Solitons in a Dual-core System with a Uniform Bragg Grating

and a Bragg Grating with Dispersive Reﬂectivity

Bellal Hossain and Javid Atai

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

Keywords:

Gap Soliton, Kerr Nonlinearity, Dispersive Reﬂectivity.

Abstract:

The existence and stability of gap solitons in a dual-core optical ﬁber made of a uniform and a nonuniform

Bragg grating with Kerr nonlinearity are considered. The nonuniformity in the one of the cores originates

from the presence of dispersive reﬂectivity. It is found that quiescent soliton solutions exist throughout the

bandgap. Stability analysis shows that there exist vast areas within the bandgap where stable solitons exist.

1 INTRODUCTION

Solitons are nonlinear waves that maintain their pro-

ﬁle for a long distance (or time). They have been ob-

served in a variety of physical systems such as wa-

ter, plasma and optical materials. In optical materi-

als, solitons are formed when the nonlinearity of the

medium is balanced by the dispersion (Chiao et al.,

1964).

In periodic optical media such as Fiber Bragg grat-

ings (FBGs), due to the coupling between the forward

and reﬂected waves gives rise to an induced disper-

sion which can be up to 6 orders magnitude greater

than that of silica. Gap solitons (GSs) are formed

when the induced dispersion in the FBG is balanced

by the nonlinearity of medium (De Sterke and Sipe,

1994). In the last few decades, GSs have attracted

much attention and have been studied in numerous

theoretical (Aceves and Wabnitz, 1989; Malomed and

Tasgal, 1994; Barashenkov et al., 1998) and experi-

mental works (De Sterke et al., 1997; Eggleton et al.,

1999).

GSs have a number of interesting features one of

which is that their velocity can range from zero to

speed of light in the optical medium. Zero velocity

or slow solitons have potential applications in optical

buffers and memory elements (Krauss, 2008). The

existencxe and dynamics of GSs have been studied

in different structures and nonlinearities such as dual-

core systems (Mak et al., 1998a; Atai and Malomed,

2000), nonuniform Bragg gratings (Atai and Mal-

omed, 2005; Baratali and Atai, 2012), photonic crys-

tal waveguides (Neill and Atai, 2007; Monat et al.,

2010), cubic-quintic nonlinearity (Atai and Malomed,

2001; Dasanayaka and Atai, 2010) and quadratic non-

linearity (Conti et al., 1997; Mak et al., 1998b).

Dual-core and dual-modesystems possess rich dy-

namical features (Atai and Chen, 1992; Mak et al.,

2004; Chen and Atai, 1998; Chen and Atai, 1995).

In particular, a dual-core system with non-identical

cores can provide superior switching performance

than the dual-core systems with identical cores (Atai

and Chen, 1993; Bertolotti et al., 1995). In this paper,

we consider the existence and stability of gap solitons

in a dual-core system with Kerr nonlinearity where

one core has a uniform Bragg grating and the other is

equipped with a Bragg grating with dispersive reﬂec-

tivity.

2 THE MODEL

Propagation of light in a dual-core nonlinear coupled

system with one core having a uniform Bragg grating

and the other being equipped with a Bragg grating and

dispersive reﬂectivity can be represented mathemati-

cally by the following equations:

+ iu

+ u



+ |v



+ λu

+ mv

1xx

= 0,

− iv

+ v



+ |u



+ λv

+ mu

1xx

= 0,

+ iu

+ u



+ |v



+ λu

= 0,

− iv

+ v



+ |u



+ λv

= 0.

(1)

Hossain, B. and Atai, J.

Solitons in a Dual-core System with a Uniform Bragg Grating and a Bragg Grating with Dispersive Reﬂectivity.

DOI: 10.5220/0008909700760079

In Proceedings of the 8th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS 2020), pages 76-79

ISBN: 978-989-758-401-5; ISSN: 2184-4364

In Eqs. (1), u

1,2

and v

1,2

stand for forward- and

backward-propagating waves of the cores 1 and 2, re-

spectively. m > 0 denotes dispersive reﬂectivity and

λ is the coupling coefﬁcient between the two cores.

It is worth noting that m > 0.5 may not be physically

realizable (Atai and Malomed, 2005). Therefore, we

have limited our analysis to 0 ≤ m < 0.5.

To determine the bandgap within which GSs may

exist, the linear spectrum of the system needs to be

analyzed. To this end, the dispersion relation for

the model by is derived by substituting u

1,2

, v

1,2

∼

exp(ikx − iωt) into linearized form of Eqs. (1) which

leads to the following equation:

ω = ±



− mk

+ λ

∓



− 4m

+4m

+ 4m

− 16mλ

+ 16λ

+16λ



+1+



(2)

Figure 1 represents the dispersion diagram or bandgap

specturm in (k, ω) plane. It is evident that the bandgap

shrinks as λ increases.

-3 -2 -1 0 1 2 3

-4

-2

m = 0.0

m = 0.2

(a)

-3 -2 -1 0 1 2 3

-4

-2

m = 0.0

m = 0.2

(b)

Figure 1: Examples of bandgap spectrum for (a) λ = 0.2,

m = 0.0, 0.2 and (b) λ = 0.4, m = 0.0, 0.2.

-10

-5

-0.4

-0.2

0.2

0.4

0.6

0.8

Re(u )

Im(u )

(a)

-10

-5

-0.2

-0.1

0.1

0.2

0.3

Re(u )

Im(u )

(b)

Figure 2: Examples of for (a) u

and (b) u

at λ = 0.2,

m = 0.2, ω = 0.4.

3 QUIESCENT GAP SOLITON

SOLUTIONS

The stationary GS solutions must be obtained numer-

ically using the relaxation algoritm since there are no

analytical solutions for Eqs. (3). The soliton so-

lutions are sought as u(x,t) = U (x)exp(−iωt) and

v(x,t) = V (x)exp(−iωt). Substituting these ansatz

into Eqs. (1) results in the following equations:

ωU

+ iU



+ |V



+ λU

+ mV

1xx

= 0,

ωV

− iV



+ |U



+ λV

+ mU

1xx

= 0,

ωU

+ iU



+ |V



+ λU

= 0,

ωV

− iV



+ |U



+ λV

= 0.

(3)

Figure 2 shows the real and imaginary parts of u

and

(note that v

= −u

∗

and v

= −u

∗

) and Figure 3

displays the amplitudes of u

and u

. Our analysis

shows that quiescent soliton solutions exist through-

out the bandgap.

Solitons in a Dual-core System with a Uniform Bragg Grating and a Bragg Grating with Dispersive Reﬂectivity

-10

-5

0.2

0.4

0.6

0.8

|u |

m=0.2

m=0.4

(a)

-10

-5

0.1

0.2

|u |

m=0.2

m=0.4

(b)

Figure 3: Examples of amplitude variation of (a) u

and (b)

at λ = 0.2, ω = 0.4, m = 0.2, 0.4.

4 STABILITY ANALYSIS OF

QUIESCENT GAP SOLITONS

To analyze the stability of the solitons in the model,

we have solved Eqs. (1) numerically using the sym-

metrized split-step Fourier method. Figure 4 shows

the examples of propagation of stable and unstable

solitons. In the case of unstable solitons, it is found

that they generally shed some energy in the form of

radiation and they either evolve to a moving soli-

ton (see Figure 4(b)) or if they are highly unstable

they are completely destroyed. Figure 5 shows the

stability diagram for λ = 0.2 in the plane of (m, ω).

An important feature of this stability diagram is that

there is a vast region within the bandgap where stable

quiescent solitons exist. Moreover, the stabilization

effect of dispersive reﬂectivity is more pronounced

for moderate values m (i.e. when m is in the range

0.2 < m < 0.4).

5 CONCLUSIONS

The existence and stability of gap solitons are con-

sidered in a coupled system with Kerr nonlinearity

where one core has a uniform Bragg grating and

the other has a Brag grating with dispersive reﬂec-

-30 0 30

2000

(a)

-30 0 30

2000

(b)

Figure 4: Examples of propagation of (a) stable soliton at

λ = 0.2, m = 0.2, ω = 0.7 and (b) unstable soliton at λ =

0.2, m = 0.2, ω = −0.7. Here only u

component is shown.

0 0.1 0.2 0.3 0.4

0.5

-0.8

-0.4

0.4

0.8

Stable

Unstable

Figure 5: The stability diagram of quiescent gap solitons at

λ = 0.2.

tivity. The analysis of the linear spectrum of the

model shows that there exists a genuine bandgap in

the model where solitons can exist. The size of the

bandgap shrinks as the coupling coefﬁcient between

the cores is increased. Quiescent soliton solutions are

found throughout the bandgap.

Stability analysis of quiescent solitons shows that

stable and unstable solitons exist in the system. Un-

PHOTOPTICS 2020 - 8th International Conference on Photonics, Optics and Laser Technology

stable solitons may either evolve to a moving soliton

or are completely destroyed. Nontrivial stability bor-

ders have been identiﬁed in the plane of (m, ω).

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Solitons in a Dual-core System with a Uniform Bragg Grating and a Bragg Grating with Dispersive Reﬂectivity