Flat-top supercontinuum generation via Gaussian pulse shaping

Minje Song; Sang Pil Han; Jaegyu Park; Hyunjong Choi; Sungil Kim; Thanh Tuan Tran; Hyun Deok Kim; Minhyup Song

doi:10.1364/OE.421876

Flat-top supercontinuum generation via Gaussian pulse shaping

Minje Song, Sang Pil Han, Jaegyu Park, Hyunjong Choi, Sungil Kim, Thanh Tuan Tran, Hyun Deok Kim, Minhyup Song

School of Electronics Engineering

Research output: Contribution to journal › Article › peer-review

32 Scopus citations

Abstract

We present the flat-top supercontinuum source with high repetition rate over a broad bandwidth. The flatness and high repetition rate are achieved by iterative optical line-by-line spectrum shaping on electro-optic optical frequency combs. By applying Gaussian apodized pulse train to a highly nonlinear medium with optimized Gaussian coefficient and nonlinear polarization rotation techniques, we implemented here a flat-top supercontinuum with a 47.7 nm bandwidth at 3 dB and 30 GHz repetition rate. The generation of high repetition rate supercontinuum sources with smooth and coherent spectrum is the critical challenging task for many applications such as optical communications and the optical arbitrary waveform generation. This work leads us to new possibilities for generating hundreds or thousands of flattened coherent optical carriers with a simple configuration.

Original language	English
Pages (from-to)	12001-12009
Number of pages	9
Journal	Optics Express
Volume	29
Issue number	8
DOIs	https://doi.org/10.1364/OE.421876
State	Published - 12 Apr 2021

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title = "Flat-top supercontinuum generation via Gaussian pulse shaping",

abstract = "We present the flat-top supercontinuum source with high repetition rate over a broad bandwidth. The flatness and high repetition rate are achieved by iterative optical line-by-line spectrum shaping on electro-optic optical frequency combs. By applying Gaussian apodized pulse train to a highly nonlinear medium with optimized Gaussian coefficient and nonlinear polarization rotation techniques, we implemented here a flat-top supercontinuum with a 47.7 nm bandwidth at 3 dB and 30 GHz repetition rate. The generation of high repetition rate supercontinuum sources with smooth and coherent spectrum is the critical challenging task for many applications such as optical communications and the optical arbitrary waveform generation. This work leads us to new possibilities for generating hundreds or thousands of flattened coherent optical carriers with a simple configuration.",

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AU - Song, Minje

AU - Han, Sang Pil

AU - Park, Jaegyu

AU - Choi, Hyunjong

AU - Kim, Sungil

AU - Tran, Thanh Tuan

AU - Kim, Hyun Deok

AU - Song, Minhyup

PY - 2021/4/12

Y1 - 2021/4/12

N2 - We present the flat-top supercontinuum source with high repetition rate over a broad bandwidth. The flatness and high repetition rate are achieved by iterative optical line-by-line spectrum shaping on electro-optic optical frequency combs. By applying Gaussian apodized pulse train to a highly nonlinear medium with optimized Gaussian coefficient and nonlinear polarization rotation techniques, we implemented here a flat-top supercontinuum with a 47.7 nm bandwidth at 3 dB and 30 GHz repetition rate. The generation of high repetition rate supercontinuum sources with smooth and coherent spectrum is the critical challenging task for many applications such as optical communications and the optical arbitrary waveform generation. This work leads us to new possibilities for generating hundreds or thousands of flattened coherent optical carriers with a simple configuration.

AB - We present the flat-top supercontinuum source with high repetition rate over a broad bandwidth. The flatness and high repetition rate are achieved by iterative optical line-by-line spectrum shaping on electro-optic optical frequency combs. By applying Gaussian apodized pulse train to a highly nonlinear medium with optimized Gaussian coefficient and nonlinear polarization rotation techniques, we implemented here a flat-top supercontinuum with a 47.7 nm bandwidth at 3 dB and 30 GHz repetition rate. The generation of high repetition rate supercontinuum sources with smooth and coherent spectrum is the critical challenging task for many applications such as optical communications and the optical arbitrary waveform generation. This work leads us to new possibilities for generating hundreds or thousands of flattened coherent optical carriers with a simple configuration.

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Flat-top supercontinuum generation via Gaussian pulse shaping

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