H, Li Y 2019 Photonics Res. 7 503 Google Scholar
[2]	刘时杰, 郑远林, 陈险峰 2021 光学学报 41 0823013 Google Scholar Liu S J, Zheng Y L, Chen X F 2021 Acta Opt. Sin. 41 0823013 Google Scholar
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施引文献

图 1 (a) x-y平面内的LNSPW截面图; (b) 电势分布图, V₀ = 100 V

Fig. 1. (a) Cross section of the LNSPW in the x-y plane; (b) potential distribution as V₀ = 100 V.

下载: 全尺寸图片幻灯片

图 2 (a) 不同λ时, Na的折射率实部Re(n_Na)和虚部Im(n_Na). 模场分布图 (b) 基模(FM); (c) 二阶模(SM); (d) 三阶模(TM); (e) 类传导模(GM). (f)FM沿y轴的模场分布

Fig. 2. (a) Re(n_Na) and Im(n_Na) of Na with different λ. Mode field distributions of the (b) FM, (c) SM, (d) TM and (e) GM; (f) mode field distribution of the FM along y axis.

下载: 全尺寸图片幻灯片

图 3 Re(n_eff)随不同w₁和h₁的变化规律　(a) h₁ = 100 nm; (b) h₁ = 200 nm; (c) h₁ = 300 nm; (d) h₁ = 400 nm

Fig. 3. Re(n_eff) as functions of w₁ and h₁: (a) h₁ = 100 nm; (b) h₁ = 200 nm; (c) h₁ = 300 nm; (d) h₁ = 400 nm.

下载: 全尺寸图片幻灯片

图 4 L_P随w₁和h₁的变化规律　(a) h₁ = 100 nm; (b) h₁ = 200 nm; (c) h₁ = 300 nm; (d) h₁ = 400 nm

Fig. 4. L_P with different w₁ and h₁: (a) h₁ = 100 nm; (b) h₁ = 200 nm; (c) h₁ = 300 nm; (d) h₁ = 400 nm.

下载: 全尺寸图片幻灯片

图 5 A_eff/A₀随w₁和h₁的变化规律　(a) h₁ = 100 nm; (b) h₁ = 200 nm; (c) h₁ = 300 nm; (d) h₁ = 400 nm

Fig. 5. Influences of w₁ and h₁ on A_eff/A₀: (a) h₁ = 100 nm; (b) h₁ = 200 nm; (c) h₁ = 300 nm; (d) h₁ = 400 nm.

下载: 全尺寸图片幻灯片

图 6 (a) LNSPW构成的电光可调DC示意图; (b) DC x-y截面; (c) DC x-z截面

Fig. 6. (a) Schematic of the electro-optic tunable DC based on the LNSPW: (b) DC cross section in x-y plane; (c) DC cross section in x-z plane.

下载: 全尺寸图片幻灯片

图 7 (a) LNSPW构成的DC端口2和端口3的P_norm随L_C和V₀的变化图; (b) L_C = 17 μm时, 端口2和端口3的P_norm

Fig. 7. P_norm of the Port 2 and Port 3 in the DC based on the LNSPW (a) with different L_C and V₀, and (b) with different V₀ as L_C = 17 μm.

下载: 全尺寸图片幻灯片

图 8 LNSPW构成的DC的电场分布图　(a) V₀ = 0 V; (b) V₀ = 53 V; (c) V₀ = 90 V

Fig. 8. Mode field distributions of the DC based on the LNSPW: (a) V₀ = 0 V; (b) V₀ = 53 V; (c) V₀ = 90 V.

下载: 全尺寸图片幻灯片

图 9 不同L_C和V₀时, W_gap对P_norm的影响　(a) L_C = 5.3 μm; (b) L_C = 12 μm; (c) L_C = 17 μm

Fig. 9. P_norm as a function of W_gap with different L_C and V₀: (a) L_C = 5.3 μm; (b) L_C = 12 μm; (c) L_C = 17 μm.

下载: 全尺寸图片幻灯片

图 10 不同λ时, P_norm随(a) L_C和(b) W_gap的变化

Fig. 10. P_norm as functions of (a) L_C and (b) W_gap with different λ.

下载: 全尺寸图片幻灯片

图 11 V₀定向耦合的性能指标的影响　(a) SR和IL; (b) L_THP, L_TP, L_DI和L_IS

Fig. 11. Influences of V₀ on the performances of the DC based on the LNSPW: (a) SR and IL; (b) L_THP, L_TP, L_DI, and L_IS.

下载: 全尺寸图片幻灯片

[1]	Zhang Q, Li M, Xu J, Lin Z J, Yu H F, Wang M, Fang Z W, Cheng Y, Gong Q H, Li Y 2019 Photonics Res. 7 503 Google Scholar
[2]	刘时杰, 郑远林, 陈险峰 2021 光学学报 41 0823013 Google Scholar Liu S J, Zheng Y L, Chen X F 2021 Acta Opt. Sin. 41 0823013 Google Scholar
[3]	Wang C, Zhang M, Chen X, Bertrand M, Shams-Ansari A, Chandrasekhar S, Winzer P, Lončar M 2018 Nature 562 101 Google Scholar
[4]	Kues M, Reimer C, Roztocki P, Cortés L R, Sciara S, Wetzel B, Zhang Y B, Cino A, Chu S T, Little B E, Moss D J, Caspani L, Azaña J, Morandotti R 2017 Nature 546 622 Google Scholar
[5]	Janner D, Tulli D, García-Granda M, Belmonte M, Pruneri V 2009 Laser Photonics Rev. 3 301 Google Scholar
[6]	李庚霖, 贾曰辰, 陈峰 2020 物理学报 69 157801 Google Scholar Li G L, Jia Y C, Chen F 2020 Acta Phys. Sin. 69 157801 Google Scholar
[7]	Poberaj G, Hu H, Sohler W, Günter P 2012 Laser Photonics Rev. 6 488 Google Scholar
[8]	Levy M, Osgood R M, Liu R, Cross L E, Cargill G S, Kumar A, Bakhru H 1998 Appl. Phys. Lett. 73 2293 Google Scholar
[9]	Wang C, Burek M J, Lin Z, Atikian H A, Venkataraman V, Huang I C, Stark P, Lončar M 2014 Opt. Express 22 30924 Google Scholar
[10]	Zhang M, Wang C, Cheng R, Shams-Ansari A, Lončar M 2017 Optica 4 1536 Google Scholar
[11]	Lin J T, Xu Y X, Fang Z W, Wang M, Wang N W, Qiao L L, Fang W, Cheng Y 2015 Sci. China-Phys. Mech. Astron. 58 114209 Google Scholar
[12]	Wu R B, Zhang J H, Yao N, Fang W, Qiao L L, Chai Z F, Lin J T, Cheng Y 2018 Opt. Lett. 43 4116 Google Scholar
[13]	乔玲玲, 汪旻, 伍荣波, 方致伟, 林锦添, 储蔚, 程亚 2021 光学学报 41 0823012 Google Scholar Qiao L L, Wang M, Wu R B, Fang Z W, Lin J T, Chu W, Cheng Y 2021 Acta Opt. Sin. 41 0823012 Google Scholar
[14]	Wu R B, Wang M, Xu J, Qi J, Chu W, Fang Z W, Zhang J H, Zhou J X, Qiao L L, Chai Z F, Lin J T, Cheng Y 2018 Nanomaterials 8 910 Google Scholar
[15]	Lin J T, Yao N, Hao Z Z, Zhang J H, Mao W B, Wang M, Chu W, Wu R B, Fang Z W, Qiao L L, Fang W, Bo F, Cheng Y 2019 Phys. Rev. Lett. 122 173903 Google Scholar
[16]	Jia Y C, Wang L, Chen F 2021 Appl. Phys. Rev. 8 011307 Google Scholar
[17]	Yang L K, Li P, Wang H C, Li Z P 2018 Chin. Phys. B 27 094216 Google Scholar
[18]	Boltasseva A, Atwater H A 2011 Science 331 290 Google Scholar
[19]	Khurgin J B 2015 Nat. Nanotechnol. 10 2 Google Scholar
[20]	Naik G V, Shalaev V M, Boltasseva A 2013 Adv. Mater. 25 3264 Google Scholar
[21]	Prucha E J, Palik E D 1998 Handbook of Optical Constants of Solids II (London: Academic Press) p354
[22]	Wang Y, Yu J Y, Mao Y F, Chen J, Wang S, Chen H Z, Zhang Y, Wang S Y, Chen X J, Li T, Zhou L, Ma R M, Zhu S N, Cai W S, Zhu J 2020 Nature 581 401 Google Scholar
[23]	Tsilipakos O, Yioultsis T V, Kriezis E E 2009 J. Hazard Mater. 106 93109
[24]	Jiang A Q, Geng W P, Lv P, Hong J W, Jiang J, Wang C, Chai X J, Lian J W, Zhang Y, Huang R, Zhang D W, Scott J F, Hwang C S 2020 Nat. Mater. 19 1188 Google Scholar

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一种电光可调的铌酸锂/钠基表面等离子体定向耦合器