Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal
Emitters strongly coupled to a photonic crystal provide a powerful platform for realizing novel quantum light-matter interactions. Here we study the optical properties of a three-level artificial atomic chain coupled to a one-dimensional superconducting microwave photonic crystal. A sharp minimum-en...
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sg-ntu-dr.10356-1006432020-09-26T21:56:24Z Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal Song, Guo-Zhu Kwek, Leong-Chuan Deng, Fu-Guo Long, Gui-Lu National Institute of Education MajuLab, CNRS-UNS-NUS-NTU International Joint Research Unit Institute of Advanced Studies DRNTU::Science::Physics Light-matter Interaction Long-range Interactions Emitters strongly coupled to a photonic crystal provide a powerful platform for realizing novel quantum light-matter interactions. Here we study the optical properties of a three-level artificial atomic chain coupled to a one-dimensional superconducting microwave photonic crystal. A sharp minimum-energy dip appears in the transmission spectrum of a weak input field, which reveals rich behavior of the long-range interactions arising from localized bound states. We find that the dip frequency scales linearly with both the number of the artificial atoms and the characteristic strength of the long-range interactions when the localization length of the bound state is sufficiently large. Motivated by this observation, we present a simple model to calculate the dip frequency with system parameters, which agrees well with the results from exact numerics for large localization lengths. We observe oscillation between bunching and antibunching in photon-photon correlation function of the output field. Furthermore, we find that the model remains valid even though the coupling strengths between the photonic crystal and artificial atoms are not exactly equal and the phases of external driving fields for the artificial atoms are different. Thus we may infer valuable system parameters from the dip location in the transmission spectrum, which provides an important measuring tool for the superconducting microwave photonic crystal systems in experiment. With remarkable advances to couple artificial atoms with microwave photonic crystals, our proposal may be experimentally realized in currently available superconducting circuits. NRF (Natl Research Foundation, S’pore) MOE (Min. of Education, S’pore) Published version 2019-06-06T08:38:47Z 2019-12-06T20:25:50Z 2019-06-06T08:38:47Z 2019-12-06T20:25:50Z 2019 Journal Article Song, G.-Z., Kwek, L.-C., Deng, F.-G., & Long, G.-L. (2019). Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal. Physical Review A, 99(4), 043830-. doi:10.1103/PhysRevA.99.043830 2469-9926 https://hdl.handle.net/10356/100643 http://hdl.handle.net/10220/48581 10.1103/PhysRevA.99.043830 en Physical Review A © 2019 American Physical Society. All rights reserved. This paper was published in Physical Review A and is made available with permission of American Physical Society. 10 p. application/pdf |
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DRNTU::Science::Physics Light-matter Interaction Long-range Interactions |
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DRNTU::Science::Physics Light-matter Interaction Long-range Interactions Song, Guo-Zhu Kwek, Leong-Chuan Deng, Fu-Guo Long, Gui-Lu Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal |
| description |
Emitters strongly coupled to a photonic crystal provide a powerful platform for realizing novel quantum light-matter interactions. Here we study the optical properties of a three-level artificial atomic chain coupled to a one-dimensional superconducting microwave photonic crystal. A sharp minimum-energy dip appears in the transmission spectrum of a weak input field, which reveals rich behavior of the long-range interactions arising from localized bound states. We find that the dip frequency scales linearly with both the number of the artificial atoms and the characteristic strength of the long-range interactions when the localization length of the bound state is sufficiently large. Motivated by this observation, we present a simple model to calculate the dip frequency with system parameters, which agrees well with the results from exact numerics for large localization lengths. We observe oscillation between bunching and antibunching in photon-photon correlation function of the output field. Furthermore, we find that the model remains valid even though the coupling strengths between the photonic crystal and artificial atoms are not exactly equal and the phases of external driving fields for the artificial atoms are different. Thus we may infer valuable system parameters from the dip location in the transmission spectrum, which provides an important measuring tool for the superconducting microwave photonic crystal systems in experiment. With remarkable advances to couple artificial atoms with microwave photonic crystals, our proposal may be experimentally realized in currently available superconducting circuits. |
| author2 |
National Institute of Education |
| author_facet |
National Institute of Education Song, Guo-Zhu Kwek, Leong-Chuan Deng, Fu-Guo Long, Gui-Lu |
| format |
Article |
| author |
Song, Guo-Zhu Kwek, Leong-Chuan Deng, Fu-Guo Long, Gui-Lu |
| author_sort |
Song, Guo-Zhu |
| title |
Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal |
| title_short |
Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal |
| title_full |
Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal |
| title_fullStr |
Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal |
| title_full_unstemmed |
Microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal |
| title_sort |
microwave transmission through an artificial atomic chain coupled to a superconducting photonic crystal |
| publishDate |
2019 |
| url |
https://hdl.handle.net/10356/100643 http://hdl.handle.net/10220/48581 |
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1681059194445234176 |