Introduction

The nonlinear Schrödinger equation (NLSE) provides a central description of a variety of nonlinear localization effects and has been intensively studied in various contexts in nonlinear science1,2. Since the pioneering analysis of Zakharov and Shabat in 1971, there has been wide and continued investigation into the properties of analytic soliton solutions of the NLSE3, both for their intrinsic scientific interest, as well as for their potential to provide new insights into important applications such as optical propagation in nonlinear waveguides4. For the case of a self-focussing nonlinearity, the most celebrated solution of this type is very likely the propagation-invariant hyperbolic secant bright soliton, but there is also an extensive literature studying various types of solitons on finite background (SFB) consisting of a localized nonlinear structure evolving upon a non-zero background plane wave5,6,7,8,9,10,11,12.

Solitons on finite background have recently attracted significant interest as their localization dynamics have been proposed as an important mechanism underlying the formation of the infamous extreme amplitude freak waves on the surface of the ocean13,14,15,16. Much of this work has also been motivated by a parallel research effort using nonlinear optical fibre systems to implement controlled experiments studying NLSE dynamics and rogue waves in a purely optical context17. Many of these recent studies have focussed on the characteristics of the Akhmediev breather, a particular SFB solution which is excited from a weak periodic modulation and which is localized in the longitudinal dimension as it undergoes growth and decay9. Experiments in optics have demonstrated important links to modulation instability18 and Fermi Pasta Ulam recurrence19, the nonlinear evolution process whose study essentially founded the field of computational nonlinear science20. Another significant application of the theory of Akhmediev breathers has been to design experiments generating the rational Peregrine soliton, an important and limiting case of a SFB solution that is localised in both transverse and longitudinal dimensions8,21,22.

The first SFB solution to the NLSE that was obtained is now known as the Kuznetsov-Ma (KM) soliton which, in contrast to the Akhmediev breather, undergoes periodic evolution with propagation. Surprisingly, however, although this solution has been known since 19775,6,7, the theoretical predictions describing KM soliton dynamics have in fact never been the subject of detailed experimental study. Certainly experiments on periodic wave train dynamics have been reported since the early years of studies in nonlinear hydrodynamics, but the results presented have been purely qualitative or have been compared only with numerical studies of the NLSE23,24,25,26. To our knowledge, there have been no explicit comparisons between experiments studying periodic nonlinear NLSE wave evolution and the theory of the KM soliton on finite background.

In this paper, we address this issue directly and present the first experimental confirmation of the pioneering theoretical studies of the KM soliton solution of the NLSE. In what follows, we first review the properties of the different SFB solutions to the NLSE under ideal conditions and then use numerical simulations to show how the dynamics of the KM soliton also appear in the longitudinal growth and decay of the individual modulation cycles of a strongly modulated initial plane wave in optical fibre. These simulations allow us to show how KM dynamics appear under conditions much wider than those originally considered, allowing us to design experiments using tailored initial conditions of a modulated optical source injected in optical fibre to confirm the KM soliton theory. Specifically, using ultrafast metrology and fibre cutback experiments, we measure the evolving temporal profile with propagation distance along the fibre, allowing us to perform a direct comparison between the generated temporal profile and its longitudinal evolution and the analytic prediction of the KM solution. These results now complete an important series of experiments that have now observed a complete family of soliton on background solutions to the NLSE and lead to the interpretation of the KM soliton as an analytic limit of the Fermi-Pasta-Ulam recurrence phenomenon in nonlinear fibre propagation.

Results

The Akhmediev, Peregrine and Kuznetsov-Ma solutions compared

We first review the different SFB solutions to the NLSE which have motivated our experimental studies. The dimensionless self-focussing NLSE is written:

where is a wave group or pulse envelope which is a function of ξ (a propagation distance or longitudinal variable) and τ (a co-moving time or transverse variable). Transformation to experimental parameters is given in Section C below. Using the notation of Ref.9, a general SFB solution of the NLSE can be written compactly as follows:

Here, the single governing parameter a determines the physical behaviour of the solution through the function arguments b = [8a (1−2a)]1/2 and ω = 2(1−2a)1/2.

We plot the solution of Eq. (2) for different values of a in Fig. 1. For a < ½ as shown in Fig. 1(a) the solution describes the Akhmediev breather and ω and b are real with physical significance as a modulation frequency and exponential growth and decay rate. We see clearly the growth and decay cycle of the initial weak periodic modulation. For a = ½ as in Fig. 1(b), the solution describes the Peregrine soliton corresponding to the low frequency limit of the Akhmediev breather which in this case is localized in both transverse and longitudinal dimensions. For a > ½ as in Fig. 1(c), the solution describes the KM soliton where the parameters ω and b become imaginary such that the hyperbolic trigonometric functions in Eq. (2) become ordinary circular functions and vice-versa. It is this that leads to the contrasting localization and periodicity characteristics and different physics of the Akhmediev and KM solutions.

Figure 1
figure 1

Analytic solutions of the NLSE from Eq. (2) with different values of parameter a as indicated illustrating the three different classes of primary soliton on finite background solutions of the NLSE.

Observing KM dynamics: Modulation Instability with strong modulation amplitude

Exciting an ideal Akhmediev breather requires a specific choice of weakly modulated continuous wave as initial condition27 and deviation from ideal initial conditions (e.g. with a large amplitude initial modulation) yields more complex behaviour. Although general solutions for complex evolution dynamics can be found using Jacobi elliptic functions10, we have found that the longitudinal dynamics observed with a large initial modulation can in fact be described and interpreted in terms of the expected longitudinal evolution of a KM soliton. It is this realization that has allowed us to design experiments to excite KM soliton dynamics under controlled conditions for the first time.

This approach is shown in Fig. 2, where we use numerical integration of the NLSE to compare the evolution of an input field based on an exact KM soliton with that of a suitably designed strongly-modulated field that approximates the KM soliton over each modulation cycle (see Methods). We first compare the two initial profiles used in the simulations in Fig. 2(a). Specifically, we choose the initial conditions of a strongly-modulated continuous wave (dashed line) such that the central modulation cycle overlaps with the KM soliton pulse above the background as shown (solid line) at a point of minimal intensity in its evolution. The governing parameter of the KM soliton in this case is aKM = 1.

Figure 2
figure 2

(a) Input field comparing ideal KM solution and modulation approximation. (b) Integrating the NLSE for the modulated input field shows complex evolution. (c) The evolution for the central region of the NLSE simulation results agrees very well with the evolution of the ideal KM soliton.

In Fig. 2(b) we show results from the numerical integration of the NLSE for the strongly modulated input field described above where we see complex and biperiodic evolution. Significantly, however, when we compare a detailed view of the evolution along ξ of the central cycle of the modulated signal with the corresponding exact evolution for the KM soliton as we show in Fig. 2(c), we see near identical periodic evolution in the two cases. (Of course, the choice of the central modulation cycle here is arbitrary; all cycles of the modulated field evolve in the same way along ξ ). This now allows us to interpret the periodic longitudinal evolution generated from an initial strong modulation in terms of the evolution of an equivalent KM soliton. Identifying this physical equivalence is extremely important, as it shows the universality of KM dynamics in NLSE propagation, even under conditions very different from those originally considered. Moreover, since such periodic evolution in the NLSE is well-known to be an example of Fermi-Pasta-Ulam recurrence19, we can also now interpret the KM soliton result as an analytic description of this process.

Experimental Setup and Results

From an experimental viewpoint, the results above have allowed us to design experiments where the predictions of the analytic KM soliton theory can be tested for the first time. Our experimental set up is shown in Fig. 3 (see Methods). We use high speed telecommunications-grade components to strongly modulate a continuous wave 1550 nm laser diode. The modulation strength and period are chosen such that the characteristics of each cycle match a particular KM soliton as shown in Fig. 2(a). We aim to synthesize an input field at the fibre input z = 0 corresponding to a KM soliton of governing parameter aKM. The initial conditions are written in dimensional form as such that the field varies between minimum “background” amplitude of and a maximum value of . Note that P0 here is the background field power in W. We study propagation in SMF-28 optical fibre with group velocity dispersion β2 [s2m−1] and nonlinearity γ[W−1m−1]. The dimensional field A(z,T) [W1/2] is: and defining a timescale T0 = (|β2| LNL)1/2, the dimensional distance time T [s] is T = τ T0.We also define a characteristic length LNL = (γ P0)−1 such that the dimensional distance z [m] is (where zp corresponds to one period of the KM cycle so that our initial conditions above are injected at z = 0.)

Figure 3
figure 3

(a) Experimental setup. PM: phase modulator. IM: intensity modulator. EDFA: Erbium doped fibre amplifier. SMF: single mode fibre: OSA: optical spectrum analayser. OSO: optical sampling oscilloscope. (b) Ideal KM soliton at minimum intensity for aKM = 0.66 (black) compared with the experimentally synthesized modulated field (red).

In our experiments, we characterized the field propagation by cutting the fiber back in steps of 200 m from its original length. This allows quantitative measurements of evolution with distance that we can compare with the theoretically-expected behaviour of an ideal KM soliton. The evolving field profile was characterized for each fibre length using an ultrafast optical sampling oscilloscope (OSO) and a high dynamic range optical spectrum analyser (OSA). A phase modulator (PM) was used to mitigate the effects of Brillouin scattering and an erbium-doped fibre amplifier (EDFA) was used to obtain average powers up to 1 W. The modulation strength (at ~30.5 GHz) was optimized to yield individual modulation cycles that provided a very good fit to an ideal KM of 0.7 W background and 1.2 W peak power with the target KM soliton parameter here aKM = 0.66. The modulated input field synthesized experimentally and the ideal KM soliton are compared in Fig. 3(b). The SMF-28 fibre length used corresponded to one period of the expected KM cycle zp = 5.3 km. Higher values of aKM and longer fibre lengths could not be used in our experiments because of limitations due to fibre loss and Brillouin scattering.

Our experimental results are shown in Fig. 4. Figure 4(a) is a false color plot of the measured temporal intensity profiles at each propagation distance, compared with the profiles of an ideal KM soliton. There is clearly very good qualitative agreement and this is confirmed quantitatively in Fig. 4(b) by comparing the instantaneous power at the centre of the modulation cycle (T = 0) from experiment (red circles) with the corresponding power evolution for an ideal KM soliton (solid line). Note that there are no free parameters used when plotting the expected theoretical KM soliton evolution. The small discrepancy between experiment and theory arises from fibre loss, but performing numerical simulations of the propagation of the experimental input field including loss (blue dashed line) reproduces experiment near-exactly.

Figure 4
figure 4

(a) False color plot of experimental and theoretical intensity evolution with propagation distance. (b) plots the evolution of the power at the centre of the modulation cycle as a function of normalised distance (zp = 5.3 km) comparing experiment (red), the theoretical evolution of the KM soliton (black) and simulation (blue). (c) compares time-domain and frequency-domain properties of the KM soliton for maximum temporal compression at z = zp/2.

Finally, in Fig. 4(c) we plot the explicit comparison between experimental and ideal KM soliton profiles in both the time and frequency domains at the point of maximum temporal compression when z = zp/2. The agreement between experiment (red), theory (black) and numerical modeling (blue) for both temporal intensity and spectrum is again very good and the experimental characterization shows both the localized soliton and the background components of the KM soliton at this point. Note that the theoretical spectrum (see Methods) plotted corresponds only to the time-varying envelope component of the KM soliton and that the delta-function component at the pump wavelength (from the infinite background of the ideal solution) is not shown. Nonetheless, there is remarkable agreement between the measured decay of the spectral sidebands of the experimentally observed KM soliton and theory.

Discussion

The results in Fig. 4 show excellent agreement between the nonlinear longitudinal evolution of a modulation cycle of a strongly modulated continuous wave and the dynamics of an ideal KM soliton. The fact that the KM soliton theory describes the evolution of individual modulation cycles is an essential conclusion of this paper and indeed, the identical evolution observed for each cycle of the evolving field leads us to conclude that these tailored initial conditions actually yield a high repetition rate train of Kuznetsov-Ma solitons with high quality compressed pulse characteristics.

These results complete a series of recent studies in optics that have now observed all three of the primary class of soliton on finite background solutions to the NLSE: the Akhmediev breather, the Peregrine soliton - and here - the Kuznetsov Ma soliton. In addition, the fact that we show that KM dynamics appear more universally than for the specific conditions considered in the original theory is further support of recent generalisations of the soliton concept beyond those based on strict mathematical considerations28. Our results also establish a further link between the dynamics of solitons on finite background and the seminal Fermi-Pasta-Ulam recurrence phenomenon of nonlinear dynamics. In fact, our results support an important interpretation of the KM soliton as a special case of analytic descriptions of NLSE evolution which provide a general framework to describe the Fermi-Pasta-Ulam process in NLSE systems1,10.

In conclusion, it is interesting to remark that whilst a 35 year interval between original theoretical studies and experimental confirmation may seem surprising, it is only recently that the importance of these soliton on background solutions has been widely appreciated within physics. Within the nonlinear optics community in particular, it is worth noting that high quality pulse characterisation in optics is a relatively recent development29,30,31 and an important implication of our work is to anticipate that experiments using optical systems will continue to provide an important and highly convenient means of testing fundamental theories of nonlinear wave dynamics.

Methods

To describe the modelling of a KM soliton by a periodic modulation over a single cycle, it is useful to write Eq. (3) for a > ½ in terms of real arguments B and Δτ where and

The KM solution evolves periodically with period . Transverse localisation is determined by . Ignoring a phase offset, the minimum amplitude solution is:

and the solid line in Fig. 2(a) plots for a = 1. The full width at half maximum (ΔΤ FWHM) of the time-varying amplitude above background of Eq. (4) is used to determine numerically the optimal frequency for a modulated field approximation: Ω mod = 2π/(2.22 ΔΤ FWHM). The compressed pulse at the point of maximum compression is:

with Fourier transform used to calculate the continuous spectrum in Fig 4 (c) analytically given by: where ν is the reciprocal Fourier variable of τ.

Experiments used a tunable high repetition rate optical source (Photline Technologies ICB SoFast ModBox), including a laser diode at 1554.9 nm modulated at ~30.5 GHz by means of an Intensity Modulator (with significant energy in only two sidebands about the pump), a 30 dBm erbium-doped fiber amplifier and a phase modulator which broadens the laser linewidth to ~43 MHz to suppress Brillouin scattering. Spectral measurements (Yokogawa - AQ6370 OSA) were carried out with 0.02 nm resolution bandwidth and the optical sampling oscilloscope (Picosolve PSO-101) had 0.8 ps resolution. The SMF-28 fibre had parameters:β2 = −21.8 ps2 km−1, β3 = 0.012 ps3 km−1, γ = 1.3 W−1 km−1 and 0.2 dB/km loss. With P0 = 0.7 W, the normalization constants LNL = 1.1 km and T0 = 4.9 ps. The KM periodicity is = 5.3 km.

Numerical integration results in Fig 2 were based on a standard split-step scheme. Accurate simulation of the modulated input field required discretization so that modulation harmonics fall exactly on frequency-domain grid points. The numerical simulations in Fig. 4 also included loss, third-order dispersion and a −50 dB noise background to model the effect of the EDFA, but the loss was found to be the primary reason for deviation from theory.