Evolution of Sommerfeld and Brillouin precursors in intermediate spectral regimes

Heejeong Jeong; Ulf L. Österberg; Tobias Hansson

doi:10.1364/JOSAB.26.002455

Journal of the Optical Society of America B
Vol. 26,
Issue 12,
pp. 2455-2460
(2009)
•https://doi.org/10.1364/JOSAB.26.002455

Evolution of Sommerfeld and Brillouin precursors in intermediate spectral regimes

Heejeong Jeong, Ulf L. Österberg, and Tobias Hansson

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Heejeong Jeong, Ulf L. Österberg, and Tobias Hansson, "Evolution of Sommerfeld and Brillouin precursors in intermediate spectral regimes," J. Opt. Soc. Am. B 26, 2455-2460 (2009)

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Related Topics
Table of Contents Category
- Fourier Optics and Signal Processing
Optics & Photonics Topics
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The topics in this list come from the Optics and Photonics Topics applied to this article.
Previously assigned OCIS codes
- Coherent optical effects (020.1670)
- Ultrafast processing (070.7145)
- Wave propagation (070.7345)
- Ultrafast phenomena (320.7120)

About this Article
History
- Original Manuscript: July 8, 2009
- Revised Manuscript: October 8, 2009
- Manuscript Accepted: October 10, 2009
- Published: November 30, 2009

Abstract

We study, numerically, the transitional behavior of precursors in the intermediate spectral regime between two contrasting regimes for which analytical solutions exist. The two opposite regimes are, respectively, defined as (1) off-resonance carrier with a spectral pulse width comparable to the medium’s absorption linewidth and (2) on-resonance carrier with the spectral width of the pulse much narrower than the absorption linewidth. Beyond these two regimes, there have been few studies of precursors. In this paper, we investigate precursor dynamics for the intermediate spectral regime using the finite-difference time domain method. The parameter that has the strongest influence on the precursor dynamics is found to be the plasma frequency, $ω_{p}$ . This research is applicable for controlling transients in fast communication systems.

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Symbol	Brillouin Regime [1]	Intermediate Regime	Resonant Regime [3]
$ω_{c}$	$0.25 ω_{0}$	$0.625 ω_{0}$	$ω_{0}$
δ	$0.07 ω_{0}$	$0.035 ω_{0}$	$0.007 ω_{0}$
$ω_{p}$	$1.1175 ω_{0}$	$0.2 ω_{0}$	$0.02 ω_{0}$

Parameters	$t_{B}$ [fs] [Eq. (3)] (FDTD)	$t_{chirp}^{S}$ [fs] [Eq. (5)]	$t_{chirp}^{B}$ [fs] [Eq. (6)]
Brillouin Regime	49.85 (46.75)	87.04	170.09
$δ = 0.035 ω_{0}$	49.95 (46.97)	87.69	168.32
$δ = 0.007 ω_{0}$	49.98 (47.31)	87.90	167.78
$ω_{p} = 0.2 ω_{0}$	34.00 (33.36)	33.80	44.75
$ω_{p} = 0.02 ω_{0}$	33.34 (33.36)	33.34	33.47

Parameters	$t_{B}$ [fs] [Eq. (3)] (FDTD)	$t_{chirp}^{S}$ [fs] [Eq. (5)]	$t_{chirp}^{B}$ [fs] [Eq. (6)]
Resonant Regime	33.34 (33.35)	33.34	33.46
$δ = 0.07 ω_{0}$	33.34 (33.35)	33.34	33.47
$δ = 0.035 ω_{0}$	33.34 (33.35)	33.34	33.46
$ω_{p} = 1.1175 ω_{0}$	49.99 (48.27)	87.90	167.78
$ω_{p} = 0.2 ω_{0}$	33.99 (33.88)	33.80	44.47

Symbol	Brillouin Regime [1]	Intermediate Regime	Resonant Regime [3]
$ω_{c}$	$0.25 ω_{0}$	$0.625 ω_{0}$	$ω_{0}$
δ	$0.07 ω_{0}$	$0.035 ω_{0}$	$0.007 ω_{0}$
$ω_{p}$	$1.1175 ω_{0}$	$0.2 ω_{0}$	$0.02 ω_{0}$

Parameters	$t_{B}$ [fs] [Eq. (3)] (FDTD)	$t_{chirp}^{S}$ [fs] [Eq. (5)]	$t_{chirp}^{B}$ [fs] [Eq. (6)]
Brillouin Regime	49.85 (46.75)	87.04	170.09
$δ = 0.035 ω_{0}$	49.95 (46.97)	87.69	168.32
$δ = 0.007 ω_{0}$	49.98 (47.31)	87.90	167.78
$ω_{p} = 0.2 ω_{0}$	34.00 (33.36)	33.80	44.75
$ω_{p} = 0.02 ω_{0}$	33.34 (33.36)	33.34	33.47

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