Abstract
Multiple quantum modes in correlated fields are essential for future quantum information processing and quantum computing. Here we report the generation of multi-mode phenomenon through parametric amplified four- and six-wave mixing processes in a rubidium atomic ensemble. The multi-mode properties in both frequency and spatial domains are studied. On one hand, the multi-mode behavior is dominantly controlled by the intensity of external dressing effect, or nonlinear phase shift through internal dressing effect, in frequency domain; on the other hand, the multi-mode behavior is visually demonstrated from the images of the biphoton fields directly, in spatial domain. Besides, the correlation of the two output fields is also demonstrated in both domains. Our approach supports efficient applications for scalable quantum correlated imaging.
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Introduction
Multi-mode is a fundamental characteristic for quantum information technologies1,2. The capacity of a communication system will be extremely expanded with multi-mode in the frequency domain, while quantum imaging is possible only when different spatial regions belong to different modes3,4. Recently, multi-mode properties shared between correlated5,6 and entangled fields7,8,9,10 have attracted immense attention. One of the competitive candidates is a pair of correlated fields11 by non-degenerate four-wave mixing (FWM) process in rubidium vapor, where hundreds of spatial modes could be achieved12. The FWM system has no requirement for an optical cavity due to the embedded nonlinearity and spatial separation of the twin output fields13, so it is easy to be adjusted in the experiment. Moreover, the FWM system has narrow bandwidth and high generation rate14 and could be treated as a phase-insensitive amplifier15 with low noise. Thus it could be applied to further multi-mode configurations such as cascaded FWM16 process and quantum network, while it is also favorable in quantum entangled imaging17,18,19, nonclassical squeezing states20,21,22 and coherent slow light.
In this paper, we deepen the multi-mode research in a system coexisting of four- and six-wave mixing (SWM)23,24. Compared with the pioneering FWM configuration25, our system shows better responses to the dressing modulation. In frequency domain, the multi-mode appears as one non-degenerate signal peak splits into multiple peaks on the spectrum. Such splitting can be attributed to the both the internal and external dressing effects26. Then in the spatial domain, we observed that different points on the light-spot image show non-synchronous responses versus the change of detuning. This provides a solid evidence that those points are in different spatial mode, from which we can deduct one hundred or more spatial modes exist in one beam. Besides, the intensity correlation can be observed in both domains27.
Results
At the beginning, when we only apply a strong pumping field E1, the three level “double-Λ” rubidium (Rb) atomic configuration is formed, involving two hyperfine ground states of 5S1/2 [F = 2 (|0〉) and F = 3 (|1〉)] and an excited state 5P3/2 (|2〉). The spatial beams alignment and energy-level diagram are shown in Fig. 1(a1,b), respectively. When E1 (frequency ω1, wave vector k1, Rabi frequency G1, vertical polarization) is set as 780.23 nm with power up to 100 mW and the temperature of media set as around 145 °C, a spontaneous parametric4 FWM process is triggered and generates a pair of Stokes (ωs) and anti-Stokes (ωas) fields. The two generated fields are symmetric to the axis of E1 with the angle of 0.26°, satisfying the phase matching conditions ks = 2k1 − kas and kas = 2k1 − ks. Then the weak probe field Ep (ωp, kp, Gp, horizontal polarization, 400 μW) intersects with E1 inside the Rb cell with the same angle of 0.26°. When the frequency of Ep is the same as Stokes or anti-Stokes signal (ωp = ωs or ωp = ωas), Ep could be treated as injected into Stokes or anti-Stokes field, while the other non-injected port is termed as the conjugate channel. Thus the parametric amplified28 four-wave mixing (PA-FWM) is formed by the injection, where both Stokes and anti-Stokes fields are amplified. The intensities of Stokes and anti-Stokes fields are proportional to and , respectively. Here and are the third-order density matrix elements, obtained by the Liouville pathways (perturbation chains) (Stokes field) and (anti-Stokes field), and shown as
where Gij = μijEij/ħ (j = s and as) is the Rabi frequency, Γij = (Γi + Γj)/2 is the decoherence rate between |i〉 and |j〉; Δi is the detuning between the resonant transition frequency Ωi and the laser frequency ωi of Ei, denoted as ∆i = Ωi − ωi. And we define , , , , , . causes the nonlinear gain peak in Stokes field at the non-degenerate window Δ1 − Δs = 0 when probe beam has the same frequency with Stokes field, i.e. Δp = Δs, where is the detuning of probe field. While causes nonlinear gain in anti-Stokes field at when ΔP = Δas.
Next, we add E2 (ω2, k2, G2, wavelength of 776 nm) at the opposite direction of E1 as injection into Stokes field, shown in Fig. 1(a1,b). E2 acts as a dressing field connecting the transition 5P3/2 (|2〉) to 5D5/2 (|3〉). The presence of E2 will lead to an electromagnetically induced absorption (EIA)29, i.e. a dip in the probe transmission signal. If the EIA overlaps with the PA-FWM gain peak, the parametric amplified six-wave mixing (PA-SWM) is formed in the four-level inverted Y-type atomic configuration. The phase matching conditions for the PA-SWM are ks = 2k1 − kas + k2 − k2 and kas = 2k1 − ks − k2 + k2, shown in Fig. 1(a2). Then the intensity of PA-SWM is associated with the fifth-order density matrix elements, and , which are introduced by the perturbation chain (anti-Stokes field) and (Stokes field). Thus, the overall multi-wave mixing (MWM)30 system, i.e. the co-existing of PA-FWM and PA-SWM could be shown as FWM signal dressed by E2. Then Eqs (1 and 2) can be modified as
where the terms are defined as following: , , , . One can easily prove that and through Taylor Expansion.
Experimentally, we scan the probe detuning ∆p over 14.0 × 2π GHz when ∆1 is around −1.1 × 2π GHz, then the signals in both probe and conjugate channels are shown on spectrum as Fig. 1(c). There are two positions triggering the non-degenerate MWM signals of 85Rb: ∆p = 1.9 × 2π GHz and −4.1 × 2π GHz, which correspond to ωp−ω1 = −3.0 × 2π GHz and 3.0 × 2π GHz, respectively. Here ωp − ω1 < 0 means probe beam is injected into Stokes field, while ωp−ω1 > 0 shows it is injected into anti-Stokes field; ωp−ω1 = 0 GHz is the resonance point. Specifically, at ωp−ω1 = −3.0 × 2π GHz, the transition of probe field is F = 3 → F′, and the conjugate is F = 2 → F′; on the contrary, at ωp−ω1 = 3.0 × 2π GHz, the probe and conjugate fields stem from 85Rb, F = 2 → F′ and 85Rb, F = 3 → F′ transitions, respectively. The two triggering points are symmetric to ωp − ω1 = 0, and the 6 × 2π GHz frequency difference between the two points is exactly the frequency gap between Stokes and anti-Stokes fields. The strong symmetry suggests the Stokes and anti-Stokes fields are strongly correlated both in frequency and spatial domains.
Generally, the probe and conjugate non-degenerate peaks raise exactly at the same ∆p in each case, while sometimes they have a frequency deviation (denoted in Fig. 1(c)), which stems from the relaxed phase matching condition12. As Stokes and anti-Stokes fields are beams with certain bandwidths, we can define ϖs, ϖas as the central frequencies of Stokes and anti-Stokes signals, respectively, in the ideal phase matching condition. Then the realistic frequencies are obtained as ωs = ϖs + δ and ωas = ϖas − δ, where δ is the phase-mismatch in frequency.
In addition, we introduce vector ∆k denoting the phase mismatch in space31,32, where
The equation shows the relationship between ∆k and δ, and the phase mismatching diagram is shown in Fig. 1(a3). vs, vas are the group velocities of Stokes and anti-Stokes signals, and k10, k s0, k as0 are the unit vectors of pump, Stokes and anti-Stokes beams, respectively. Since phase mismatch indicates the multi-mode properties of signals, the relationship of δ and ∆k demonstrates the concord of multi-mode in both frequency and spatial domains. The detailed deductions and expressions of theoretical models are in Supplementary Information.
We begin with the case of frequency multi-mode through FWM. Here only pump beam E1 and probe beam Ep interact inside the rubidium vapor, which forms a PA-FWM process. Due to the strong internal dressing effect of E1, the Stokes or anti-Stokes peak splits into two peaks in Fig. 2(a1,a2). That is the so-called Autler-Townes splitting33, where the excited state 5P3/2 (|2〉) is splited by E1. Multiple split-peaks are direct evidences of multi-mode in frequency domain. Specifically, by increasing the diameter of E1, the intensities of both Stokes and anti-Stokes PA-FWM gain peaks first grow to maxima then decrease. Moreover, there exists the competition between the left and right portion of the signal: in Fig. 2(a1) of Stokes signal, the left peak dominates at the beginning, then the difference of the left and right peak vanishes gradually, finally the right peak becomes more prominent; while the case of anti-Stokes in Fig. 2(a2) is just the contrary.
Here the splitting is caused by the internal-dressing effect of E1, whose diameter is associated with the nonlinear phase modulation34. Since the intensities of Stokes and anti-Stokes gains are proportional to the square form of density matrix elements and respectively, where
For the sake of frequency multi-mode, the phase mismatch term δ is introduced. Besides, an additional nonlinear phase shift factor eiΦ is introduced35 via cross-Kerr effect36 from the internal-dressing effect of E1, compared with Eqs (1 and 2). See Methods section for the theory of nonlinear phase shift and cross-Kerr effect. The maxima of and occur at and , respectively, which further correspond to the enhancement conditions and . While δs = 0 and δas = 0 correspond the suppression conditions Δs = Δ1 and , respectively. The parameters are Δ1 = −1.1 × 2π GHz, GHz and the detailed dressing energy diagram is showed in Fig. 2(c). Thus, the splitting of single peak into double is caused by enhancement conditions, while the dip between the double peaks corresponds to the suppression condition. By adjusting the pump beam diameter, the relative position of pump and probe beams will be changed, which tends to vary the nonlinear phase shift Ф. Theoretically, the change of Ф leads to the movement of E1-induced splitting energy levels, which means the switch of enhancement and suppression. And when the diameter changes from 0.8 mm to 3.2 mm, Ф goes through 1.625 π. The normalized theoretical simulations (Fig. 2(b1,b2)) fit perfectly with experiments (Fig. 2(a1,a2)). Besides, varying Ф also changes the distance of splited peaks from 20 to 300 MHz, which is the bandwidth of δ, i.e. the bandwidth of multimode. Concisely, multi-mode could be caused by internal dressing effect, and the properties are controlled by nonlinear phase shift.
Next, we focus on the properties of frequency multi-mode in SWM process by adding a dressing beam E2. In order to avoid the internal-dressing effect, power of E1 is lowered. In Fig. 3(a1), it is observable that E2 will lead to a small dip on the intensity profile of PA-FWM, which is caused by EIA of E2. Increasing ∆2 over 0.3 × 2π GHz around 776.1605 nm (∆2 = 1.65 × 2π GHz), the EIA dip moves with ∆2 in Fig. 3(a1); when the EIA overlaps exactly with the PA-FWM gain peak (circled in Fig. 3(a1)), the PA-SWM process will be formed and the anti-Stokes gain peak (Fig. 3(a2)) will be enhanced in probe channel, and the corresponding anti-Stokes signal in conjugate channel (Fig. 3(b1)) is enhanced as well. However, due to the phase-matching condition ks = 2k1 − kas + k2 − k2 and energy conservation in Stokes and anti-Stokes fields, the enhancement of anti-Stokes signal leads to the Stokes peak in conjugate channel (Fig. 3(b2)) impaired.
Theoretically, considering the phase mismatch caused by the external dressing effect of E2, Eqs (3 and 4) can be expressed as
Here with the parameters set as ∆1 = −1.07 × 2π GHz and ∆2 = 1.65 × 2π GHz and power of E2 being 24 mW, the normalized simulations of Eqs (8 and 9) are shown as Fig. 3(c1,c2) for Stokes and anti-Stokes signals, respectively. Both Stokes and anti-Stokes signals have three maxima, denoted as δs−, δs0, δs+, and δas−, δas0, δas+, where δs0 = δas0 = 0. The intensities at δs0 = δas0 = 0 are much greater than others, so this case happens only at δs0 = δas0 = 0, which means no frequency mismatch. To sum up, weak external dressing effect will not lead to multi-mode.
Subsequently, in Fig. 4 we discuss the case that SWM multi-mode formed by strong external dressing effect of E2. Here, the detuning of pump field E1 is ∆1 = −1.61 × 2π GHz, ∆2 = 2.15 × 2π GHz, and power of E2 is 80 mW, i.e. with larger detunings and greater dressing power. Hence the dressing effect is more obvious, and the dressing energy diagram is shown in Fig. 4(f). Experimentally, when the E2-induced EIA overlaps with PA-FWM signal (circled on Fig. 4(a1)), the PA-SWM is generated. However, the anti-Stokes signal in probe field splits further into three or more smaller peaks, highlighted in Fig. 4(d1). The splitting will cause the peak intensity to lower down, as well as anti-Stokes signal in conjugate field to be impaired (Fig. 4(b1)), whose splitting details are shown in Fig. 4(d2). Due to the energy conservation in Stokes and anti-Stokes fields, the suppression in anti-Stokes field leads to the enhancement of Stokes field (Fig. 4(b2)), while Stokes signal also splits into multiple peaks (Fig. 4(d3)).
In contrast with Fig. 2, external dressing effect of SWM causes division to at least three peaks, while internal dressing effect of FWM only causes double peaks. This suggests SWM will lead to more modes than FWM system. Besides, the Stokes and anti-Stokes signals will not appear simultaneously at the same ∆p as shown in Fig. 3(e), where the deviation is the phase mismatch δ in frequency domain. We can measure that δ = 186.66 MHz here.
Theoretically, we also conduct Stokes and anti-Stokes simulations versus phase mismatch δ by Eqs (8 and 9), shown in Fig. 4(c1,c2). There are still three maxima for every signal. However, compared with Fig. 3(c1,c2), the relative intensities at nonzero δs−(δas−), δs+(δas+) to δs0(δas0) are stronger, which means the Stokes (anti-Stokes) signal has larger probability to appear at δs−(δas−) or δs+(δas+). The simulations suggest that stronger dressing effect will result in larger probability of phase mismatch and multi-mode. In short, the multi-mode phenomenon of FWM is caused by internal dressing effect, while in case of SWM, it is subjected to strong dressing effect of E2. Besides, SWM has better potential to achieve more modes than FWM.
After discussion about multi-mode in frequency domain, in Fig. 5 we study multi-mode in spatial domain through light-spot images (detected by a charge coupled device camera, CCD) of probe and conjugate fields. We set ∆p = ∆s so the probe field is injected into Stokes field (while the conjugate channel means anti-Stokes field), and change Δ1 from −0.9 × 2π GHz to 0.3 × 2π GHz. Theoretically, with the phase-mismatch δ in frequency, we have ∆k = δ((1/vas)kas0 − (1/vs)ks0) from Eq. (5), then spatial multi-mode appears. Provided Ep is not injected, each pair of correlated Stokes and anti-Stokes photons could distribute evenly between the ideal Stokes and anti-Stokes cones due to the perfect symmetry37 (Fig. 5(a1)), so at a certain cross-section of pump axis, the intensity of photon appears evenly on a circular ring (Fig. 5(a2)). Next, when applying Ep in our experiments, the intensities in probe and conjugate fields are amplified with multiples of G and (G−1)38 (Fig. 5(b1,b2)), which provides a better chance for the detection, but the spatial multi-mode distribution is unaffected.
Experimentally, the detailed spatial images of both probe (Stokes) and conjugate (anti-Stokes) fields are shown. Initially, we focus on the evolutions of Stokes and anti-Stokes spatial images versus ∆1 in Fig. 5(c1. Generally, the size of both fields become larger by increasing ∆1; and the fields intensities are strengthened. Specifically, the shape of the spatial mode varies with ∆1. In Fig. 5(c1), the Stokes image remains almost the same as the intensity is too strong that we cannot observe too many details. While in Fig. 5(c2) for anti-Stokes, at first (Δ1 = −0.9 × 2π GHz) there is only one small bright spot (denoted on figures by circle), later three more spots (denoted on figures by oval, square and triangle, respectively) appear subsequently as Δ1 gradually changes to −0.4 × 2π GHz. As the four spots have different responses for ∆1, it testimonies that the four spots represent different spatial modes. So instead of using noise figure (NF)12, we prove spatial multi-mode via carefully analyzing the details of light spot images. Moreover, the intensity correlation is also proved. For example, with changing Δ1 in Fig. 5(d1,d2), one pair of corresponding points of Stokes and anti-Stokes fields (denoted by circles) are getting bright or dark together from −0.3 × 2π to 0.2 × 2π GHz, which means they are correlated in intensity. Other pair of points denoted by squares, triangles and ovals are also correlated, respectively. This phenomenon directly suggests the corresponding spatial modes in Stokes and anti-Stokes fields are strongly correlated in intensity, while the study on noise and squeezing correlation has been presented by Paul Lett group previously4,11.
The observations can be clearly interpreted by the theory. Applying Eqs (6 and 7) to show the dressing effect of E1, the normalized simulations of Stokes and anti-Stokes signals versus δ at different ∆1 are shown as Fig. 5(f1,f2). The Stokes simulations have two discrete peaks while anti-Stokes have four peaks, and the positions of the peaks are still denoted by δs and δas, respectively. Firstly, the absolute values of δas are generally much larger than δs, so it is reasonable that there are more spatial modes in anti-Stokes than Stokes field. The deduction fits well with the appearance that there are more light spots in the images of anti-Stokes (Fig. 5(c2,d2)) than Stokes (Fig. 5(c1,d1)). Moreover, by changing ∆1, the absolute value of δas generally grow higher (Fig. 5(f2), from left to right), which indicates larger phase mismatch and more spatial multi-modes. It is true that we have more modes with changing ∆1, in Fig. 5 (c2,d2, from left to right).
The detailed spot images and multi-mode correlation at ∆1 = 0.3 GHz are shown in Fig. 5(e1,e2). The number of modes is calculated as N = A(QPM)/A(one), where A(QPM) is the quasi-phase-matched area, A(one) is the area of one mode3. If we assign the circled mode as a standard mode area, by comparing the area of the single mode and the whole circular light spot image, it can be calculated that we have totally 112 spatial modes in our observations. So at least one hundred spatial modes exist in one field, and the spatial modes of Stokes and anti-Stokes fields are correlated.
Methods
Experimental setup
The pump beam E1 is emitted from a continuous Ti:sapphire laser of 20–100 mW, meanwhile the probe beam Ep is excited by an external cavity diode laser (ECDL). The two beams are of orthogonal polarization, intersecting at the rubidium cell, which couple the three-level “double-Λ” PA-FWM configuration. If dressing beam E2 (30 mW, from another ECDL) is injected opposite to E1, the four-level “inverted-Y” PA-SWM process is formed. The 1 cm rubidium cell is of natural abundance, including both 85Rb and 87Rb, and wrapped by μ-metal and heated by a heater tape. Both the probe and conjugate signals are detected by a balanced photodetector (105 V/A) with the diameter of around 0.5 cm, or shot by a CCD.
Nonlinear phase shift and cross-Kerr effect
The so-called cross-Kerr effect occurs when a weak probe beam interacts with a strong pump beam, then the spatial orientation of probe beam will be shifted, and a nonlinear term, n2, will be added into the refractive index at the intersection point. Here we have where the density matrix element , Gc is the Rabi frequency of conjugate field, and χ(3) is the third-order nonlinear susceptibilities. The nonlinear phase shift Ф is introduced as , where kp is the length of probe field wave vector.
Additional Information
How to cite this article: Zhu, D. et al. Multi-mode of Four and Six Wave Parametric Amplified Process. Sci. Rep. 7, 43689; doi: 10.1038/srep43689 (2017).
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References
Duan, L. M., Lukin, M. D., Cirac, J. I. & Zoller, P. Long-distance quantum communication with atomic ensembles and linear optics. Nature. 414, 413 (2001).
Nielsen, M. A. & Chuang, I. L. Quantum computation and quantum information (Cambridge University Press, 2010).
Devaux, F. & Lantz, E. Spatial and temporal properties of parametric fluorescence around degeneracy in a type I LBO crystal. Eur. Phys. J. D. 8, 117–124 (2000).
Boyer, V., Marino, A. M., Pooser, R. C. & Lett, P. D. Entangled images from four-wave mixing. Science 321, 544–547 (2008).
Lukin, M. D., Hemmer, P. R., Löffler, M. & Scully, M. O. Resonant enhancement of parametric processes via radiative interference and induced coherence. Phys. Rev. Lett. 81, 2675–2678 (1998).
Lukin, M. D., Matsko, A. B., Fleischhauer, M. & Scully, M. O. Quantum noise and correlations in resonantly enhanced wave mixing based on atomic coherence. Phys. Rev. Lett. 82, 1847–1850 (1999).
Qin, Z. Z. et al. Experimental generation of multiple quantum correlated beams from hot rubidium vapor. Phys. Rev. Lett. 113, 023602 (2014).
Yan, H. et al. Generation of narrow-band hyperentangled nondegenerate paired photons. Phys. Rev. Lett. 106, 033601 (2011).
Kwiat, P. G. et al. New high-intensity source of polarization-entangled photon pairs. Phys. Rev. Lett. 75, 4337 (1995).
Balić, V., Braje, D. A., Kolchin, P., Yin, G. Y. & Harris, S. E. Generation of paired photons with controllable waveforms. Phys. Rev. Lett. 94, 183601 (2005).
McCormick, C. F., Marino, A. M., Boyer, V. & Lett, P. D. Strong low-frequency quantum correlations from a four-wave-mixing amplifier. Phys. Rev. A. 78, 043816 (2008).
Corzo, N. V., Marino, A. M., Jones, K. M. & Lett, P. D. Noiseless optical amplifier operating on hundreds of spatial modes. Phys. Rev. Lett. 109, 043602 (2012).
Fang, Y. M., Feng, J. L., Qin, Z. Z., Wang, Y. X. & Jing, J. T. Experimental implementation of a nonlinear beamsplitter based on a phase-sensitive parametric amplifier. Appl. Phys. Lett. 108, 131106 (2016).
Thompson, J. K., Simom, J., Loh, H. & Vuletić, V. A high-brightness source of narrowband, identical-photon pairs. Science. 313, 74 (2006).
Pooser, R. C., Marino, A. M., Boyer, V., Jones, K. M. & Lett, P. D. Low-noise amplification of a continuous variable quantum state. Phys. Rev. Lett. 103, 010501 (2009).
Qin, Z. Z., Cao, L. M. & Jing, J. T. Experimental characterization of quantum correlated triple beams generated by cascaded four-wave mixing processes. Appl. Phys. Lett. 106, 211104 (2015).
Lopez, L., Treps, N., Chalopin, B., Fabre, C. & Maitre, A. Quantum processing of images by continuous wave optical parametric amplification. Phys. Rev. Lett. 100, 013604 (2008).
Boyer, V., Marino, A. M. & Lett, P. D. Generation of spatially broadband twin beams for quantum imaging. Phys. Rev. Lett. 100, 143601 (2008).
Vasilyev, M., Stelmakh, N. & Kumar, P. Phase-sensitive image amplification with elliptical Gaussian pump. Opt. Express. 17, 11415–11425 (2009).
Slusher, R. E., Hollberg, L. W., Yurke, B., Mertz, J. C. & Valley, J. F. Observation of squeezed states generated by four-wave mixing in an optical cavity. Phys. Rev. Lett. 55, 2409–2412 (1985).
McCormick, C. F., Boyer, V., Arimondo, E. & Lett, P. D. Strong relative intensity squeezing by four-wave mixing in rubidium vapor. Opt. Lett. 32, 178–180 (2007).
Liu, C. C. et al. Realization of low frequency and controllable bandwidth squeezing based on a four-wave-mixing amplifier in rubidium vapor. Opt. Lett. 36, 2979–2981 (2011).
Zhang, Y. P., Brown, A. W. & Xiao, M. Opening four-wave mixing and six-wave mixing channels via dual electromagnetically induced transparency windows. Phys. Rev. Lett. 99, 123603 (2007).
Zhang, Y. P., Anderson, B. & Xiao, M. Efficient energy transfer between four-wave-mixing and six-wave-mixing processes via atomic coherence. Phys. Rev. Lett. 77, 061801(R) (2008).
Zhang, Z. Y. et al. Dressed gain from the parametrically amplified four-wave mixing process in an atomic vapor. Sci. Rep. 5, 15058 (2015).
Nie, Z. et al. Interacting multiwave mixing in a five-level atomic system. Phys. Rev. A. 77, 063829 (2008).
Zhang, Y. P., Khadka, U., Anderson, B. & Xiao, M. Temporal and spatial interference between four-wave mixing and six-wave mixing channels. Phys. Rev. Lett. 102, 013601 (2009).
Chen, H. et al. Parametrically amplified bright-state polariton of four- and six-wave mixing in an optical ring cavity. Sci. Rep. 4, 3619 (2014).
Dimitrijević, J., Arsenović, D. & Jelenković, B. M. Intensity dependence narrowing of electromagnetically induced absorption in a Doppler-broadened medium. Phys. Rev. A. 76, 013836 (2007).
Zhang, Y., Wen, F. & Xiao, M. Quantum control of multi-wave mixing (John Wiley & Sons, 2013).
Bencheikh, K., Huntziger, E. & Levenson, J. A. Quantum noise reduction in quasi-phase-matched optical parametric amplification. J. Opt. Soc. Am. B. 12, 847–852 (1995).
Du, S. W., Wen, J. M., Rubin, M. H. & Yin, G. Y. Four-wave mixing and biphoton generation in a two-level system. Phys. Rev. Lett. 98, 053601 (2007).
Zhang, Y. P. et al. Evidence of Autler-Townes splitting in high-order nonlinear processes. Opt. Lett. 35, 3420–3422 (2010).
Li, P. Y. et al. Phase control of bright and dark states in four-wave mixing and fluorescence channels. Appl. Phys. Lett. 101, 081107 (2012).
Fang, Y. M. & Jing, J. T. Quantum squeezing and entanglement from a two-mode phase-sensitive amplifier via four-wave mixing in rubidium vapor. New J. Phys. 17, 023027 (2015).
Zhang, Y. P. et al. Electromagnetically induced spatial nonlinear dispersion of four-wave mixing. Phys. Rev. A. 80, 013835 (2009).
Dawes, A. M., Illing, L., Clark, S. M. & Gauthier, D. J. All-optical switching in rubidium vapor. Science. 308, 672–674 (2005).
Chen, H. X. et al. Parametric amplification of dressed multi-wave mixing in atomic ensemble. Laser Phys. Lett. 11, 045201 (2014).
Acknowledgements
This work was supported by the 973 program (No. 2012CB921804), the National Nature Science Foundation of China (No. 61308015, 11474228), and the Key Scientific and Technological Innovation Team of Shaanxi Province (No. 2014KCT-10).
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D.Y.Z., Y.H.Y. and D.Z. wrote the main manuscript and contributed to the theoretical and experimental analysis. Y.P.Z. provided the idea. R.Z.L., D.M.M. and C.B.L. contributed to the presentation and execution of the work. All authors discussed the results and contributed to the writing of the manuscript.
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Zhu, D., Yang, Y., Zhang, D. et al. Multi-mode of Four and Six Wave Parametric Amplified Process. Sci Rep 7, 43689 (2017). https://doi.org/10.1038/srep43689
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