Experimental demonstration of spinor slow light

Lee, Meng-Jung; Ruseckas, Julius; Lee, Chin-Yuan; Kudriašov, V.; Chang, Kao-Fang; Cho, Hung-Wen; Juzeliūnas, Gediminas; Yu, Ite A.

doi:10.1117/12.2220197

Cited by 7 publications

(8 citation statements)

References 65 publications

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“…Recently, controllable beam splitting in frequency or time modes has been demonstrated by using the gradient echo memory scheme [15], with a double-tripod EIT scheme [16], and with a tripod EIT scheme [17]. Dynamic beam splitting in the spatial modes which functions as a variable beam splitter [18], however, has not been implemented in a long-coherence atomic medium.…”

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confidence: 99%

Coherent and dynamic beam splitting based on light storage in cold atoms

Park

Zhao

Lee

et al. 2016

Sci Rep

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We demonstrate a coherent and dynamic beam splitter based on light storage in cold atoms. An input weak laser pulse is first stored in a cold atom ensemble via electromagnetically-induced transparency (EIT). A set of counter-propagating control fields, applied at a later time, retrieves the stored pulse into two output spatial modes. The high visibility interference between the two output pulses clearly demonstrates that the beam splitting process is coherent. Furthermore, by manipulating the control lasers, it is possible to dynamically control the storage time, the power splitting ratio, the relative phase, and the optical frequencies of the output pulses. With further improvements, the active beam splitter demonstrated in this work might have applications in photonic photonic quantum information and in all-optical information processing.

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confidence: 99%

Coherent and dynamic beam splitting based on light storage in cold atoms

Park

Zhao

Lee

et al. 2016

Sci Rep

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“…1 F = 2, m F = 2 , the Rydberg state |32D 5/2 , m J = 5/2 , and the excited state |5P 3/2 , F = 3, m F = 3 of 87 Rb atoms, respectively. We prepared all population in a single Zeeman state |5S 1/2 , F = 2, m F = 2 by optical pumping [32]. In the experiment, the σ +polarized probe and coupling fields were used.…”

Section: Observation Of the Accumulation Effectmentioning

confidence: 99%

Increasing decoherence rate of Rydberg polaritons due to accumulating dark Rydberg atoms

Chen,

Kim,

et al. 2021

Preprint

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We experimentally observed an accumulative type of nonlinear attenuation and distortion of slow light in a laser-cooled electromagnetically-induced-transparency (EIT) medium with the Rydberg state of |32D 5/2 . The present effect of attenuation and distortion was caused by the dipole-dipole interaction between Rydberg atoms in a weak-interaction regime, i.e., the mean distance between Rydberg atoms was far greater than the dipole blockade radius. Our observation can be attributed to the atoms self-accumulated in dark Rydberg states other than those in the bright Rydberg state |32D 5/2 driven by the coupling field. We performed three different experiments to verify the above hypothesis, to confirm the existence of the dark Rydberg states, and to measure the decay rate from the bright to dark Rydberg states. In the theoretical model, we included the decay process from the bright to dark Rydberg states and the DDI effect induced by both the bright and dark Rydberg atoms. All the experimental data of slow light taken at various probe Rabi frequencies were in good agreement with the theoretical predictions based on the model. The systematic study presented in this work provides a better understanding of the Rydberg-EIT system.

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“…Recently, a highly efficient quantum memory protocol based on EIT has been experimentally demonstrated for cold rubidium [ 13 ] and cesium atoms [ 14 ]. Experimental evidence of spinor slow light as a quantum memory for two-color qubits in cold rubidium has also been presented [ 15 ].…”

Section: Introductionmentioning

confidence: 99%

Electromagnetically Induced Transparency in Media with Rydberg Excitons 1: Slow Light

Ziemkiewicz

2020

Entropy

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In this paper, we show that Electromagnetically Induced Transparency (EIT) can be realized in mediums with Rydberg excitons. With realistic, reliable parameters which show good agreement with optical and electro-optical experiments, as well as the proper choice of Rydberg exciton states in the Cu2O crystal, we indicate how the EIT can be performed. The calculations show that, due to a large group index, one can expect the slowing down of a light pulse by a factor of about 10 4 in this medium.

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Experimental demonstration of spinor slow light

Cited by 7 publications

References 65 publications

Coherent and dynamic beam splitting based on light storage in cold atoms

Coherent and dynamic beam splitting based on light storage in cold atoms

Increasing decoherence rate of Rydberg polaritons due to accumulating dark Rydberg atoms

Electromagnetically Induced Transparency in Media with Rydberg Excitons 1: Slow Light

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