Your search keyword '"Rui, Bo"' showing total 6 results

1. Spatial modulation of refractive index in a dense atomic ensemble using Laguerre–Gaussian beams.

Author

Peng, Chen, Zheng, Kang, Jin, Rui-Bo, Ding, Chunling, and Hao, Xiangying

Subjects

LAGUERRE-Gaussian beams, ATOMIC beams, VECTOR beams, OPTICAL vortices, OPTICAL switching, REFRACTIVE index, LOGIC circuits

Abstract

We propose a scheme to investigate the spatial modulation of the refractive index in a dense atomic ensemble under the action of the Laguerre–Gaussian (LG) beams. Theoretical derivations based on a density-matrix approach associated with numerical simulations are utilized to study the behaviors of the index of refraction, showing that the azimuthal and radial mode indices (i.e., l 2 and p 2) of the LG beams significantly affect the real and imaginary parts of the refractive index. To be specific, the number of the dispersive peaks is determined by (p 2 + 1) | l 2 | , and there are 2 | l 2 | lossless petals in conjunction with p 2 concentric absorption rings centered on the vortex center. Furthermore, by tuning the phase values of the electric and magnetic components of the electromagnetic field, the index of refraction can be drastically tuned from negative to zero to positive and accompanied by periodic absorption and amplification. This investigation provides a powerful tool for manipulating the index of refraction through a nonlinear interaction between atoms and the vortex beams and suggests potential applications in optical switching, logic gates, and optical storage with spatially varying refractive indices. [ABSTRACT FROM AUTHOR]

Published

2023

2. Controllable probe absorption spectrum via vortex beams excitation in a cascaded atomic system.

Author

Dai, Xiao, Hao, Xiangying, Jin, Rui-Bo, Peng, Chen, and Ding, Chunling

Subjects

ABSORPTION spectra, VECTOR beams, ATOMIC excitation, TRANSPARENCY (Optics), OPTICAL switches, OPTICAL vortices, ANGULAR momentum (Mechanics)

Abstract

Dynamic control of probe absorption spectrum via vortex beams in multilevel systems has attracted much attention because it provides an avenue to observe unique transport properties. In this paper, we employ experimentally accessible parameters to flexibly control the probe absorption spectrum that shows vortex-induced transparency (VIT) and absorption (VIA) phenomena. Specifically, this system can be served as an optical switch while the vortex beams can act as the control knob, which has the ability to switch from a transparency dip to an absorption peak. Differing from a conventional electromagnetically induced transparency technique, our proposed scheme investigates VIT and VIA by tuning the orbital angular momentum of vortex beams in the resonance and non-resonance cases. Moreover, the collective feature caused by constructive or destructive interference is also studied via adjustable frequency detuning. Our results may provide an efficient approach to study similar phenomena in multilevel quantum systems driven by optical vortex beams. [ABSTRACT FROM AUTHOR]

Published

2021

3. Witnessing entangled two-photon absorption via quantum interferometry.

Author

Martínez-Tapia, Áulide, Corona-Aquino, Samuel, Triana-Arango, Freiman, You, Chenglong, Jin, Rui-Bo, Magaña-Loaiza, Omar S., Dong, Shi-Hai, U'Ren, Alfred B., and León-Montiel, Roberto de J.

Subjects

QUANTUM networks (Optics), INTERFEROMETRY, ABSORPTION, INTERFEROMETERS, WITNESSES

Abstract

Recent investigations have suggested that the use of non-classical states of light, such as entangled photon pairs, may open new and exciting avenues in experimental two-photon absorption spectroscopy. Despite several experimental studies of entangled two-photon absorption (eTPA), there is still a heated debate on whether eTPA has truly been observed. This interesting debate has arisen mainly because it has recently been argued that single-photon-loss mechanisms, such as scattering or hot-band absorption, may mimic the expected entangled-photon linear absorption behavior. In this work, we focus on transmission measurements of eTPA and explore three different two-photon quantum interferometers in the context of assessing eTPA. We demonstrate that the so-called N00N-state configuration is the only one among those considered insensitive to linear (single-photon) losses. Remarkably, our results show that N00N states may become a potentially powerful tool for quantum spectroscopy, placing them as a strong candidate for the certification of eTPA in an arbitrary sample. [ABSTRACT FROM AUTHOR]

Published

2023

4. Two-photon spectral modulation via temporal manipulation: Quantum optical synthesis of spectral modes from temporal square waves.

Author

Jin, Rui-Bo, Oshima, Hiroki, Yagisawa, Takumi, Yabuno, Masahiro, Miki, Shigehito, China, Fumihiro, Terai, Hirotaka, and Shimizu, Ryosuke

Subjects

*SQUARE waves, *WAVE packets, *RADIANT intensity, *PHOTONS

Abstract

Precise manipulation of the time–frequency modes of entangled photons is crucial for future quantum science and technologies. Recently, the frequency-domain-quantum-optical-synthesis (FD-QOS) method was demonstrated by creating a superposition of different joint temporal amplitudes: those temporal distributions can be controlled by manipulating the joint spectral amplitude in 2D frequency space via a Fourier optical relation. This FD-QOS method provides an efficient, flexible, and easy-to-control way to precisely modulate the temporal distributions of the entangled photon in an ultrafast region. However, manipulation of only the temporal modes is not sufficient for various applications in quantum information, since spectral modulations are also needed on many occasions. Here, we present a proof-of-concept experiment of two-photon spectral modulation via temporal manipulation of a biphoton wave packet. This protocol, called time-domain-quantum-optical-synthesis (TD-QOS), is achieved by adjusting the relative phases between two joint temporal distributions. In addition, the two-photon joint spectral distributions are characterized by measuring the joint spectral intensities and Hong–Ou–Mandel interferences. The combination of FD-QOS and TD-QOS enables complete control over the biphoton states. Our work would further develop quantum technologies that rely on the time–frequency modes of entangled photons. [ABSTRACT FROM AUTHOR]

Published

2022

5. Quantum optical synthesis in 2D time–frequency space.

Author

Jin, Rui-Bo, Tazawa, Kurumi, Asamura, Naoto, Yabuno, Masahiro, Miki, Shigehito, China, Fumihiro, Terai, Hirotaka, Minoshima, Kaoru, and Shimizu, Ryosuke

Subjects

FOURIER transform optics, WAVE packets, PHOTON correlation, QUANTUM correlations, OPTICAL measurements, QUANTUM optics

Abstract

Conventional optical synthesis, the manipulation of the phase and amplitude of spectral components to produce an optical pulse in different temporal modes, is revolutionizing ultrafast optical science and metrology. These technologies rely on the Fourier transform of light fields between time and frequency domains in one-dimensional space. However, within this treatment, it is impossible to incorporate the quantum correlation among photons. Here, we expand the Fourier synthesis into high-dimensional space to deal with the quantum correlation and carry out an experimental demonstration by manipulating the two-photon probability distribution of a biphoton in two-dimensional time and frequency space. As a potential application, we show the manipulation of a heralded single-photon wave packet, which is never explained by the conventional one-dimensional Fourier optics. Our approach opens up a new pathway to tailor the temporal characteristics of a photon wave packet with high-dimensional quantum-mechanical treatment. We anticipate that such high-dimensional treatment of light in time and frequency domains could bridge the research fields between quantum optics and ultrafast optical measurements. [ABSTRACT FROM AUTHOR]

Published

2021

6. Intrinsic pure single-photon source and its nonclassical interference with weak coherent photons.

Author

Jin, Rui-Bo, Zhang, Jun, Shimizu, Ryosuke, Matsuda, Nobuyuki, Mitsumori, Yasuyoshi, Kosaka, Hideo, and Edamatsu, Keiichi

Subjects

*PHOTONS, *QUANTUM optics, *QUANTUM interference, *QUANTUM information science, *BANDPASS filters, *PHOTONICS, *AMPLITUDE modulation, *LIGHT filters

Abstract

We report the generation of pure single-photon state in the process of spontaneous parametric down-conversion with extended phase-matching condition. The measured joint spectral distribution of the photon pairs shows a high purity of the state we prepared. A visibility of 89.4± 0.5% was achieved without any spectral filtering in a nonclassical Hong-Ou-Mandel interference between pure heralded single photons and weak coherent photons. [ABSTRACT FROM AUTHOR]

Published

2011