Abstract
We observe the dynamics of pulse trapping in a microstructured fiber. Few-cycle pulses create a system of two pulses: a Raman shifting soliton traps a pulse in the normal dispersion regime. When the soliton approaches a wavelength of zero group velocity dispersion the Raman shifting abruptly terminates and the trapped pulse is released. In particular, the trap is less than 4 ps long and contains a 1 ps pulse. After being released, this pulse asymmetrically expands to more than 10 ps. Additionally, there is no disturbance of the trapping dynamics at high input pulse energies as the supercontinuum develops further.
©2009 Optical Society of America
1. Introduction
When a short and intense pulse of light is launched into a microstructured fiber (MF), non-linear effects can significantly broaden the spectrum to much more than an octave [1]. These supercontinua are used in a variety of applications such as ultrafast optical switching, spectroscopy, optical coherence tomography, optical clocks, etc. Routinely, around 100-fs pulses are used at a wavelength close to a zero-group velocity dispersion wavelength (ZDW) of the fiber. Using nearly octave–spanning input pulses [2, 3, 4], the phenomenon of ‘pulse trapping’ [5, 6, 7, 8, 9, 10] can be observed. In this effect a non-dispersing pulse can form at the short wavelength end of the broad spectrum. This is surprising because the pulse exists in a region of normal dispersion in the fiber, where the dispersion-induced chirp cannot be cancelled by self-phase modulation. The non-dispersing pulse is trapped behind a fundamental soliton in the anomalous dispersion regime that was generated by soliton fission. Soliton fission can create multiple fundamental solitons, which shift to longer wavelengths via the soliton self-frequency shift (SSFS) [11].
Nishizawa and Goto [6] were the first to demonstrate that a soliton undergoing the SSFS can trap light behind it. The trapped light adjusts to a wavelength that is group velocity matched to the soliton. Because it is forced to travel with the soliton and lies in the normal dispersion regime, it has to shift to shorter wavelengths in order to keep the same group velocity as the soliton. Gorbach and Skryabin provided an alternative view of pulse trapping [8]: the light is trapped because the soliton accelerates. In simulations they turned off the (negative) acceleration induced by the SSFS and the trapping ceased. The acceleration of the soliton provides a ‘gravity-like’ potential to the trapped pulse.
In this paper we study experimentally the phenomenon of pulse trapping in a fiber with two ZDWs. We use intense few-cycle pulses to generate a soliton and a trapped pulse and focus in particular on the trap dynamics as the soliton reaches the longer zero-dispersion wavelength and decays. We observe how the light escapes the trap, expanding to a few times the trap length. For higher input pulse energies, a further component in the spectrum at even shorter wavelengths is formed, which dominates the blue end of the evolving supercontinuum.
2. Pulse trapping
As previously shown, pulse trapping can be explained by an effective potential that is produced by an accelerating pulse – the fundamental soliton undergoing SSFS [8]. The discussion below follows this analysis. The soliton induces a nonlinear modification of the refractive index n, via the optical Kerr effect [12]:
where I is the intensity and n 2 the nonlinear index coefficient, assuming an instantaneous response, and n 0 is the linear index.
Any light field A in the fiber that interacts with the soliton sees the nonlinear contribution to the refractive index, n 2 I=n−n 0, and experiences cross-phase modulation (XPM) [13]. The evolution of the slowly varying envelope A(z, t) of this light is governed by [12]:
z and t are space and time in the laboratory frame. β 1 and β 2 are the dispersion parameters, where evaluated at the frequency of A. Since this frequency lies in the normal dispersion regime, β 2 is positive. iVA is the XPM-term and V(z, t)=2γ|As(z, t)|2, where As is the envelope of the soliton and γ is the nonlinear parameter.
In the co-moving frame given by T=t−β 1z and Z=z, eqn. (2) is transformed into the nonlinear Schrödinger equation
In analogy to the ordinary Schrödinger equation in quantum mechanics, the XPM contribution V induced by the soliton plays the part of a potential barrier.
Equation (3) is transformed into an accelerating frame [8]:
Here α describes the rate of the SSFS, which determines the soliton acceleration. For a soliton, α=−8TRβ 2 2,s/15T 4 0 [12]. TR is the Raman time; the soliton length is T 0. β 2,s is the group velocity dispersion at the soliton wavelength, and the minus sign indicates that the accelerating soliton is redshifting and slowing down. The transformation fixes the peak of the accelerating soliton at τ=0. In this frame, the propagating light A acquires a phase ϕ(ζ, τ), so A(Z,T) is replaced with ψ(ζ, τ) [14]:
The propagation equation (3) becomes
where
Therefore, in a frame that accelerates with the soliton, other waves propagate in the presence of an effective potential U eff. The first term in equation 7 is the barrier due to XPM and the second term is a linear potential due to the (negative) acceleration α. U eff is sketched in Fig. 1. The barrier is located at τ=0 and at τ=τ′ the linear increase reaches the height of the barrier.
Gorbach and Skryabin pointed out that the potential is ‘gravity-like’, i.e. similar to the gravitational potential on earth. Standing in a lift, the floor acts as a strong potential barrier against the gravitational force. Without gravity, the same potential would be created if the lift had a constant upward acceleration. So a uniformly accelerating barrier can trap objects just as a barrier in a gravitational field does.
As seen in Fig. 1, the potential can trap light between τ=0 and τ=τ′. We can estimate the temporal length of the trap by calculating τ′ using U eff(τ′)=U eff(0). Approximating V(τ′)≈0 and inserting α we obtain for an accelerating soliton
τ′ depends on the SSFS as well as the ratio of group velocity dispersions for the trapped light and the soliton. In our experiments the trap length is relatively constant, so that the trapped light is expected to have a well defined temporal length. The trap is positioned immediately behind the soliton center at τ≥0. In consequence, the trapped light travels at the group velocity of the soliton and slows down with it. The spectrum of the trapped light shifts to a wavelength associated with the same group velocity as the soliton. Accordingly, the potential determines both the spectral and temporal properties of the trapped light.
3. Experiment
To create the trapping soliton as well as the trapped light we couple a few-cycle pulse into a microstructured fiber. We use pulses from a <7 fs Ti:Sapphire laser with a repetition rate of 78MHz (Rainbow, Femtolasers GmbH). A reflective-optics telescope expands the beam and a parabolic mirror of high numerical aperture focuses the light for fiber coupling. The use of mirrors minimizes dispersion-induced pulse broadening. The 1.8m-long fiber (NL-PM-760, Crystal Fiber A/S) has zero dispersion at 760 nm and 1160 nm. The dispersion of the fiber and the initial pulse spectrum are shown in Fig. 2; the group index is displayed as β 1 in Fig. 3; the nonlinear coefficient is γ=102(Wkm)−1 at λ=780nm [15]. We rotate the fiber to align the fiber axes to the polarization of the incoming light. As a test of the pulse length at the fiber input face we replaced the fiber with a mirror and backreflected the pulse through the reflective focusing optics. Compensating for group delay dispersion, no significant pulse broadening was observed after the double pass. After the fiber we use a microscope objective to collimate the light and analyze it temporally with an autocorrelator (Pulsecheck, APE GmbH). By tilting the nonlinear crystal of the autocorrelator we perform Frequency-Resolved Optical Gating (FROG) measurements [16]. We also pick off part of our laser output beam, reduce the spectral bandwidth with a 60-nm interference filter, and use it as a reference pulse to record X-FROG traces. The reference pulse was characterized using a FROG measurement to be 35-fs in length (FWHM). Simultaneous to the FROG and X-FROG traces, we measure the spectrum of the trapped light and trapping solitons on a compact CCD-based spectrometer and an optical spectrum analyzer (OSA) for longer wavelengths. Figure 4 demonstrates that the fiber output spectra are very sensitive to the dispersion-induced chirp on the input pulse, that was varied by translating a glass wedge in the beam just after the laser output coupling mirror. In all experiments that follow we adjusted the input chirp to obtain maximum output spectral width (black curve in Fig. 4).
We create solitons in the near-infrared and trapped light in the visible. Because the input spectrum lies partially in the anomalous dispersion regime beyond 760 nm wavelength, a soliton forms and Raman shifts via the SSFS. The part of the input light that is in the normal dispersion regime and that is trailing the soliton is trapped. In addition there is interaction between light in the two dispersion regimes via self-phase modulation and phasematched amplification of dispersive waves [17, 18, 19, 20, 21]. Therefore, both the trap and trapped light are created by launching a single pulse into the fiber. Since the Raman-shifting soliton traps light, the trapped light has to maintain the soliton group velocity 1/β 1(λs) even though the soliton slows down. When it collides with the soliton, the trapped light is blueshifted [13]. This ultimately leads to the trapped light and soliton having the same group velocity. Increasing the input pulse energy in the fiber speeds up the SSFS and secondary fundamental solitons are created. For high input pulse energies the primary soliton shifts up to the long ZDW, which it cannot pass. The SSFS abruptly ends and the soliton decays. As the acceleration of the soliton is terminated, the ‘gravity-like’ part of the potential disappears, while the barrier decays slowly, i.e. the trapped light can escape behind the soliton. At the same time the wavelength shift of the trapped light ceases.
3.1. Output spectra at low pulse energies
When sufficient pulse energy is provided, a soliton is generated and redshifted due to the SSFS. Figure 5 shows the spectra of the soliton in the infrared for three input energies (upper row) and the corresponding spectra of the visible trapped light (lower row). The rate of redshifting of the soliton increases with pulse energy as longer wavelengths are reached within our finite fiber length. Below a wavelength of 700 nm a trapped pulse is created that frequency shifts with the soliton, but in opposite direction. The relative rate of shifting is determined by group velocity matching. Some of the initial pulse energy remains between 700 nm and 900 nm and propagates ahead of the slowing soliton. In the right-hand column of Fig. 5 (an input pulse energy of 40 pJ), the soliton is at a wavelength of 1150 nm, as marked by the red line. In the normal dispersion regime near 1300 nm, dispersive ‘Cherenkov’ radiation [22] is formed as has been seen in other experiments [3, 4]. Note that the light near 1300 nm does not form a pulse. The effect is discussed further below.
3.2. Output spectra at higher pulse energies
Spectra for higher pulse energies are shown in Fig. 6. The SSFS has ceased and the soliton has reached a final wavelength of 1150 nm, just below the ZDW of 1160 nm. Approaching this wavelength, the soliton produces dispersive Cherenkov waves around 1300 nm. The production of Cherenkov radiation balances the stimulated Raman effect in the soliton and the soliton redshift terminates. Since the soliton energy is gradually being transferred to the Cherenkov radiation, the soliton decays [24]. Figure 6 also shows that nearly all of the trapped light shifts to wavelengths shorter than the group velocity matched wavelength. These are propagating slower than the soliton - that is the light escapes behind the soliton. Light at wavelengths travelling faster than the soliton collides with the soliton one last time and shifts to the blue beyond the group velocity matched wavelength. This is seen particularly clearly by examining the soliton and the trapped light in the time domain, which we describe next.
3.3. FROG and X-FROG measurements at low pulse energies
For low input pulse energies the soliton undergoes SSFS throughout the fiber and hence it is always slowing down. The ‘gravity-like’ part of the trap potential still exists at the fiber end. The trapped light is confined behind the barrier created by the soliton. In Fig. 7 second harmonic-FROG (SHG-FROG) measurements [16] of the visible part of the spectrum show the trapped pulse. All of the FROG and X-FROG traces in this paper use the same linear color scale shown. The retrieved FROG traces are very similar to the measured traces, as indicated by the FROG errors. Thus, we have retrieved the correct pulse shape and phase in the time domain. The trapped pulse has a duration of ~1ps. The time-bandwidth product (FWHM) of this pulse is more than ten – the spectral width could support a sub 50-fs pulse. Note that the trapped pulse spectrum is faster than the soliton for the low 26 pJ input energy in Fig. 7. This seems to indicate that the trapped pulse is still forming.
The FROG retrieval requires a FROG grid as large as 2048×2048 pixels. Before retrieval, the wavelength is scaled by a factor to fit the data into a square grid [25]. After retrieval the wavelength is unscaled to recover the physical scale. The FROG error in Fig. 7 is 0.00468 (left column) and 0.00557 (right column). SHG-FROG has an ambiguity regarding the direction of time and the FROG measurement is not suitable to resolve the relative positions in time of the trapped pulse and soliton. Therefore we performed X-FROG measurements on the solitons and the trapped pulse by mixing the light from the fiber with the reference pulse (FWHM 35 fs) derived before the fiber and spectrally filtered. The X-FROG traces can be interpreted directly. Results are shown in Fig. 8, where the propagation direction is to the left. Again the ps-wide trapped pulse is measured. It is confined to the region behind the soliton. As the soliton redshifts and delays, the trapped light blueshifts to maintain group velocity matching with the soliton. Note that the trapped pulse trails the soliton by about 0.5 ps. This delay is due to the normal group velocity dispersion of the microscope objective used to collimate the light from the fiber. The measurements clearly show how the trapped pulse is strongly blocked by the soliton-induced barrier.
The retrieved pulse shapes in Fig. 7 (left) indicate that the trapped pulse has a small, low intensity shoulder on one side. The X-FROG measurements in Fig. 8 show that this shoulder extends behind the trapping soliton and reveal some ps temporal oscillations not resolved in the retrieved FROG traces, that are smoother than the measured traces. The shoulder seems induced by the asymmetry of the confining potential. The linearly increasing part of the trap potential caused by the SSFS is much more shallow than the sharp edge of the barrier.
The size of the trap can be estimated by equation 8. The soliton, when shifted to a wavelength around 1000 nm, maintains a near constant width of T 0=60 fs for different input pulse energies as measured separately by autocorrelation. With TR=5 fs [23] and a ratio β 2/|β 2,s|≈1.5 (see Fig. 2) this gives a trap length of 4 ps. The actual length of a pulse in this trap will be somewhat shorter as the pulse energy will not reach the height of the potential barrier of the trap due to tunneling. The observed pulse length of about 1 ps is in good agreement with this estimate.
3.4. Higher pulse energies and the end of trapping
When the input pulse energy in the fiber is sufficient for the soliton to reach the longer zero-dispersion wavelength, the behavior of the trapped light changes. SHG-FROG measurements of the trapped light are shown in Fig. 9. (FROG retrieval errors: 0.00449 (left), 0.00484 (right)). The pulse peak has widened considerably beyond 1 ps and the small shoulder of Fig. 7 has developed into a long tail. With more energetic input pulses the tail extends further.
This behavior again is a direct consequence of the soliton dynamics. When the soliton wavelength is stabilized by Cherenkov radiation, the acceleration terminates rapidly, but the soliton decays slowly [24]. The barrier part of the potential remains, but the gravity-like part disappears. Hence one side of the potential well vanishes and the light escapes the trap to one side creating the pronounced tail in Fig. 9. A higher launched pulse energy leads to a faster SSFS and the soliton acceleration turns off earlier on in the fiber. Thus the trapping ceases earlier and the trapped light can spread out more under dispersion during the remaining length of fiber. This is seen in Fig. 9 as the tail extends further for higher pulse energies.
Corresponding X-FROG traces of the trapped pulse and soliton after the soliton redshift has ceased are shown in Fig. 10. The soliton remains a barrier and prevents the trapped pulse from overtaking as before. On the other side the developing tail is clearly visible, extending more than 10 ps behind the soliton barrier (see also Fig. 9). Again the tail bears oscillations not resolved in the retrieved FROG traces. The shorter wavelengths in the tail travel slower due to the normal dispersion. The spectrum of the trapped pulse in Fig. 9 (right) is centered at 580 nm with a spectral width of 40 nm. At this wavelength the fiber dispersion is β 2≈45 ps2/km (Fig. 2). This leads to an expected length of the tail of about 10 ps per meter, in good agreement with the measured length. Thus as soon as the trapping terminates, the trapped light spreads quickly.
4. Yet higher pulse energies
By sacrificing the reference beam used in the X–FROG measurements we are able to further increase the pulse energy into the fiber. The soliton now reaches the wavelength stabilized by Cherenkov radiation even earlier in the fiber. Unfortunately, the large temporal width of the pulse and a small signal appearing at longer wavelengths made it impossible for our code to retrieve the FROG trace. The FROG trace in Fig. 12 is similar to traces of the trapped light at lower powers (compare to Fig. 9). The length of the tail is determined by the dispersion over the full fiber length. The wavelength of the pulse peak is arrested at ~590 nm. This stabilizes the trapped pulse and makes it independent of coupled input energy in this energy range.
Apart from this, the spectrum continues to reach shorter wavelengths, considerably below the group velocity-matched point (Fig. 11). We attribute the additional peak of light appearing below 550 nm to nonlinearly phase matched resonant wave mixing at the very input of the fiber [26, 17, 27]. This is consistent with the observation that the peak shifts to the blue and broadens with increasing energy. Similar behaviour has been seen in [19, 4]. In our case this leaves a particularly pronounced spectral gap at 550 nm between the arrested soliton and the additional developing peak, independent of input energy and of constant shape. In the infrared we see that multiple solitons, created from the input pulse by soliton fission, have shifted towards the long ZDW. The soliton that is arrested just short of the long ZDWis at a minimum of group velocity. The initially trapped light still trails the soliton and thus is of a wavelength shorter than the group velocity-matched wavelength. Light in the trap that had been propagating Δv faster than the soliton before release has undergone a spectral blueshift at the soliton to a group velocity Δv slower than the soliton [13].
5. Conclusion
By measurements in both the temporal and spectral domains, we show how the dynamics of a soliton determine both the wavelength and pulse-like nature of the short wavelength end of the supercontinuum. Light in the normal dispersion regime forms a trapped pulse governed by a potential consisting of a nonlinear barrier and a ‘gravity-like’ linear potential. The linear part is due to the SSFS which causes a negative acceleration of the soliton. As long as the soliton is accelerating, the trapping confines the light in time. When the SSFS terminates, the trapped light falls behind the soliton, moving to a wavelength associated with a group–velocity slower than the soliton. This effect dominates the shape of the supercontinuum at short wavelengths until resonant wave mixing with the input pulse further broadens the spectrum.
This setup allows for the creation and release of wavelength tunable picosecond pulses in the normal dispersion regime at any location along a microstructured fiber. The wavelength for the trapped pulse is obtained by choosing an appropriate dispersion profile of the fiber. The most important parameter is the longer zero dispersion wavelength. If the fiber has a long ZDW that is longer than 1160 nm, then the SSFS would take the soliton further into the infrared before the acceleration terminates. The trapped pulse would shift to even shorter wavelengths and still be confined in time. Once the soliton is arrested, the trapped pulse has reached the final wavelength which is largely independent of pulse energy. Hence, the trapped pulse wavelength could be increased from this by use of lower input pulse energies or chirped input pulses.
Acknowledgements
We are indebted to Dmitry Skryabin, Andrey Gorbach, Scott Robertson, Franz Kärtner, Peter Staudt, Klaus Metzger and Wilson Sibbett for discussions and technical support. This work is supported by the EPSRC, the Royal Society, and the Leonhardt Group Aue.
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