Abstract
We report the measurement of increased noise cross-correlation between stokes and anti-stokes beams created in cascaded four-wave mixing processes with dual pump wavelengths. This method may be useful in creating highly correlated twin beams for various applications including quantum information processing.
©2007 Optical Society of America
1. Introduction
Four-wave mixing (FWM) has been used in many optical communication applications such as parametric amplification [1-4], wavelength conversion [5-7], and parametric oscillation [8-10]. It is also used to create super-continuum light and frequency combs for applications in spectroscopy and absolute frequency calibration [11]. Recently there has been a growing interest in studying the FWM with multiple pump wavelengths [12, 13]. In most experiments reported so far with two pump wavelengths ω P1 < ω P2, the two stimulated degenerate FWM processes 2ω P1 = ω st + ω P2 and 2ω P2 = ω P1 + ω as dominate over the spontaneous non-degenerate FWM process ω P1 +ω P2 = ω st + ω as in creating stokes (ω st) and anti-stokes (ω as) light in the spectral side bands. Study of cross-correlation between the created stokes and anti-stokes light is of special interest for the generation of squeezed states [14] or correlated photon pairs [15-17] that may be of use for high resolution imaging or quantum information applications. While there has been consistent interest in studying the correlation between the stokes and anti-stokes light created in a degenerate FWM process with a single pump wavelength [18, 19], correlation studies have not been made of FWM with multiple pump wavelengths because it was assumed there is no direct correlation between the stokes and anti-stokes beams due to the dominance of degenerate FWM amplification.
Recently it was shown [12, 16, 20] that when fiber dispersion varies slowly near the zero-dispersion wavelength (λZDW), phase-matching or quasi-phase-matching can be satisfied between the pump, signal and idler fields. By arranging a pair of pump beams with frequencies (ω st, ω as) conjugate with respect to λZDW, such a process can occur and dominate with ω st + ω as = 2ωZDW. The frequency-degenerate two-photon light was produced efficiently with this method in the visible and the near infrared [16, 20, 21].
When light is created at the middle frequency in the two-photon state by spontaneous non-degenerate FWM instead of in single-photon state via stimulated degenerate FWM, this contradicts the accepted view as described above. One may further consider that this dominance of spontaneous non-degenerate FWM relative to stimulated degenerate FWM might also appear in the creation of stokes and anti-stokes wavelengths in the spectral side bands, ω P1 +ω P2 → ω st + ω as, which also contradicts the conventional wisdom. The stokes and anti-stokes wavelengths created by this spontaneous non-degenerate FWM process exhibit inherent correlation. In this paper we report what we believe is the first measurement of the cross-correlation between frequency-matched stokes and anti-stokes wavelengths created in a FWM process with dual-pump wavelengths. As the FWM process cascades to higher order, the higher order stokes and anti-stokes wavelengths show increased cross-correlation.
2. Experiment and discussion
The experiment (Fig. 1) begins with a 3 ps linearly polarized laser pulse (λp = 834.9 nm) coupled into a microstructure fiber* [22] MF1 (γ = 70/W/km, dispersion D = 1.8 ps/nm/km at λp = 835 nm) along one principal axis to generate quasi-super-continuum light at a repetition rate of 80 MHz, from which we select a pair of wavelengths (Stokes, λst = 836.9 nm and anti-Stokes, λas = 832.6 nm). Using a two-pass grating configuration, the two selected light pulses are put back in the same single spatial-mode and then coupled into a second microstructure fiber, MF2 along the same principal axis used for MF1. (MF1 and MF2 are two identical fibers with MF1 to be 1.8 m and MF2 to be 1 m.) The delay between the two pulses is adjusted to maximize the power of the third-order anti-Stokes light out of MF2 (Fig. 1 inset). The light output from MF2 is directed to a second grating to separate the wavelengths.
A spectrum of the light exiting MF2 is shown in Fig. 2(a), where the two pump wavelengths (λst and λas) are labeled, along with wavelengths λst+1 = 841.9 nm and λas-1 = 828.1 nm, λst+2 = 846.7 nm and λas-2 = 823.4 nm, and λst+3 = 851.6 nm and λas-3 = 818.7 nm designating the first, second, and third order stokes and anti-stokes wavelengths, respectively. It is easy to verify energy conservation with,
For each order, we plot the average power of the anti-Stokes light as a function of the total average power of the preceding order stokes and anti-stokes wavelengths in Figs. 2(b)-(d). Each curve shows an exponentially increasing power-dependence, where if we assume that the non-degenerate FWM dominates over other nonlinear processes in the generation of each order Stokes and anti-Stokes wavelength, and we assume that the pump power is not significantly consumed, the gain for each order FWM process is [23]
where κ = β 2(Δω)2 + γ(P st,i + P as,i) accounts for the FWM phase matching, and is the FWM gain, P st,i and P as,i are the powers of the parent stokes and anti-stokes pump light with i = 0, 1, 2 representing the order of the FWM process, is the group velocity dispersion and z is fiber length. As seen in Figs. 2(b)-2(d), the data are consistent with the exponential behavior of Eq. (2).
The stokes and anti-stokes light separated by the grating are each individually coupled into a fast photo-diode. To measure the correlation between conjugate wavelengths given by energy conservation (Eq. (1)), the induced photo-currents, I st+i and I as+i are fed into a phase-mixer to create sum- and difference- currents I + and I -, which are measured by a RF spectrum analyzer [19]. The difference noise current density for perfect correlation is < I 2 - > = 0 while for two completely uncorrelated wavelengths < I 2 - > = < I 2 + > assuming equal detection efficiencies. A ratio characterizes the noise cross-correlation between the two wavelengths. For equal detection efficiencies, and perfect correlation between the two wavelengths, Γ approaches unity.
The measured noise cross-correlations (Fig. 3) show that the two second-order wavelengths (λas-2 and λst+2) have higher cross-correlation than the two first-order wavelengths (λas-1 and λst+1). The correlation increases with power and saturates at high power, where the difference-noise falls below the sum-noise by 14 dB for the first order, and 24 dB for the second order. We recall that the two frequency-conjugate inputs to MF2 were selected from the spontaneous degenerate FWM output of MF1, where the difference-noise falls below the sum-noise by 3.6 dB. (The light coupling-out efficiency from MF2 is 80%, the grating efficiency is 90% and the detector efficiency is 80%.) This is close to the maximum noise correlation of 5 dB measured in a previous degenerate FWM experiment with a single pump wavelength [18]; while in our experiment the subsequent cascaded FWM in MF2 creates twin wavelengths with much higher cross-correlations. Considering that the two FWM processes in MF1 and MF2 are inherently cascaded, a 10 dB increase (difference-noise falling below the sum-noise) is obtained for each higher order cascaded process. (The cross-correlation between the third- and higher-order Stokes and anti-Stokes wavelengths could not be resolved due to limited detection sensitivity.)
It is known that purely classical noise sources can also result in < I 2 - > = 0 and Γ = 1. A number of approaches can be used to differentiate between classical and non-classical effects. One way is to compare the difference-noise with the shot noise limit [18], another way is to examine the violation of classical probability [24]. For our experiment, we used yet another method to examine the non-classicality. We varied the wavelengths of one of the two inputs to MF2, and observed the wavelengths of the created spectral side bands shifting correspondingly. We saw the measured sum-noise remain nearly constant, while the difference-noise rose to the level of the sum-noise. This decreased correlation shows that the spontaneous non-degenerate FWM process is replaced by the stimulated degenerate FWM process in MF2 as we vary the wavelength. In our previous publication [25], we discussed how the spontaneous FWM process is a quantum process. Hence, the noise correlation measurement, together with the gain measurement, strongly suggests that spontaneous non-degenerate FWM also dominates in the cascaded process in creating the stokes and anti-stokes wavelengths, as well as dominating the creation of two-photon light at the middle frequency. When repeating the same type of experiment with a different microstructure fiber which has similar nonlinear gain but different dispersion properties, we did not observe correlation between those two wavelengths in the side spectral bands, suggesting that dispersion plays an important role. It is known that for a dual-pump wavelength process in an optical fiber, several third-order nonlinear processes such as degenerate FWM, non-degenerate FWM, and Bragg scattering can occur, each with different phase-matching conditions [26, 27]. In practice there can be significant interactions between these processes via their phase-matching conditions. With appropriate dispersion management, one nonlinear process can be enhanced while other processes are relatively suppressed. In our experiment, by arranging to have the non-degenerate FWM dominate at the middle frequency, we observe its dominance in creating the higher order side spectral bands as well.
In conclusion, we have measured, for the first time, increased classical cross-correlation for high order wavelength-matched stokes and anti-stokes light created from a cascaded FWM process, suggesting the dominance of spontaneous non-degenerate FWM in the interaction. The demonstrated correlation feature may have potential for producing highly correlated twin beams, and correlated two-photon light. This correlation feature depends on the fiber dispersion, as evidenced by our tests with different fibers and the variation of pump wavelength in the experiment. Theoretical work is needed to understand the fundamental physics that generates this correlation feature, to guide our future experimental studies. This analysis is under way.
Acknowledgments
This work was supported in part by the MURI Center for Photonic Quantum Information Systems (ARO/DTO program DAAD19-03-1-0199) and the DTO entangled source programs. LJW thanks the support of JST (CREST).
Footnotes
* | Certain trade names and company products are mentioned in the text or identified in an illustration in order to specify adequately the experimental procedure and equipment used. In no case does such identification imply recommendation or endorsement by the National Institute of Standards and Technology, nor does it imply that the products are necessarily the best available for the purpose. |
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