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高性能非互易光子器件能够有效地提升光量子操控、信息处理以及量子模拟的效率. 放大的光信号可以增强并隔离量子系统输出的微弱信号, 避免敏感量子系统受反向散射噪声等影响, 是高性能光子器件的核心技术. 在我们先前的工作(
2023 Opt. Express 31 38228 )中, 基于四波混频增益并利用耦合场强度随位置线性变化实现了单向反射光放大的动力学调控. 本文巧妙地设计了简单的三能级闭合回路相干增益原子系统, 创新性地设置耦合场强度随位置阶梯型变化来破坏极化率空间对称性实现了完美非互易反射光放大. 相比之下, 耦合场强度阶梯型变化在实验上更容易调节, 大大地降低了实验难度. 特别地, 该系统引入了相位调制. 通过改变相位能够切换探测光增益和吸收的频率域, 对反射光放大的调节更具灵活性.High-performance non-reciprocal photonic devices can improve the efficiency of optical quantum manipulation, information processing, and quantum simulation effectively. The enhanced optical signal can simultaneously amplify the weak signal output by the quantum system and isolate the sensitive quantum system from the back-scattered external noise, which is the core technology of high-performance photonic devices. In our previous work (2023 Opt. Express 31 38228 ), we have achieved dynamic control of unidirectional reflection amplification based on four-wave mixing gain and the use of coupling field intensity varying linearly with position. In this work, we design a simple three-level closed loop coherent gain atomic system, setting the intensity of coupling field to be varying with position step shape to break the spatial symmetry of probe susceptibility, and achieving perfect non-reciprocal reflection light amplification. In contrast, the stepped variation of coupling field intensity is easier to adjust in experiment, greatly reducing the difficulty in the experiment. Specifically, the system introduces phase modulation. By changing the phase, the frequency region of probe gain and absorption can be switched, which makes the modulation of reflection amplification more flexible.-
Keywords:
- perfect non-reciprocal /
- reflection amplification /
- relative phases
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图 1 (a)三能级$ \Lambda $型相干原子系统; (b)耦合场$ {G_{\mathrm{c}}}(x) $随位置阶梯型变化, $ k = 5 $和$ k = 8 $分别对应红色虚线和蓝色实线, 恒定耦合场$ {G_{\mathrm{c}}} = 25{\text{ MHz}} $对应绿色虚点线; (c)耦合场和微波场竖直方向进入介质, 探测场沿水平方向传播的示意图, 介质长度$ L = 8{\text{ μm}} $
Fig. 1. (a) Three-level $ \Lambda $ model coherent atomic system; (b) the intensity of coupling field $ {G_{\mathrm{c}}}(x) $ varies with position by step, $ k = 5 $ and $ k = 8 $ corresponding to red dashed and blue solid respectively, the constant coupling field $ {G_{\mathrm{c}}} = 25{\text{ MHz}} $ corresponding to green dotted line; (c) diagram of the homogeneous atomic medium illuminated by coupling and microwave fields vertical $ x $ axis, and probe field travels along $ x $ direction, the medium length $ L = 8{\text{ μm}}$.
图 2 (a) 恒定耦合场$ {G_{\mathrm{c}}} = 25 {\text{MHz}} $时, 各能级粒子数布居随失谐$ {\varDelta _{\text{p}}} $的变化; (b) 阶梯型耦合场$ (k = 8) $时, 各能级粒子数布居随位置的变化; (c), (d) $ \left| 1 \right\rangle $能级与$ \left| 3 \right\rangle $能级粒子数布居差$ {\rho _{11}} - {\rho _{33}} $随位置和失谐的变化以及随位置和相位的变化, 对应阶梯型耦合场$ (k = 8) $. 相关参数: $ \varPhi = {{3\pi } \mathord{\left/ {\vphantom {{3\pi } 2}} \right. } 2} $, $ {N_0} = 3 \times {10^{11}}{\text{ c}}{{\text{m}}^{ - 3}} $, $ {G_{\text{d}}} = 15{\text{ MHz}}, {\text{ }}{G_{\text{p}}} = 0.3{\text{ MHz}} $, $ {\varDelta _{\text{c}}} = 0, {\text{ }}{d_{13}} = 2.0 \times {10^{ - 29}}{\text{ }}{\mathrm{C}} \cdot {\mathrm{m}}, $$ {\text{ }}{\varGamma _{31}} = {\varGamma _{32}} = 6{\text{ MHz}} $
Fig. 2. (a) Population distribution of each level vs. $ {\varDelta _{\text{p}}} $ with the constant coupling field $ {G_{\mathrm{c}}} = 25{\text{ MHz}} $; (b) population distribution of each level varies with position with stepped coupling field $ (k = 8) $; (c), (d) the population difference $ {\rho _{11}} - {\rho _{33}} $ between level $ \left| 1 \right\rangle $ and level $ \left| 3 \right\rangle $ varies with position $ x $ and detuning $ {\varDelta _{\text{p}}} $ or position $ x $ and relative phase $ \varPhi $ with step coupling field $ (k = 8) $. Other parameters: $ \varPhi = 3\pi /2 $, $ {N_0} = 3 \times {10^{11}}{\text{ c}}{{\text{m}}^{ - 3}} $, $ {G_{\text{d}}} = 15{\text{ MHz}}, {\text{ }}{G_{\text{p}}} = 0.3{\text{ MHz}}, $$ {\varDelta _{\text{c}}} = 0, {\text{ }}{d_{13}} = 2.0 \times {10^{ - 29}}{\text{ }}{\mathrm{C}} \cdot {\mathrm{m}}, {\text{ }}{\varGamma _{31}} = $$ {\varGamma _{32}} = 6{\text{ MHz}} $.
图 3 (a), (c), (e) 探测场的左右反射率随失谐$ {\varDelta _{\mathrm{p}}} $的变化, 分别对应恒定场$ {G_{\mathrm{c}}} = 25{\text{ MHz}} $, 阶梯型耦合场$ (k = 5) $和$ (k = 8) $; (b), (d), (f) 探测场左右反射率对比度随失谐$ {\varDelta _{\text{p}}} $的变化; 其他参数与图2相同
Fig. 3. (a), (c), (e) Left and right reflectivity of the probe field vs. detuning $ {\varDelta _{\text{p}}} $, corresponding to constant coupling field $ {G_{\mathrm{c}}} = 25{\text{ MHz}} $, stepped coupling field $ (k = 5) $ and $ (k = 8) $, respectively; (b), (d), (f) the corresponding contrast of left and right reflectivity vs. detuning $ {\varDelta _{\text{p}}} $. Other parameters are the same as in Fig 2.
图 4 极化率虚部随失谐和相对相位的变化 (a) $ {G_{\text{c}}} = 9{\text{ MHz}} $; (b) $ {G_{\text{c}}} = 16{\text{ MHz}} $; (c) $ {G_{\text{c}}} = 25{\text{ MHz}} $; (d) $ {G_{\text{c}}} = 36{\text{ MHz}} $; 其他参数与图2相同
Fig. 4. Changes of the imaginary part of the polarizability with the detuning and relative phase: (a) $ {G_{\text{c}}} = 9{\text{ MHz}} $; (b) $ {G_{\text{c}}} = $$ 16{\text{ MHz}} $; (c) $ {G_{\text{c}}} = 25{\text{ MHz}} $; (d) $ {G_{\text{c}}} = 36{\text{ MHz}} $. Other parameters are the same as in Fig. 2.
图 5 探测场的左右反射率(a), (b)及其对比度(c), (d)随失谐$ {\varDelta _{\text{p}}} $的变化 (a), (c)阶梯型耦合场对应 $ k = 5 $; (b), (d) 阶梯型耦合场对应$ k = 8 $; 相对相位 $ \varPhi = 7\pi /4 $, 其他参数与图2相同
Fig. 5. (a), (b) Left and right reflectivity of the probe field and (c), (d) their contrast vs. detuning $ {\varDelta _{\text{p}}} $: (a), (c) The stepped coupling field corresponding to $ k = 5 $; (b), (d) the stepped coupling field corresponding to $ k = 8 $. The relative phases $ \varPhi = 7{\text{π }}/4 $, other parameters are the same as in Fig. 2.
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[1] Hu Y Q, Zhang S C, Qi Y H, Lin G W, Niu Y P, Gong S Q 2019 Phys. Rev. Appl. 12 054004
Google Scholar
[2] Shi Y, Yu Z F, Fan S H 2015 Nat. Photonics 9 388
Google Scholar
[3] Cao Q T, Wang H, Dong C H, Jing H, Liu R S, Chen X, Ge L, Gong Q, Xiao Y F 2017 Phys. Rev. Lett. 118 033901
Google Scholar
[4] Shen Z, Zhang Y L, Chen Y, Sun F W, Guo X B, Dong C H 2018 Nat. Commun. 9 1797
Google Scholar
[5] Shen H Z, Wang Q, Wang J, Yi X X 2020 Phys. Rev. A 101 013826
Google Scholar
[6] Markelov V A, Novikov M, Turkin A A 1977 JETP Lett. 25 9
[7] Yu Z, Fan S 2009 Nat. Photonics 3 91
Google Scholar
[8] Lira H, Yu Z, Fan S, Lipson M 2012 Phys. Rev. Lett. 109 033901
Google Scholar
[9] Kang M S, Butsch A, Russell P S J 2011 Nat. Photonics 5 549
Google Scholar
[10] Estep N A, Sounas D L, Soric J, Alu A 2014 Nat. Phys. 10 923
Google Scholar
[11] Kittlaus E A, Otterstrom N T, Kharel P, Gertler S, Rakich P T 2018 Nat. Photonics 12 613
Google Scholar
[12] Sohn D B, Kim S, Bahl G 2018 Nat. Photonics 12 91
Google Scholar
[13] 盖云冉, 郑康, 丁春玲 2024 物理学报 73 014201
Google Scholar
Gai Y R, Zheng K, Ding C L 2024 Acta Phys. Sin. 73 014201
Google Scholar
[14] 刘妮, 马硕, 梁九卿 2023 物理学报 72 060702
Google Scholar
Liu N, Ma S, Liang J Q 2023 Acta Phys. Sin. 72 060702
Google Scholar
[15] Xu X W, Li Y, Chen A X, Liu Y X 2016 Phys. Rev. A 93 023827
Google Scholar
[16] Fang K, Luo J, Metelmann A, Matheny M H, Marquardt F, Clerk A A, Painter O 2017 Nat. Phys. 13 465
Google Scholar
[17] Yang P F, Xia X W, He H, Li S K, Han X, Zhang P, Li G, Zhang P F, Xu J P, Yang Y P, Zhang T C 2019 Phys. Rev. Lett. 123 233604
Google Scholar
[18] Huang R, Miranowicz A, Liao J Q, Nori F, Jing H 2018 Phys. Rev. Lett. 121 153601
Google Scholar
[19] Tang L, Tang J S, Chen M Y, Nori F, Xiao M, Xia K Y 2022 Phys. Rev. Lett. 128 083604
Google Scholar
[20] Hafezi M, Rabl P 2012 Opt. Express 20 7672
Google Scholar
[21] Shen Z, Zhang Y L, Chen Y, Zou C L, Xiao Y F, Zou X B, Sun F W, Guo G C, Dong C H 2016 Nat. Photonics 10 657
Google Scholar
[22] Peng B, Ozdemir S K, Lei F C, Monifi F 2014 Nat. Phys. 10 394
Google Scholar
[23] Xia K, Lu G, Lin G, Cheng Y, Niu Y, Gong S, Twamley J 2014 Phys. Rev. A 90 043802
Google Scholar
[24] Sayrin C, Junge C, Mitsch R, Albrecht B, O’Shea D, Schneeweiss P, Rauschenbeutel A 2015 Phys. Rev. X 5 041036
Google Scholar
[25] Scheucher M, Hilico A, Will E, Volz J, Rauschenbeutel A 2016 Science 354 1577
Google Scholar
[26] Lodahl P, Mahmoodian S, Stobbe S, Rauschenbeutel A, Schneeweiss P, Volz J, Zoller P 2017 Nature 541 473
Google Scholar
[27] Wu J H, Artoni M, La Rocca G C 2015 Phys. Rev. A 91 033811
Google Scholar
[28] Chaung Y L, Shamsi A, Abbas M 2020 Opt. Express 28 1701
Google Scholar
[29] Yang L, Zhang Y, Yan X B, Sheng Y, Cui C L, Wu J H 2015 Phys. Rev. A 92 053859
Google Scholar
[30] Wang D W, Zhou H T, Guo M J, Zhang J X, Evers J, Zhu S Y 2013 Phys. Rev. Lett. 110 093901
Google Scholar
[31] Zhang S, Hu Y, Lin G, Niu Y, Xia K, Gong J, Gong S 2018 Nat. Photonics 12 744
Google Scholar
[32] Lin G, Zhang S, Hu Y, Niu Y, Gong J, Gong S 2019 Phys. Rev. Lett. 123 033902
Google Scholar
[33] Hu Y, Qi Y, You Y, Zhang S, Lin G, Li X, Niu Y 2021 Phys. Rev. Appl. 16 014046
Google Scholar
[34] 李鑫, 解舒云, 李林帆, 周海涛, 王丹, 杨保东 2022 物理学报 71 184202
Google Scholar
Li X, Xie S Y, Li L F, Zhou H T, Wang D, Yang B D 2022 Acta Phys. Sin. 71 184202
Google Scholar
[35] Heras de las A M, Carusotto I 2021 Phys. Rev. A 104 043501
Google Scholar
[36] Otterstrom N T, Kittlaus E A, Gertler S, Behunin R O, Lentine A L, Rakich P T 2019 Optica 6 1117
Google Scholar
[37] Song L N, Wang Z H, Li Y 2018 Opt. Commun. 415 39
Google Scholar
[38] Abdo B, Sliwa K, Shankar S, Hatridge M, Frunzio L, Schoelkopf R, Devoret M 2014 Phys. Rev. Lett. 112 167701
Google Scholar
[39] Metelmann A, Clerk A A 2015 Phys. Rev. X 5 021025
Google Scholar
[40] Koutserimpas T T, Fleury R 2018 Phys. Rev. Lett. 120 087401
Google Scholar
[41] Sliwa K M, Hatridge M, Narla A, Shankar S, Frunzio L, Schoelkopf R J, Devoret M H 2015 Phys. Rev. X 5 041020
Google Scholar
[42] Lecocq F, Ranzani L, Peterson G A, Cicak K, Simmonds R W, Teufel J D, Aumentado J 2017 Phys. Rev. Appl. 7 024028
Google Scholar
[43] Li Y, Huang Y Y, Zhang X Z, Tian L 2017 Opt. Express 25 18907
Google Scholar
[44] Jiang C, Song L N, Li Y 2018 Phys. Rev. A. 97 053812
Google Scholar
[45] Ruesink F, Miri M A, Alù A, Verhagen E 2016 Nat. Commun. 7 13662
Google Scholar
[46] Malz D, Tóth L D, Bernier N R, Feofanov A K, Kippenberg T J, Nunnenkamp A 2018 Phys. Rev. Lett. 120 023601
Google Scholar
[47] Jiang W, Ma Y, Yuan J, Yin G, Wu W, He S 2017 Laser Photonics Rev. 11 1600253
Google Scholar
[48] Liu D J, Huang Y, Hu H, Liu L L, Gao D L, Ran L X, Ye D X, Luo Y 2019 IEEE Trans. Antennas Propag. 68 2945
Google Scholar
[49] Zhang Y, Wu J H, Artoni M, La Rocca G C 2021 Opt. Express 29 5890
Google Scholar
[50] Geng Y, Pei X, Li G, Lin X, Zhang H, Yan D, Yang H 2023 Opt. Express 31 38228
Google Scholar
[51] Artoni M, La Rocca G, Bassani F 2005 Phys. Rev. E 72 046604
Google Scholar
[52] Zhang Y, Xue Y, Wang G, Cui C L, Wang R, Wu J H 2011 Opt. Express 19 2111
Google Scholar
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