Effect of Dispersive Reﬂectivity on the Dynamics of Interacting Solitons

in Dual-Core Systems with Separated Bragg Grating and Nonlinearity

Tanvir Ahmed and Javid Atai

School of Electrical and Information Engineering, The University of Sydney, NSW 2006, Sydney, Australia

Keywords:

Gap Soliton, Fiber Bragg Grating, Dispersive Reﬂectivity.

Abstract:

The interactions of in-phase and π-out-of-phase quiescent Bragg grating solitons in a dual-core system where

one core has Kerr nonlinearity and other is linear and has a Bragg grating with dispersive reﬂectivity are

systematically investigated. The effect of dispersive reﬂectivity on the outcomes of the interactions is analyzed.

It is found that above a certain value of dispersive reﬂectivity solitons develop sidelobes. The presence of

sidelobes has a signiﬁcant effect on the outcomes of the interactions. In the absence of sidelobes, in-phase

soliton-soliton interactions may result in several outcomes such as merger into a quiescent soliton, symmetric

or asymmetric separation of solitons or destruction of both solitons. However, the interaction of solitons in the

presence of sidelobes produces other outcomes such as repulsion of solitons or formaion of a temporary bound

state followed by separation of two solitons. π-out-of-phase solitons generally repel each other. However, in

the presence of sidelobes, interactions of π-out-of-phase solitons may lead to the formation of temporary

bound state and subsequent generation of two separating solitons.

1 INTRODUCTION

A key characteristic of ﬁber Bragg gratings (FBGs)

is that they exhibit strong effective dispersion due to

resonant reﬂection of light. This effective dispersion

can be six orders of magnitude larger than the chro-

matic dispersion of silica ﬁber (de Sterke and Sipe,

1994; Eggleton et al., 1997). The interplay of FBG-

induced dispersion and Kerr nonlinearity gives rise

to the formation of gap solitons (GSs). Over the

past few decades, gap solitons have been investigated

extensively both theoretically (Aceves and Wabnitz,

1989; Christodoulides and Joseph, 1989; Malomed

and Tasgal, 1994; Barashenkov et al., 1998; De Rossi

et al., 1998; Neill and Atai, 2006) and experimen-

tally (Eggleton et al., 1996; de Sterke C. M. and

Krug, 1997; Eggleton et al., 1999) due to their po-

tential applications in optical signal processing, opti-

cal buffer elements and logic gates (Krauss, 2008). A

major property of gap solitons is that they can pos-

sess any velocity from zero (quiescent) to the speed

of light in the medium. To date, gap solitons with

a velocity in excess of 23% of the speed of light in

the medium have been observed experimentally (Mok

et al., 2006).

Gap solitons have been studied in more complex

media and structures such as photonic crystals (Monat

et al., 2010; Skryabin, 2004; Neill and Atai, 2007),

quadratic nonlinearity (Mak et al., 1998b; Conti et al.,

1997; He and Drummond, 1997), waveguide ar-

rays (Mandelik et al., 2004; Tan et al., 2009; Dong

et al., 2011), dual core ﬁbers (Atai and Malomed,

2000; Atai and Malomed, 2001; Mak et al., 1998a;

Tsofe and Malomed, 2007), and Bragg gratings (BGs)

with dispersive reﬂectivity (Atai and Malomed, 2005;

Neill et al., 2008). Dual-core nonlinear couplers with

dissimilar cores exhibit rich nonlinear dynamics and

switching characteristics (Atai and Chen, 1992; Atai

and Chen, 1993; Atai and Malomed, 1998). There-

fore, slow GSs in grating-assisted couplers can be ex-

ploited to build novel optical devices for signal pro-

cessing and switching.

In this paper, we investigate the effect of disper-

sive reﬂectivity on the interaction dynamics of gap

solitons in a dual-core ﬁber where one core has only

Kerr nonlinearity and the other core is linear and is

equipped with a BG with dispersive reﬂectivity.

2 THE MODEL

Propagation of light in a dual-core ﬁber where one

core has only Kerr nonlinearity and other one is linear

and contains a BG with dispersive reﬂectivity is de-

Ahmed T. and Atai J.

Effect of Dispersive Reﬂectivity on the Dynamics of Interacting Solitons in Dual-Core Systems with Separated Bragg Grating and Nonlinearity.

DOI: 10.5220/0006099000490053

In Proceedings of the 5th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS 2017), pages 49-53

ISBN: 978-989-758-223-3

-80 -40 0 40 80

2000

(a)

-80 -40 0 40 80

4000

(b)

-36

-18 0 18

4000

(c)

-64

-32 0 32

4000

(d)

Figure 1: Examples of the outcomes of soliton-soliton interaction for in-phase quiescent solitons without sidelobes for λ = 1.0,

c = 0.2 and △x= 12. (a) Destruction for ω = 1.570, m = 0.020 (b) Merger for ω = 1.610, m = 0.060 (c) Symmetric separation

for ω = 1.570, m = 0.160 (d) Asymmetric separation for ω = 1.590, m = 0.260. Only |u| component is shown here.

scribed by the following set of normalized equations:

+ iu



|v|

|u|



u+ φ = 0,

− iv



|u|

|v|



v+ ψ = 0,

iφ

+ icφ

+ u + λψ+ mψ

= 0,

iψ

− icψ

+ v + λφ+ mφ

= 0,

(1)

where u(x,t) and v(x, t) are the forward- and

backward-propagating waves in the nonlinear core,

and φ(x, t) and ψ(x,t) are their counterparts in the

linear core which is equipped with a Bragg grating.

The coefﬁcient of linear coupling between the cores

is normalized to 1 and the FBG-induced linear cou-

pling coefﬁcient between the forward- and backward-

propagating waves is represented by a real parameter

λ > 0. The group velocity in the nonlinear core is

set equal to 1 and c represents the relative group ve-

locity in the linear core. The real parameter m > 0

controls the strength of dispersive reﬂectivity. Sub-

stituting u, v, φ, ψ ∼ exp(ikx− iωt) into Eqs. (1) and

linearizing results in the following form of dispersion

relation:

−





λ− mk





1+ c







λk− mk





− 1



= 0 (2)

The dispersion relation results a genuine central

band gap along with upper and lower band gaps

(which are not genuine band gaps). No stationary

solutions are available in the central bang gap. The

soliton solutions are sought numerically in both up-

per and lower band gaps by relaxation algorithm in

the range 0 ≤ m ≤ 0.5.

PHOTOPTICS 2017 - 5th International Conference on Photonics, Optics and Laser Technology

3 INTERACTIONS OF GAP

SOLITONS

We have investigated the interactions between two

identical stable quiescent GSs by numerically solv-

ing Eqs. (1) using a symmetrized split-step Fourier

method for in-phase and π-out-of-phase solitons sub-

ject to the following initial conditions:

u(x, 0) = u



x−

△x

, 0



+ u



△x

, 0



exp(i△θ),

v(x, 0) = v



x−

△x

, 0



+ v



△x

, 0



exp(i△θ),

φ(x, 0) = φ



x−

△x

, 0



+ φ



△x

, 0



exp(i△θ),

ψ(x, 0) = ψ



x−

△x

, 0



+ ψ



△x

, 0



exp(i△θ),

(3)

where △x and △θ represent the initial separa-

tion and phase difference between the solitons respec-

tively, and u, v, φ and ψ belong to the stable regions.

As is shown in Fig. 1, for the in-phase solitons, the

interactions may result in several outcomes such as

merger into a single soliton, destruction of both soli-

tons, symmetric and asymmetric separation of soli-

tons for low to moderate values of dispersive reﬂec-

tivity. Fig. 2 summarizes the outcomes of in-phase

and π-out-of-phase soliton-soliton interactions in the

upper bandgap in the plane (m, ω) for λ = 1, c = 0.2

and initial separation of ∆x = 12. The simulations

demonstrate that the outcomes of interactions are sig-

niﬁcantly inﬂuenced by strong dispersive reﬂectivity.

This is mainly due to the fact that beyond a certain

value of m (i.e. the region to the right of the dash-

dotted curve in Fig. 2) solitons develop sidelobes.

The presence of sidelobes drastically alters the in-

teraction dynamics. As is shown in Fig. 2(a), the

bound state formation and repulsion are generally ob-

served when sidelobes are present. Typical examples

of repulsion and formation a temporary bound state

followed by generation of two separating solitons are

shown in Fig 3(a) and 3(b), respectively.

In the case of π-out-of-phase solitons, in the ab-

sence of sidelobes solitons repel each other (see Fig.

2(b)). However, when solitons have sidelobes the in-

teractions may also result in the formation of a bound

state followed by two separating solitons. Figs. 3(c)

and 3(d) respectively show examples of repulsion and

formation of a bound state followed by generation of

two moving solitons for initially π-out-of-phase soli-

tons.

0.25 0.5

1.50

1.55

1.6

1.618

(a)

0.25 0.5

1.50

1.55

1.6

1.618

(b)

Figure 2: The outcomes of soliton-soliton interactions for

λ = 1.0, c = 0.2 and △x = 12 in the upper bandgap for

(a) in-phase and (b) π−out-of-phase solitons on the (m, ω)

plane. The labeled regions are merger (M), symmetric sep-

aration (S), asymmetric separation (A), destruction (D), re-

pulsion (R), and formation of bound state followed by sepa-

ration (B). In the region U, GSs are unstable. GSs have side-

lobes in the region to the right of the dashed-dotted curve.

4 CONCLUSIONS

The interaction dynamics of quiescent Bragg grating

solitons are investigated in a systematic way to test

the effect of dispersive reﬂectivity in a dual-core sys-

tem where one core contains Kerr nonlinearity and an-

other core is equipped with a Bragg grating and dis-

persive reﬂectivity. It is found that, for low to moder-

ate dispersive reﬂectivity (i.e. in the absence of side-

lobes), in-phase quiescent Bragg grating solitons at-

tract each other and generate different outcomes such

as merger into a quiescent soliton, separation of soli-

tons with equal and unequal velocities after initial at-

traction or destruction of both solitons. For high dis-

Effect of Dispersive Reﬂectivity on the Dynamics of Interacting Solitons in Dual-Core Systems with Separated Bragg Grating and

Nonlinearity

-50 -25

25 50

(a)

4000

-34 -17 0 17 34

6000

(b)

-80 -40 0 40 80

5000

(c)

-40 -20 0 20 40

15000

(d)

Figure 3: Examples of the outcomes of soliton-soliton interaction for λ = 1.0, c = 0.2 and △x = 12 for solitons with sidelobes.

(a) Repulsion for ∆θ = 0, ω = 1.590, m = 0.360, (b) Formation of temporary bound state followed by separation for ∆θ = 0,

ω = 1.590, m = 0.420, (c) Repulsion for ∆θ = π, ω = 1.601, m = 0.280 and (d) Formation of a bound state followed by

separating solitons for ∆θ = π, ω = 1.610, m = 0.380. Only |u| component is shown here.

persive reﬂectivity solitons have side-lobes in their

proﬁle. The presence of sidelobes signiﬁcantly af-

fects the interaction dynamics. In particular, in-phase

solitons with sidelobes may repel each other or form

of a temporary bound state followed by generation of

two separating solitons. In the case of π-out-of-phase

solitons, solitons without sidelobes always repel each

other. However, in the region where solitons have

sidelobes, the interactions may also give rise to the

formation of a bound state that subsequently evolves

in to two separating solitons.

REFERENCES

Aceves, A. B. and Wabnitz, S. (1989). Self-induced trans-

parency solitons in nonlinear refractive periodic me-

dia. Phys. Lett. A, 141(1):37–42.

Atai, J. and Chen, Y. (1992). Nonlinear couplers composed

of different nonlinear cores. J. Appl. Phys., 72(1):24–

27.

Atai, J. and Chen, Y. (1993). Nonlinear mismatches be-

tween two cores of saturable nonlinear couplers. IEEE

J. Quantum Electron., 29(1):242–249.

Atai, J. and Malomed, B. A. (1998). Bound states of soli-

tary pulses in linearly coupled Ginzburg-Landau equa-

tions. Phys. Lett. A, 244:551–556.

Atai, J. and Malomed, B. A. (2000). Bragg-grating soli-

tons in a semilinear dual-core system. Phys. Rev. E,

62(6):8713–8718.

Atai, J. and Malomed, B. A. (2001). Solitary waves in sys-

tems with separated bragg grating and nonlinearity.

Physical Rev. E, 64(6 Pt 2):066617.

Atai, J. and Malomed, B. A. (2005). Gap solitons in bragg

gratings with dispersive reﬂectivity. Phys. Lett. A,

342(5):404–412.

PHOTOPTICS 2017 - 5th International Conference on Photonics, Optics and Laser Technology

Barashenkov, I. V., Pelinovsky, D. E., and Zemlyanaya,

E. V. (1998). Vibrations and oscillatory instabilities

of gap solitons. Phys. Rev. Lett., 80(23):5117–5120.

Christodoulides, D. N. and Joseph, R. I. (1989). Slow bragg

solitons in nonlinear periodic structures. Phys. Rev.

Lett., 62(15):1746–1749.

Conti, C., Trillo, S., and Assanto, G. (1997). Doubly res-

onant Bragg simultons via second-harmonic genera-

tion. Phys. Rev. Lett., 78:2341–2344.

De Rossi, A., Conti, C., and Trillo, S. (1998). Stability,

multistability, and wobbling of optical gap solitons.

Phys. Rev. Lett., 81(1):85–88.

de Sterke, C. M. and Sipe, J. E. (1994). Gap solitons.

Progress in Optics, 33:203–260.

de Sterke C. M., Eggleton, B. J. and Krug, P. A. (1997).

High-intensity pulse propagation in uniform gratings

and grating superstructures. J. Lightwave Technol.,

15(8):1494–1502.

Dong, R., R¨uter, C. E., Kip, D., Cuevas, J., Kevrekidis,

P. G., Song, D., and Xu, J. (2011). Dark-bright gap

solitons in coupled-mode one-dimensional saturable

waveguide arrays. Phys. Rev. A, 83(6):063816.

Eggleton, B. J., de Sterke, C. M., and Slusher, R. E. (1997).

Nonlinear pulse propagation in bragg gratings. J. Opt.

Soc. Am. B, 14(11):2980–2993.

Eggleton, B. J., de Sterke, C. M., and Slusher, R. E. (1999).

Bragg solitons in the nonlinear schr¨odinger limit: ex-

periment and theory. J. Opt. Soc. Am B, 16(4):587–

599.

Eggleton, B. J., Slusher, R. E., Krug, P. A., and Sipe, J. E.

(1996). Bragg grating solitons. Phys. Rev. Lett.,

76(10):1627–1630.

He, H. and Drummond, P. D. (1997). Ideal soliton envi-

ronment using parametric band gaps. Phys. Rev. Lett.,

78:4311–4315.

Krauss, T. F. (2008). Why do we need slow light? Nature

Photonics, 2(8):448–450.

Mak, W. C. K., Chu, P. L., and Malomed, B. A. (1998a).

Solitary waves in coupled nonlinear waveguides with

bragg gratings. J. Opt. Soc. Am. B, 15(6):1685–1692.

Mak, W. C. K., Malomed, and Chu, P. L. (1998b).

Asymmetric solitons in coupled second-harmonic-

generating waveguides. Phys. Rev. E, 57:1092–1103.

Malomed, B. A. and Tasgal, R. S. (1994). Vibration modes

of a gap soliton in a nonlinear optical medium. Phys.

Rev. E, 49(6):5787–5796.

Mandelik, D., Morandotti, R., Aitchison, J. S., and Silber-

berg, Y. (2004). Gap solitons in waveguide arrays.

Phys. Rev. Lett., 92(9):093904.

Mok, J. T., de Sterke, C. M., Littler, I. C. M., and Eggle-

ton, B. J. (2006). Dispersionless slow light using gap

solitons. Nature Phys., 2(11):775–780.

Monat, C., de Sterke, M., and Eggleton, B. J. (2010). Slow

light enhanced nonlinear optics in periodic structures.

J. Opt., 12:104003.

Neill, D. R. and Atai, J. (2006). Collision dynamics of gap

solitons in kerr media. Phys. Lett. A, 353(5):416–421.

Neill, D. R. and Atai, J. (2007). Gap solitons in a hollow

optical ﬁber in the normal dispersion regime. Phys.

Lett. A, 367(1-2):73–82.

Neill, D. R., Atai, J., and Malomed, B. A. (2008). Dynam-

ics and collisions of moving solitons in bragg gratings

with dispersive reﬂectivity. J. Opt. A: Pure Appl. Opt.,

10:085105.

Skryabin, D. V. (2004). Coupled core-surface solitons in

photonic crystal ﬁbers. Opt. Express, 12(20):4841–

4846.

Tan, Y., Chen, F., Beliˇcev, P. P., Stepi´c, M., Maluckov, A.,

R¨uter, C. E., and Kip, D. (2009). Gap solitons in de-

focusing lithium niobate binary waveguide arrays fab-

ricated by proton implantation and selective light illu-

mination. Appl. Phys. B, 95(3):531–535.

Tsofe, Y. J. and Malomed, B. A. (2007). Quasisymmet-

ric and asymmetric gap solitons in linearly coupled

Bragg gratings with a phase shift. Phys. Rev. E, 75(5

Pt 2):056603.

Effect of Dispersive Reﬂectivity on the Dynamics of Interacting Solitons in Dual-Core Systems with Separated Bragg Grating and

Nonlinearity