Feng Wen scite author profile

We demonstrate Autler-Townes (AT) splitting of four-wave mixing in an electromagnetically induced transparency window, which results from the destructive interference between a three-photon process and a five-photon process. The primary and secondary AT splittings are achieved via induced atomic coherence in a four-level Y-type atomic system. Theoretical calculations fit well with the experimentally measured results. Such controlled multichannel splitting of nonlinear optical signals can have potential applications in optical communication and quantum information processing.

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Two-dimensional photonic crystals with large complete photonic band gaps in both TE and TM polarizations

Wen¹,

David²,

Checoury³

et al. 2008

Opt. Express

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Photonic crystals exhibiting a photonic band gap in both TE and TM polarizations are particularly interesting for a better control of light confinement. The simultaneous achievement of large band gaps in both polarizations requires to reduce the symmetry properties of the photonic crystal lattice. In this letter, we propose two different designs of two-dimensional photonic crystals patterned in high refractive index thin silicon slabs. These slabs are known to limit the opening of photonic band gaps for both polarizations. The proposed designs exhibit large complete photonic band gaps: the first photonic crystal structure is based on the honey-comb lattice with two different hole radii and the second structure is based on a "tri-ellipse" pattern in a triangular lattice. Photonic band gap calculations show that these structures offer large complete photonic band gaps deltaomega/omega larger than 10% between first and second photonic bands. This figure of merit is obtained with single-mode slab waveguides and is not restricted to modes below light cone.

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Cubic-quintic condensate solitons in four-wave mixing

Zhang

Yuan

et al. 2013

Phys. Rev. A

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We experimentally investigate the two-dimensional condensate (optical dropletlike) soliton formation and dynamics of the generated signal and probe beams in four-wave mixing (FWM) process with atomic coherence, under competition between the third-and fifth-order nonlinear susceptibilities. With such competing nonlinearities, mutual transformations among dropletlike fundamental, dipole, and azimuthally modulated vortex FWM solitons are observed. The influence of nonlinear competition on the photonic band gap is also investigated. All the results are obtained under low powers.

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Controlled Correlation and Squeezing in Pr3+:Y2SiO5 to Yi

Jiang

Zhang

et al. 2017

Phys. Rev. Applied

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Three-dimensional supercritical resolved light-induced magnetic holography

Hao

Nie

et al. 2017

Sci. Adv.

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Feng Wen

Evidence of Autler–Townes splitting in high-order nonlinear processes

Two-dimensional photonic crystals with large complete photonic band gaps in both TE and TM polarizations

Cubic-quintic condensate solitons in four-wave mixing

Controlled Correlation and Squeezing in Pr3+:Y2SiO5 to Yi

Three-dimensional supercritical resolved light-induced magnetic holography

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