Stable numerical schemes for nonlinear dispersive equations with counter-propagation and gain dynamics

Chang Sun; Niall Mangan; Mark Dong; Herbert G. Winful; Steven T. Cundiff; J. Nathan Kutz

doi:10.1364/JOSAB.36.003263

Journal of the Optical Society of America B
Vol. 36,
Issue 12,
pp. 3263-3274
(2019)
•https://doi.org/10.1364/JOSAB.36.003263

Stable numerical schemes for nonlinear dispersive equations with counter-propagation and gain dynamics

Chang Sun, Niall Mangan, Mark Dong, Herbert G. Winful, Steven T. Cundiff, and J. Nathan Kutz

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Chang Sun, Niall Mangan, Mark Dong, Herbert G. Winful, Steven T. Cundiff, and J. Nathan Kutz, "Stable numerical schemes for nonlinear dispersive equations with counter-propagation and gain dynamics," J. Opt. Soc. Am. B 36, 3263-3274 (2019)

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- Ultrafast Optics
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About this Article
History
- Original Manuscript: June 27, 2019
- Revised Manuscript: October 2, 2019
- Manuscript Accepted: October 3, 2019
- Published: November 11, 2019

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Abstract

We develop a stable and efficient numerical scheme for modeling the optical field evolution in a nonlinear dispersive cavity with counter-propagating waves and complex, semiconductor physics gain dynamics that is expensive to evaluate. Our stability analysis is characterized by a von Neumann analysis that shows that many standard numerical schemes are unstable due to competing physical effects in the propagation equations. We show that the combination of a predictor–corrector scheme with an operator splitting not only results in a stable scheme, but also provides a highly efficient, single-stage evaluation of the gain dynamics. Given that the gain dynamics is the rate-limiting step of the algorithm, our method circumvents the numerical instability induced by the other cavity physics when evaluating the gain in an efficient manner. We demonstrate the stability and efficiency of the algorithm on a diode laser model that includes three waveguides and semiconductor gain dynamics. The laser is able to produce a repeating temporal waveform and stable optical comb lines, thus demonstrating that frequency comb generation may be possible in chip-scale, diode lasers.

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Symbol	Description	Value
$L$	Length of device	500 µm
$W$	Width of waveguide	4 µm
$h_{sch}$	Height of SCH layer	50 nm
$h_{qw}$	Height of quantum well	5 nm
$n_{0}$	Group refractive index	3.5
$n_{qw}$	Number of quantum wells	2
$α$	Intrinsic waveguide loss	5 ${cm}^{- 1}$
$Γ_{x y}$	Optical confinement factor	0.02
$α_{S}$	Two-photon absorption	$580 W^{- 1} m^{- 1}$
$β_{S}$	Kerr coefficient	$430 W^{- 1} m^{- 1}$
$ℏ ω_{0}$	Central transition energy	1.55 eV
$\| \hat{e} \cdot p \|^{2}$	Momentum matrix element	$25 meV \times m_{0} / 6$
$Γ$	Homogenous half-linewidth	$11 meV / ℏ$
$m_{e, sch}^{*}$	Effective mass of electrons in SCH layer	$0.125 m_{0}$
$m_{h, sch}^{*}$	Effective mass of holes in SCH layer	$0.703 m_{0}$
$m_{e, qw}^{*}$	Effective mass of electrons in GaAs QW	$0.093 m_{0}$
$m_{h, qw}^{*}$	Effective mass of holes in GaAs QW	$0.53 m_{0}$
$τ_{c}^{e, h, qw}$	Electron, hole capture time	1, 10 ps
$δ E_{c}$	Conduction band quantum well barrier	50 meV
$δ E_{v}$	Valence band quantum well barrier	25 meV
$β_{sp}$	Spontaneous emission coupling factor	$1 \times 10^{- 4}$
$τ_{sp}$	Spontaneous emission lifetime	1 ns
$D$	Ambipolar diffusion coefficient	$20 {cm}^{2} / s$

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Journal of the Optical Society of America B