Slow light with a swept-frequency source

Rui Zhang; Yunhui Zhu; Jing Wang; Daniel J. Gauthier

doi:10.1364/OE.18.027263

1. Introduction

Slow light, where the group velocity of a pulse is much smaller than the light speed in vacuum [1,2], has shown promise in a great number of applications [3–5], such as optical buffering, variable true time delay, and enhancing nonlinear optical phenomena. Slow light via stimulated Brillouin scattering (SBS) in optical fibers has attracted a lot of interest due to its compatibility with fiber-optic communication systems and room-temperature operation [6–9]. Its use in high-bandwidth systems is limited, however, due to the natural linewidth of the SBS process, which is typically 35 MHz in conventional single-mode fibers. The bandwidth can be extended into the tens of GHz range by dithering the frequency of the pump beam [10–13]. In some applications, such as swept-source optical coherence tomography (OCT) [14] and Fourier transform spectroscopy [15], it is desirable to have controllable slow light over a bandwidth of several nanometers, which is currently not accessible with SBS slow light.

Optical coherence tomographic systems, comprised of a reference arm and a sample arm, are used for micron-resolution imaging. One method, which shows advantage for obtaining a high signal-to-noise ratio, uses a rapidly-swept narrowband source that is linearly chirped over a broad optical bandwidth. The resolution of such a swept-source OCT system is limited by the total sweep range, and the imaging depth is limited by the smallest frequency step of the source or the digital sampling rate of the detection system. To capture an image of a sample over a large depth, the length of the reference is often changed and the sweep repeated, thereby changing the region of interest. A controllable slow light medium, placed in the reference arm, could make it possible to change the region of interest without changing the physical length of the reference arm because the image location is proportional to group index n_g in the reference arm [16]. However, due to the narrow linewidth of SBS process, it is not possible to use SBS slow light for such an application.

In this paper, we introduced a new concept to realize SBS slow light applicable to broadly-swept sources. This method allows slow light to be achieved, in principle, over the entire transparency window of the optical fiber (many 100’s of nm at telecommunication wavelengths). The key idea is to pump the SBS process with a beam that is derived from the linearly swept source, but shifted to a higher frequency equal to the Brillouin frequency shift of the fiber Ω_Β using a Mach-Zehnder modulator. In this way, the pump beam frequency automatically tracks the swept-source signal frequency as they enter the fiber and hence are always near the SBS resonance frequency where the slow-light effect is largest. The fact that the pump and signal beams counterpropagate through the fiber causes a small detuning Δν between the beams, which decreases the slow light effect. This detuning increases with increasing fiber length L and the source sweep rate R and must be accounted for to optimize the slow light delay.

We experimentally and theoretically investigate the slow light effect and its dependence on R and other experimental parameters. We demonstrate that there is an optimum value of L to obtain the largest delay for a given R. We observe a delay τ = 10 ns using a 10-m-long photonic crystal fiber (PCF) with R = 400 MHz/μs and a pump power P_in = 200 mW. Larger delays can be obtained by increasing P_in until spontaneous Brillouin scattering dominates the process. We find that the maximum obtainable delay for an optimum-length fiber of the same type used in our experiment is ~38 ns independent of R. A pump power of 760 mW is required to obtain the maximum delay for R = 400 MHz/μs for our fiber.

2. Experiment setup

In the experiment, a beam from a single-mode rapidly-tunable laser is split in two, with one beam serving as the SBS pump beam and the other as the signal beam (see Fig. 1 ). The signal beam passes through a MZM operated in carrier-suppressed mode to create frequency-shifted sidebands at the SBS Stokes and anti-Stokes frequencies. The anti-Stokes beam is filtered out using a fiber Bragg grating (FBG) with a linewidth of 20 GHz. In future research, the MZM and Bragg grating can be removed and replaced by single-side-band carrier-suppressed optical modulator [17]. The pump and signal beams counterpropagate through the optical fiber (the SBS slow light medium), and the signal beam experiences SBS amplification and the associated slow light delay [4]. An additional short fiber is used in the pump beam path to compensate for the propagation time difference between the pump and signal arms. This guarantees the signal and pump have the same frequency shift in the middle of the PCF.

Fig. 1 Experiment setup for slow light via stimulated Brillouin scattering. EDFA, erbium doped fiber amplifier; PC, polarization controller; FBG, fiber Bragg grating; PD, photodetector; RF, radio frequency generator.

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Before we study the slow light effect with a frequency-swept-source, we first characterize the properties of the fiber for a monochromatic laser (R = 0). A 10-m-long PCF (NKT Photonics Inc., NL-1550-NEG-1) is used as the slow light medium, which is made of pure silica with a core diameter of 2.1 μm and air-filling fraction of 16%. To measure the gain due to SBS, we record the signal output while turning on and off the pump beam. The gain factor is denoted by G = log(P_s/P_so), where P_s (P_so) is the signal output with (without) the pump beam present, respectively. We measure a Lorentzian-shaped gain profile with a resonance frequency Ω_B = 9.782 GHz, and a resonance width (FWHM) Γ_B = 40.8 MHz. To measure τ, we sinusoidally modulate the signal beam intensity at a frequency of 1 MHz. We record the transmitted intensity in the presence and absence of the pump beam and determine τ by comparing the phase difference of the waveforms. We find τ = 20 ns with a pump power inside the PCF P_in = 200 mW.

3. Slow light with a swept source

We investigate the slow light effect using a linearly swept-frequency source. By directly sweeping the injection current of the DFB laser, we obtained a linearly-swept source over a total sweep range of 10 GHz with frequency $ν (t) = ν_{0} + R t$ , where ν ₀ is the initial frequency and R is the sweep rate. The output power varies slightly as the frequency is swept (less than 5%). The natural linewidth of the DFB laser is ~1 MHz, comparable to the linewidth of advanced swept sources used in OCT systems [18]. The repetition period of the modulation waveform is much longer than the transit time of light through the fiber, denoted by t_r = L/u, where u~ $2 \times 10^{8}$ m/s is the speed of light in the fiber, and t_r is ~50 ns for our fiber. Therefore, we can assume the pump and probe frequency increase linearly with time during the SBS process. The MZM is largely insensitive to the change in frequency of the light passing through it. Since the signal and the pump beams are derived from the same swept source, they are chirped simultaneously. The signal-beam frequency automatically tracks the swept-source pump-beam frequency and hence is always near the SBS resonance frequency, which guarantees a strong slow light effect. However, the pump and signal beams counterpropagate through the fiber, which causes a spatially-dependent detuning between the beams and hence decreases the slow light effect.

To investigate the frequency-dependent SBS gain experienced by the chirped beams, we adjust the signal beam frequency (set by the frequency-shift Ω of the MZM) and measure the gain G. Fig. 2 shows the measured gain profiles for three different sweep rates as a function of the frequency difference δ = Ω-Ω_B. We see that the gain profile is broadened substantially due to the sweep-rate-dependent detuning mentioned above. Broadening begins when the detuning between the two beams differs by Ω_B ± Γ_B/2 at the middle of the fiber (recall that the beams differ by Ω when enter either end of the fiber). That is, when R = Γ_B/(2t_r)~400 MHz/μs for our fiber. To characterize the gain profile in greater detail, we analyze theoretically the gain and delay experienced by the signal beam.

Fig. 2 Measured (dots) and simulated (solid) gain profile of photonic crystal fiber with sweep rate R of 0 (blue circles), 400 MHz/μs (red diamonds), and 800 MHz/μs (black stars).

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Consider a reference frame that travels with signal beam (see Fig. 3 ). The frequency detuning between the pump and signal beam at position x is given by

Δ ν = ν_{s} - ν_{p} (x) + Ω_{B} = ν (t - \frac{x}{u}) - ν (t - \frac{L - x}{u}) + δ = \frac{L - 2 x}{u} R + δ,

where ν_s and ν_p(x) are frequencies of signal and pump beams, respectively. The detuning Δν decreases G, whose effect can be found by integrating the differential gain per unit path length dx over the whole fiber as

G = \ln (\frac{P_{s}^{}}{P_{s o}^{}}) = \int_{0}^{L} g (Δ ν) P (x) d x,

where g(Δν) is gain profile of the slow light medium, and P(x) is pump power. We find

G = \int_{0}^{L} g_{p} P_{i n} e_{}^{- α x} \frac{{(\frac{Γ_{B}}{2})}^{2}}{{(\frac{L - 2 x}{u} R + δ)}^{2} + {(\frac{Γ_{B}}{2})}^{2}} d x,

where α (g_p) is the optical loss (SBS gain) coefficient of the fiber. For our photonic crystal fiber, α = 9 dB/km and g_p = 2.5 m⁻¹W⁻¹. The PCF used in this experiment is only 10 meter long, which makes the optical loss negligible and hence we can set α = 0 for simplicity. However, for a longer fiber, the optical loss needs to be considered because it will cause asymmetry of the broadened gain profile. With α = 0, we solve Eq. (3) and find

G = g_{p}^{} P_{i n}^{} Γ_{B}^{} u \frac{\arctan (\frac{2 L R + 2 u δ}{u Γ_{B}^{}}) + \arctan (\frac{2 L R - 2 u δ}{u Γ_{B}^{}})}{2 R} .

The linewidth (FWHM) of the gain profile is then given by

Γ = \sqrt{Γ_{B}^{2} + 4 {(\frac{L R}{u})}_{}^{2}},

and goes over to 2LR/u in the limit of R>>Γ_B u/(2L). Using Eq. (4), we predict the SBS gain profile for three different sweep rates, as shown in Fig. 2. Agreement with our experimental measurements is very good.

Fig. 3 Diagram of the space-dependent frequency detuning between the pump and signal beams caused by the swept source.

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The slow light effect is largest at the center of the resonance (Ω = Ω_B). Therefore, we analyze the gain and delay and their dependence on R on the resonance. With δ = 0 in Eq. (4), we find that

G = g_{p}^{} P_{i n}^{} Γ_{B}^{} u \frac{\arctan (\frac{2 L R}{u Γ_{B}^{}})}{2 R} .

The slow light delay due to the SBS process is given by

τ = \int_{0}^{L} \frac{n_{g} (x) - n_{f g}}{c} d x,

where n_fg is the group index of the fiber without the SBS process, c is speed of light in vacuum, and

n_{g} (x) = n_{f g} + \frac{c g_{p}^{} P_{i n}^{}}{2 π Γ_{B}^{}} \frac{1 - \frac{4 Δ ν^{2}}{Γ_{B}^{2}}}{{(1 + \frac{4 Δ ν^{2}}{Γ_{B}^{2}})}^{2}}

is the group index due to the SBS effect in a differential segment of the fiber [6]. By combining Eqs. (1), (5), (7) and (8), we find

τ = \frac{g_{p}^{} P_{i n}^{} L Γ_{B}^{}}{2 π Γ_{}^{2}} .

The gain and delay are measured in our PCF using P_in = 200 mW for various value of R as shown in Fig. 4 , using the same method described in the previous section. We see that the delay drops faster than the gain due to the broadened gain profile, as discussed above. In particular, we observe τ = 10 ns for R = 400 MHz/μs and τ = 4 ns for R = 800 MHz/μs. We also overlay the predictions of Eq. (6) and (9) with no free parameters, where the agreement with our observations is very good.

Fig. 4 (a) Measured (dots) and simulated (solid) gain as a function of sweep rate R. (b) Measured (dots) and simulated (solid) delay as a function of sweep rate R.

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4. Optimum fiber length to achieve the largest delay

We find that, for a given sweep rate R, there is an optimum value of fiber length L to obtain the largest delay. From Eqs. (5) and (9), the maximum delay occurs for L_opt = uΓ_B/(2R) and is equal to τ_max = g _p P_inu/(4R), showing that τ_max is inversely proportional to R. Figure 5(a) shows the delay as a function of L for R = 400 MHz/μs using Eq. (9). For Γ_B = 40 MHz, L_opt~10 m, which corresponds to the length of our PCF. For fixed L and different R, a constant delay can be obtained by adjusting P_in, as shown in Fig. 5(b).

Fig. 5 (a) Delay as a function of L for R = 400 MHz/μs with P_in = 200 mW. (b) The pump power needed to obtain τ = 10 ns for L = 10 m.

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Larger delays can be obtained by increasing the pump power until spontaneous Brillouin scattering dominates the process. The gain parameter G is limited up to the Brillouin threshold G_th, where the delay reaches its maximum value τ_th obtainable by the fiber. By combining Eqs. (5) and (8) and assuming L = L_opt (giving Rt_r = Γ_B/2), we find that

τ_{t h}^{} = \frac{G_{t h}^{}}{π^{2} Γ_{B}^{}},

which is independent of R. Using Γ_B = 40 MHz and G_th = 15 for the 10-m-long PCF [19], we estimate τ_th = 38 ns, obtained when P_in = 760 mW.

5. Conclusion

We investigate the slow light effect via SBS with a linearly swept-frequency source. The pump and signal beams counterpropagate through the fiber, which introduces a small detuning between the beams and hence decreases the slow light effect. This detuning increases with increasing fiber length L and the source sweep rate R. We find there is an optimum value of fiber length to obtain the largest delay for a given sweep rate. Using the optimum-length fiber, we observed a delay of 10 ns with R of 400 MHz/μs and a pump power of 760 mW.

This research provides a path toward practical applications of the SBS slow light technique that uses broadband swept sources. The total frequency sweeping range using this method is limited up to 1 nm due to the varying Brillouin resonance as a function of pump frequency. However, by adjusting the RF frequency Ω to simultaneously track the Brillouin resonance of the pump frequency, the slow light can be achieved over the entire transparency window of the optical fiber. It has a potential to work with the high-speed commercial frequency-swept sources, which makes it applicable to optical coherence tomography and Fourier transform spectroscopy.

Acknowledgment

R. Z., Y. Z. and D. J. G. gratefully acknowledge the financial support of the DARPA DSO Slow Light Program and the Air Force Research Laboratory under contract FA8650-09-C-7932. J. W. gratefully acknowledges the financial support of the China Scholarship Council and Beijing Jiaotong University.

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Slow light with a swept-frequency source

Abstract

1. Introduction

2. Experiment setup

3. Slow light with a swept source

4. Optimum fiber length to achieve the largest delay

5. Conclusion

Acknowledgment

References and links

Cited By

Figures (5)

Equations (10)

Optics Express