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Coherence and multimode correlations from vacuum fluctuations in a microwave superconducting cavity

Abstract

The existence of vacuum fluctuations is one of the most important predictions of modern quantum field theory. In the vacuum state, fluctuations occurring at different frequencies are uncorrelated. However, if a parameter in the Lagrangian of the field is modulated by an external pump, vacuum fluctuations stimulate spontaneous downconversion processes, creating squeezing between modes symmetric with respect to half of the frequency of the pump. Here we show that by double parametric pumping of a superconducting microwave cavity, it is possible to generate another type of correlation, namely coherence between photons in separate frequency modes. The coherence correlations are tunable by the phases of the pumps and are established by a quantum fluctuation that stimulates the simultaneous creation of two photon pairs. Our analysis indicates that the origin of this vacuum-induced coherence is the absence of which-way information in the frequency space.

Introduction

A direct consequence of the Heisenberg uncertainty principle is that quantum fields, even in the vacuum state, are teeming with fluctuations. Modern quantum field theory predicts that these fluctuations are not only a useful mathematical representation but also they can produce observable effects, encompassing vastly different physical scales—from atoms to black holes. Among these are the Purcell effect1, the Lamb shift of the atomic states2, the Schwinger effect3, the Hawking radiation4 and the Casimir effect5.

Recently, in parallel to the interest in fundamental physics6, a novel approach has emerged—the idea of engineering the quantum vacuum to create novel devices and protocols for quantum technologies7. Parametrically modulated superconducting circuits have attracted significant interest8,9,10, motivated also by the demand for parametric amplifiers where the added noise is pushed to the quantum limit11,12,13,14,15. In these systems, it has been demonstrated that vacuum fluctuations present at the input port trigger the creation of real microwave photons16,17,18,19,20,21,22. Some of these experiments provide beautiful analogies with the motion of a mirror in free space20,21,23,24, also referred to as dynamical Casimir effect. For the development of quantum computing with continuous variables (CV) in microwave circuits25, these results demonstrate that a key operation is now available experimentally: two-mode squeezing26,27 of the modes a and b, leading to a non-zero correlation 〈ab〉≠0. However, there exists another fundamental type of correlation between microwave fields, yielding 〈ab〉≠0, which is instrumental in CV quantum computing. This is a measure of coherence of the fields in the two modes, and it appears ubiquitously in the modelling of beam-splitter and interference phenomena. From the perspective of quantum vacuum engineering, achieving this correlation is problematic: vacuum fluctuations at different times and frequencies are completely uncorrelated. This is such a precise feature, that vacuum fluctuations can even serve as perfect random number generators28. Even when the fluctuations trigger, the downconversion of a higher-energy photon into two photons in modes a and b, as in the case of a single-pump dynamical Casimir effect, the correlation 〈ab〉 remains zero.

Here we demonstrate that two-mode coherence correlations can be obtained from the dynamical Casimir effect by employing another fundamental quantum mechanical principle, namely the absence of which-way information29,30, which is applied here in the frequency space. Specifically, we study the parametric modulation of the quantum vacuum under the action of two pumps. We demonstrate that a nonzero coherent correlation is established between two frequency modes and , through downconversion processes in the two pumps triggered by the same vacuum fluctuation in a third-frequency mode . This correlation is non-zero provided that it is not possible to specify from which pump the downconverted photons at mode originate from. In addition, due to this coherence effect, a highly populated bright mode and, orthogonal to it, a zero-population dark mode can be defined in the subspace of the two frequency modes. Dark states appear as a result of destructive quantum interference. Typically, in atomic physics, optics and more recently in superconducting microwave systems, dark states appear in Rabi-driven multilevel quantum systems31,32,33,34,35,36, or, in the case of resonators, through sideband driving37,38, both of which require Hamiltonians of the type ab+h.c. to simply transfer population from one level to another. In contrast, here our Hamiltonian is of parametric type aa+h.c., which creates populations from the vacuum instead of transferring quanta between modes. We also show that this parametric coherence effect is a phase-sensitive phenomenon and, therefore, it can be controlled by the relative phase of the applied pumps. Our result opens a way for realizing highly complex multi-mode entangled states displaying both coherence and squeezing correlations with CV. In terms of the modes , and , the state we created is a CV tripartite state39,40 of bisymmetric type41,42, which at low powers, in the subspace with at most two photons, becomes a W-type state43. Tripartite bisymmetric states are a resource for protocols such as one-to-two telecloning44,45, while W states can be used for fundamental tests of quantum mechanics46,47. Our approach can be generalized in a straightforward way to multiple modes and pumps, opening the way to the implementation of algorithms such as bosonic sampling48 and the realization of CV cluster states for one-way quantum computing49,50 in the microwave regime.

Results

Theoretical predictions

Our system consists of a superconducting resonator (see Fig. 1) which can be described by the effective Hamiltonian21

Figure 1: Overview of the measurement setup and pumping.
figure1

(a) Simplified schematic representation of the measurement setup (see Supplementary Figs 3 and 4 from Supplementary Note 7 for more detailed schematics). The investigated resonator was made using a capacitively shunted superconducting quantum interference device (SQUID), fabricated using a NbAlOxNb trilayer process at VTT57. The device forms a flux tunable resonator which acts as a tunable boundary condition for the reflected waves in the attached 50 Ω transmission line21. The resonance is tuned down from the maximum value (nominally 10 GHz) to 5 GHz using dc-flux biasing. The designed critical current for the junctions of the SQUID was IC=33 μA, and the total parallel capacitance was C=40 pF. We estimate the effective temperature to remain below 35 mK at the highest pumping powers used in these experiments while the cryostat base temperature is held at 15 mK. This corresponds to thermal occupation number =10−3. Modulation of the flux through the SQUID is realized through a lithographically fabricated rectangular spiral coil underneath the junction layer. (b) Illustration of the first reflections of a frequency ξ=ωωres with respect to half the pump frequencies. The short-hand notation of modes , , and signifies the cavity output modes , , and , respectively.

where αp is the strength of pump p coupled into the resonator, in units of frequency, and specifies the pump phase. Denoting the decay rate of the resonator by κ and setting ξ=ωωres, the output field is obtained within the input–output formalism by solving iteratively the Heisenberg–Langevin equations (HLEs) in a rotating frame at the resonator frequency defined by . We obtain a nested structure

Here χ(ξ)=(κ/2−)−1 is the electrical susceptibility of the resonator, {1, 2}\{p}, denote normalization factors (see the Supplementary Notes 1–3), and Δp=ωp/2−ωres.

For simplification, we truncate equation (2) to the first-order reflections of ξ with respect to the pumps, and assume |Δp||ξ|. Higher-order reflection (Supplementary Fig. 1) amplitudes are suppressed by a factor proportional to the cavity susceptibility, however they can be observed experimentally at high enough pumping power (Supplementary Fig. 6). In this first-order approximation, we have , and we use a pump-power parameterization by a squeezing parameter λ and power asymmetry angle θ, , and . This allows us to calculate the correlations in the output field of the cavity , with the vacuum as the input state. We find that each pump produces squeezing correlations , as well as noise at 2Δ1ξ and 2Δ2ξ, according to the dynamical Casimir effect power noise formula21 for each pump separately, , , while at ξ the noise is produced by the action of both pumps, . Surprisingly, the simultaneous action of the two pumps produces the correlation between the frequencies 2Δ1ξ and 2Δ2ξ,

which can be regarded as a coherence between the extremal modes 2Δ1ξ and 2Δ2ξ, mediated by the middle vacuum fluctuation. From the expression of the correlations above we can construct the covariance matrix, which has a bisymmetric structure41,42. Note that, since the Hamiltonian is quadratic in the field operators, the state is Gaussian. Therefore, the first-order correlations presented here provide a complete characterization of the output field.

On the basis of the structure of equation (2) we can introduce ‘bright’ and ‘dark’ modes,

and similar relations for the output and input modes. These two modes are orthogonal to each other, spanning the Hilbert space of the extremal modes 2Δ1ξ and 2Δ2ξ. Experimentally, the asymmetry angle θ in the bright and dark modes is determined from measurements of the noise power generated by each pump through the dynamical Casimir effect. The definition of the modes and resembles a beam-splitter/merging operation in frequency (rather than in space, as in usual interferometers), where a mode is separated into two branches with a distance 2(Δ1−Δ2) between them. Indeed, when the modes and are rotated by some angles and and combined as in equations (4) and (5), this vacuum-induced coherence manifests as an interference effect, producing the extinction of power in the dark mode and the maximization of power in the bright mode. Specifically, for the correlations involving the dark and bright modes we obtain

These correlations reflect the structure of the output state of the resonator |vac〉out, which fulfils . For the truncated form of equation (2), the output state is a two-mode squeezed state in terms of the operators and , , where . In the subspace containing at most two excitations, the tripartite state is in the W class, see Supplementary Note 5.

The disappearance of power in the dark mode is a particular manifestation of coherence which has been employed for many applications, such as quantum memory35 and stimulated Raman adiabatic passage (STIRAP) in superconducting qubit systems36. Note that in the usual type of dark state, the destructive interference is produced at the same frequency, for example, on a quantum state of a qubit or of a mode of a field. Here, the two modes at 2Δ1ξ and 2Δ2ξ are separated in frequency and do not overlap51. The destructive interference effect is created by the vacuum fluctuations at ξ which trigger two correlated two-photon parametric downconversion processes in the pumps.

As for standard quantum interference, the lack of path information52,53 is critical for the interference between extremal frequencies. Here, instead of which-path information in space, we deal with absence of which-colour information29,30: for a real photon at frequency ξ, there is no way of knowing from which of the two spontaneous parametric downconversion processes it came from (see Supplementary Note 4).

Experimental results for correlations

To test the above predictions, we pumped our sample using two phase-locked microwave generators at frequencies 9.99 and 10.01 GHz. The output field from the resonator is amplified, yielding a signal that is further downconverted and digitized. The Fourier-transformed amplified field is measured in a bandwidth around the three frequencies of interest. The resulting fields are denoted by , , (see Methods), corresponding to the output fields , and , respectively. Upon substraction of the added noise of the amplifiers, the correlations between the amplified fields provide a direct measurement of the corresponding correlations of the resonator output field19,54. For additional information see Supplementary Notes 7–8. The measured noise power data can be reproduced by simulations using the theoretical results presented earlier. The data are presented in (Fig. 2a), while the corresponding numerical result from equation (2) is presented in Fig. 2b). The measured correlations, as well as the analytical and the simulation results are normalized with respect to the vacuum state values, corresponding to λ=0. Thus, the correlations at finite pumping λ≠0 are expressed in dB (with vacuum as reference). The noise power levels can also be expressed in absolute units (photon flux/Hz).

Figure 2: Noise power spectra.
figure2

(a) Measured noise power spectra corresponding to the correlator for fixed half-pump frequencies ω1/2=(2π) × 4.995 GHz, ω2/2=(2π) × 5.005 GHz at different values of the resonance frequency Δωr/2π and measurement frequency Δω/2π relative to (ω1/2+ω2/2)/2=(2π) × 5 GHz for a pump power corresponding to 20 photon flux/Hz emerging from the cavity at the centre frequency of 5 GHz. The colour bar is scaled in dB relative to vacuum. The dashed magenta lines indicate the measurement bands within which the correlation data were collected. The red lines indicate the locations of the half of the pump frequencies ω1 and ω2. The dashed yellow line indicates the symmetry point which was used for measuring the data depicted in Fig. 3. The external and internal cavity decay rates for this sample were κE=2κI≈36 MHz. (b) Noise power as predicted by equation (2) including only first-order reflections with κ=κE+κI taken from the measurement (Supplementary Fig. 2).

For symmetry reasons, we chose to analyse correlations when the microwave resonance lies at half of the average of the two pump frequencies, that is Δ1≈−Δ2, in which case the tripartite correlations are strongest.

Figure 3 displays the most relevant correlators determined as a function of the number of photons in the resonator. All these correlators can be calculated from the measured field quadratures of the output field. The simulation is based on the Langevin equation corresponding to the Hamiltonian equation (1) (see also equation (6) in Supplementary Note 1), with white noise as input, and the theoretical curves are obtained from equations (3), (6) and (9). We find that the behaviour of these correlators agrees well with the theory—squeezing correlations exist between neighbouring frequencies and vacuum-induced coherence correlations between the extremal ones. Indeed, the correlators grow nearly exponentially with the squeezing parameter, as predicted by theory. Furthermore, the ratio between various correlators is close to the expectations obtained from equation (2), with only the first-order pump reflections included.

Figure 3: Experimental correlations and theoretical predictions.
figure3

We present the measured correlators (specified in the inset label) versus photon flux/Hz at the output of the cavity measured at the centre frequency of 5 GHz; see text for the relation between the photon flux and the squeezing parameter. The symbols refer to measured data, while the curves are predictions from theory (dashed) and simulations (solid). Our simulation includes the higher order reflections and it reproduces also the residual population in the dark mode. The 3D histogram represents the measured covariance matrix corresponding to the fields and , where the mode quadratures defined as , , and , yield two-mode squeezing correlations across the first pump. For additional correlations see Supplementary Fig. 5.

From Fig. 3 we note that the coherence is preserved also in the limit of small number of photons. This shows that our result is fundamentally different from tripartite slit-interferometer schemes55, where the coherence between two modes is obtained only in the limit of a large number of photons in the pump mode.

The phase-dependent interplay between the bright and dark modes is presented in (Fig. 4a). By adjusting the phase difference of the pumps, the measured correlator power will shift from into as seen in Fig. 4a. The division of power between the dark and bright modes depends also on the asymmetry of the two pump amplitudes, that is, the parameter θ. Thus, we find θ by measuring the noise power generated by each pump separately. Figure 4b illustrates the change in the argument of the correlator when the phase of one pump is varied relative to the other one. We note that the possibility of applying phase shifts on the modes by the rotation of the pump phases is a key operation in CV quantum computing56.

Figure 4: Phase sensitivity of correlations.
figure4

(a) Bright-/dark-mode amplitude versus phase difference between the pumps and pump amplitude asymmetry parameter θ (symmetric pumps have θ=π/4). The maximum value corresponds to the bright-mode amplitude while the minimum refers to the dark mode. (b) Measured argument of the complex quadrature correlations versus , where is varied and θπ/4.

Correlations in time-domain

The creation of vacuum-induced coherence was investigated in pulsed pump tone experiments, in which the overlap of the pump signals was varied as illustrated in (Fig. 5. The results show that, in order to obtain a non-zero coherence correlation, the downconversion processes have to occur simultaneously. We observe that the coherence is reduced proportionally to the decrease of pulse overlap, while the squeezing correlations and remain. The linear dependence of the coherence correlation on the overlap can be obtained through a fully analytical relation (see Supplementary Note 6). This demonstrates that the generation of the coherence requires overlapping pump signals and simultaneous creation of photons, during which the which-colour information is not available. When the pump pulses are separated in time, the information about which pump has generated the photons becomes accessible in principle, and the coherence is suppressed.

Figure 5: Pulsed-pump measurements.
figure5

Decrease of vacuum-induced coherence when the overlap time τ of the parametric pump pulses is varied. The coherence decreases linearly (see Supplementary Note 6) as the pumps become non-overlapping. Complete vanishing of the correlation between the extremal frequencies with zero overlap of the pulses implies that the photons are created simultaneously. For this experiment the sample was replaced with a new higher Q chip with , κE≈2 MHz. The pulse width for both pump tones was 1 μs. Three other correlators specified in the inset labelling are also depicted. Dashed lines are from time domain simulations based on equation (6) from the Supplementary Note 1 and the dots are experimental data. The difference in the values of and when the pulses do not overlap is due to the asymmetric power generation by the dynamical Casimir effect in each of the pumps separately.

Discussion

Our work on tripartite microwave correlations can be extended towards multipartite entangled states49, which would yield a platform for universal quantum computation using CV, as recently proposed in ref. 25. For example, the creation of cluster states in microwave cavities would be an important step towards realizing a superconducting one-way computer. Such multipartite entangled states require pulsed microwave pumping for entangling different frequencies, a scheme that has been shown to be a fully functioning concept in our work.

Methods

Numerical evaluation of correlators

The numerically simulated results presented in Figs 2 and 3 were obtained using Gaussian (white) noise to represent the effect of the vacuum as input. In addition, higher-order reflections were included in Fig. 3 by solving the HLE in the rotating-wave approximation . The presumption of white noise is accurate for narrow bandwidths where the spectrum of quantum noise is approximately uniform. In this way, higher-order reflections are included automatically in the results.

As seen from Fig. 3, the simple tripartite analytical solution of equation (2), leading to correlators listed in equations (5)–(9), , , , , agrees quite well with the results, except for the dark-mode correlator . The disagreement can be traced to the assumption , but the numerical simulations are not limited by this approximation.

Homodyne detection of correlations

The output field of the resonator propagates through circulators and is amplified by a cryogenic low-noise high-electron-mobility transistor (HEMT) amplifier and by room-temperature microwave amplifiers. The quadratures are measured by standard homodyne methods, that is, captured using an Anritsu MS2830A signal analyser. Approximately 20 GB of data per sweep were collected and transferred to PC for later analysis. The single bins of the Fourier transformed data represent a bandwidth of 50 Hz and, therefore, spectral leakage due to used rectangular windowing is insignificant.

From the quadratures, we can construct the complex field amplitudes, calculate their Fourier components around the central and extremal frequencies, in a bandwidth BW. We can write

where f(BW)[ξ;ς] is a digital filtering function of width BW centred at the frequency ξ. Choosing ensures that , , . A simple choice is , if ς is in the interval (ξBW/2, ξ+BW/2), and 0 otherwise.

Because the added noise of the measurement chain is contained in and it is uncorrelated, its contribution will vanish when calculating the correlations of and in the case of autocorrelation, it can be subtracted as a known constant. We can obtain then directly from equations (10) and (11) all the measured correlations, for example etc.

Also, given the definitions above, the correlations in the field at the output of the cavity are adimensional; in particular, , and represent the flux of photons per bandwidth in the modes , and , respectively. This power is estimated from the increase of observed power due to pumping relative to the amplifier-noise temperature.

Pulsed parametric pumping

In pulsed measurements, the pumping tones (corresponding to 50 photon flux/Hz in continuous operation emerging from the cavity at the centre frequency of 5 GHz) were modulated using a pair of mixers (Marki M10220LA), driven by digital delay generators from Stanford Research System (DG535). The system provides an ON/OFF ratio of 1:100 and a rise time of 10 ns. The repetition rate was set to 250 kHz, which resulted in signals of 30% when compared with continuous measurements. With a pulse width of 1 μs, the repetition rate corresponds to a duty cycle of 1:3. The same method of simulating the HLEs in time domain was employed to calculate numerically the response for pulsed pump tones.

Data availability

The data that support the findings of this study are available from the corresponding author upon request.

Additional information

How to cite this article: Lähteenmäki, P. et al. Coherence and multimode correlations from vacuum fluctuations in a microwave superconducting cavity. Nat. Commun. 7:12548 doi: 10.1038/ncomms12548 (2016).

References

  1. 1

    Purcell, E. M. Spontaneous emission probabilities at radio frequencies. Phys. Rev. 69, 681 (1946).

    Article  Google Scholar 

  2. 2

    Lamb, W. & Retherford, R. Fine structure of the hydrogen atom by a microwave method. Phys. Rev 72, 241–243 (1947).

    CAS  ADS  Article  Google Scholar 

  3. 3

    Schwinger, J. S. On gauge invariance and vacuum polarization. Phys. Rev 82, 664–679 (1951).

    ADS  MathSciNet  Article  Google Scholar 

  4. 4

    Hawking, S. W. Black hole explosions? Nature 248, 30–31 (1974).

    ADS  Article  Google Scholar 

  5. 5

    Casimir, H. B. G. On the attraction between two perfectly conducting plates. Proc. K. Ned. Akad. Wet. B 51, 793–795 (1948).

    MATH  Google Scholar 

  6. 6

    Paraoanu, G. S. in Boston Studies in the Philosophy and History of Science Vol. 313 (eds Parvu, I., Sandu, G. & Toader, I.) 181–197 (Springer, 2015).

  7. 7

    Sabín, C. & Adesso, G. Generation of quantum steering and interferometric power in the dynamical Casimir effect. Phys. Rev. A 92, 042107 (2015).

    ADS  Article  Google Scholar 

  8. 8

    Lähteenmäki, P. et al. Advanced concepts in Josephson junction reflection amplifiers. J. Low Temp. Phys. 175, 868–876 (2014).

    ADS  Article  Google Scholar 

  9. 9

    Paraoanu, G. S. Recent progress in quantum simulation using superconducting circuits. J. Low Temp. Phys. 175, 633–654 (2014).

    CAS  ADS  Article  Google Scholar 

  10. 10

    You, J. Q. & Nori, F. Atomic physics and quantum optics using superconducting circuits. Nature 474, 589–597 (2011).

    CAS  ADS  Article  Google Scholar 

  11. 11

    Kamal, A., Marblestone, A. & Devoret, M. Signal-to-pump back action and self-oscillation in double-pump Josephson parametric amplifier. Phys. Rev. B 79, 043804 (2009).

    Article  Google Scholar 

  12. 12

    Simoen, M. et al. Characterization of a multimode coplanar waveguide parametric amplifier. J. Appl. Phys. 118, 154501 (2015).

    ADS  Article  Google Scholar 

  13. 13

    Eichler, C. et al. Quantum-limited amplification and entanglement in coupled nonlinear resonators. Phys. Rev. Lett. 113, 110502 (2014).

    CAS  ADS  Article  Google Scholar 

  14. 14

    Bergeal, N. et al. Phase-preserving amplification near the quantum limit with a Josephson ring modulator. Nature 465, 64–69 (2010).

    CAS  ADS  Article  Google Scholar 

  15. 15

    Clerk, A. A., Devoret, M. H., Girvin, S. M., Marquardt, F. & Schoelkopf, R. J. Introduction to quantum noise, measurement, and amplification. Rev. Mod. Phys. 82, 1155–1208 (2010).

    ADS  MathSciNet  Article  Google Scholar 

  16. 16

    Yurke, B. et al. Observation of 4.2-K equilibrium-noise squeezing via a Josephson-parametric amplifier. Phys. Rev. Lett. 60, 764–767 (1988).

    CAS  ADS  Article  Google Scholar 

  17. 17

    Castellanos-Beltran, M. A., Irwin, K. D., Hilton, G. C., Vale, L. R. & Lehnert, K. W. Amplification and squeezing of quantum noise with a tunable Josephson metamaterial. Nat. Phys. 4, 929–931 (2008).

    Article  Google Scholar 

  18. 18

    Mallet, F. et al. Quantum state tomography of an itinerant squeezed microwave field. Phys. Rev. Lett. 106, 220502 (2011).

    CAS  ADS  Article  Google Scholar 

  19. 19

    Eichler, C. et al. Observation of two-mode squeezing in the microwave frequency domain. Phys. Rev. Lett. 107, 113601 (2011).

    CAS  ADS  Article  Google Scholar 

  20. 20

    Wilson, C. M. et al. Observation of the dynamical Casimir effect in a superconducting circuit. Nature 479, 376–379 (2011).

    CAS  ADS  Article  Google Scholar 

  21. 21

    Lähteenmäki, P., Paraoanu, G. S., Hassel, J. & Hakonen, P. J. Dynamical Casimir effect in a Josephson metamaterial. Proc. Natl Acad. Sci. USA 110, 4234–4238 (2013).

    ADS  Article  Google Scholar 

  22. 22

    Menzel, E. P. et al. Path entanglement of continuous-variable quantum microwaves. Phys. Rev. Lett. 109, 250502 (2012).

    CAS  ADS  Article  Google Scholar 

  23. 23

    Lähteenmäki, P., Paraoanu, G. S., Hassel, J. & Hakonen, P. J. Photon generation from quantum vacuum using a Josephson metamaterial. PIERS Taipei Proc. 151, (2013).

  24. 24

    Nation, P. D., Johansson, J. R., Blencowe, M. P. & Nori, F. Colloquium: Stimulating uncertainty: amplifying the quantum vacuum with superconducting circuits. Rev. Mod. Phys. 84, 1–24 (2012).

    ADS  Article  Google Scholar 

  25. 25

    Bruschi, D. et al. Towards universal quantum computation through relativistic motion. Sci. Rep. 6, 18349 (2016).

    CAS  ADS  Article  Google Scholar 

  26. 26

    Yuen, H. P. Two-photon coherent states of the radiation field. Phys. Rev. A 13, 2226–2243 (1976).

    ADS  Article  Google Scholar 

  27. 27

    Caves, C. M. & Schumaker, B. L. New formalism for 2-photon quantum optics. 1. Quadrature phases and squeezed states. Phys. Rev. A 31, 3068–3092 (1985).

    CAS  ADS  MathSciNet  Article  Google Scholar 

  28. 28

    Symul, T., Assad, S. M. & Lam, P. K. Real time demonstration of high bitrate quantum random number generation with coherent laser light. Appl. Phys. Lett. 98, 231103 (2011).

    ADS  Article  Google Scholar 

  29. 29

    Zou, X. Y., Wang, L. J. & Mandel, L. Induced coherence and indistinguishability in optical interference. Phys. Rev. Lett. 67, 318–321 (1991).

    CAS  ADS  Article  Google Scholar 

  30. 30

    Kim, Y.-H., Yu, R., Kulik, S. P., Shih, Y. & Scully, M. O. Delayed choice quantum eraser. Phys. Rev. Lett. 84, 1–5 (2000).

    CAS  ADS  Article  Google Scholar 

  31. 31

    Kelly, W. R. et al. Direct observation of coherent population trapping in a superconducting artificial atom. Phys. Rev. Lett. 104, 163601 (2010).

    ADS  Article  Google Scholar 

  32. 32

    Arimondo, E. & Wolf, E. Coherent population trapping in laser spectroscopy. Prog. Opt. 35, 257–354 (1996).

    ADS  Article  Google Scholar 

  33. 33

    Tanji-Suzuki, H., Chen, W., Landig, R., Simon, J. & Vuletic, V. Vacuum-Induced Transparency. Science 333, 1266–1269 (2011).

    CAS  ADS  Article  Google Scholar 

  34. 34

    Agarwal, G. S. Quantum Optics Cambridge University Press (2012).

  35. 35

    Zhu, X. et al. Observation of dark states in a superconductor diamond quantum hybrid system. Nat. Commun. 5, 3424 (2014).

    Article  Google Scholar 

  36. 36

    Kumar, K. S., Vepsäläinen, A., Danilin, S. & Paraoanu, G. S. Stimulated Raman adiabatic passage in a three-level superconducting circuit. Nat. Commun. 7, 10628 (2016).

    CAS  ADS  Article  Google Scholar 

  37. 37

    Marquardt, F., Chen, J. P., Clerk, A. A. & Girvin, S. M. Quantum theory of cavity-assisted sideband cooling of mechanical motion. Phys. Rev. Lett. 99, 093902 (2007).

    ADS  Article  Google Scholar 

  38. 38

    Zakka-Bajjani, E. et al. Quantum superposition of a single microwave photon in two different colour states. Nat. Phys. 7, 599–603 (2011).

    CAS  Article  Google Scholar 

  39. 39

    Giedke, G., Kraus, B., Lewenstein, M. & Cirac, J. I. Suppression of arbitrary internal coupling in a quantum register. Phys. Rev. A 64, 052301 (2001).

    ADS  Article  Google Scholar 

  40. 40

    Adesso, G., Serafini, A. & Illuminati, F. Multipartite entanglement in three-mode Gaussian states of continuous-variable systems: quantification, sharing structure, and decoherence. Phys. Rev. A 73, 032345 (2006).

    ADS  Article  Google Scholar 

  41. 41

    Serafini, A., Adesso, G. & Illuminati, F. Unitarily localizable entanglement of Gaussian states. Phys. Rev. A 71, 032349 (2005).

    ADS  MathSciNet  Article  Google Scholar 

  42. 42

    Adesso, G., Serafini, A. & Illuminati, F. Quantification and scaling of multipartite entanglement in continuous variable systems. Phys. Rev. Lett. 93, 220504 (2004).

    ADS  Article  Google Scholar 

  43. 43

    Dür, W., Vidal, G. & Cirac, J. I. Three qubits can be entangled in two inequivalent ways. Phys. Rev. A 62, 062314 (2000).

    ADS  MathSciNet  Article  Google Scholar 

  44. 44

    van Loock, P. & Braunstein, S. L. Telecloning of continuous quantum variables. Phys. Rev. Lett. 87, 247901 (2001).

    CAS  ADS  MathSciNet  Article  Google Scholar 

  45. 45

    Adesso, G., Serafini, A. & Illuminati, F. Optical state engineering, quantum communication, and robustness of entanglement promiscuity in three-mode Gaussian states. New J. Phys. 9, 60 (2007).

    ADS  Article  Google Scholar 

  46. 46

    Paraoanu, G. S. Realism and single-quanta nonlocality. Found. Phys. 41, 734 (2011).

    ADS  MathSciNet  Article  Google Scholar 

  47. 47

    Heaney, L., Cabello, A., Santos, M. F. & Vedral, V. Extreme nonlocality with one photon. New J. Phys. 13, 053054 (2011).

    ADS  Article  Google Scholar 

  48. 48

    Aaronson, S. & Arkhipov, A. The computational complexity of linear optics. Proceedings of the Forty-Third Annual ACM Symposium on Theory of Computing 333–342http://dx.doi.org/10.1145/1993636.1993682 (2011).

  49. 49

    Chen, M., Menicucci, N. C. & Pfister, O. Experimental realization of multipartite entanglement of 60 modes of a quantum optical frequency comb. Phys. Rev. Lett. 112, 120505 (2014).

    ADS  Article  Google Scholar 

  50. 50

    Raussendorf, R. & Briegel, H. J. A one-way quantum computer. Phys. Rev. Lett. 86, 5188 (2001).

    CAS  ADS  Article  Google Scholar 

  51. 51

    Ramelow, S., Ratschbacher, L., Fedrizzi, A., Langford, N. K. & Zeilinger, A. Discrete tunable color entanglement. Phys. Rev. Lett. 103, 253601 (2009).

    CAS  ADS  Article  Google Scholar 

  52. 52

    Lemos, G. B. et al. Quantum imaging with undetected photons. Nature 512, 409–412 (2014).

    CAS  ADS  Article  Google Scholar 

  53. 53

    Ma, X.-S., Kofler, J. & Zeilinger, A. Delayed-choice gedanken experiments and their realizations. Rev. Mod. Phys 88, 015005 (2016).

    ADS  Article  Google Scholar 

  54. 54

    da Silva, M. P., Bozyigit, D., Wallraff, A. & Blais, A. Schemes for the observation of photon correlation functions in circuit QED with linear detectors. Phys. Rev. A 82, 043804 (2010).

    ADS  Article  Google Scholar 

  55. 55

    Bertet, P. et al. A complementarity experiment with an interferometer at the quantum-classical boundary. Nature 411, 166–170 (2001).

    CAS  ADS  Article  Google Scholar 

  56. 56

    Braunstein, S. L. & van Loock, P. Quantum information with continuous variables. Rev. Mod. Phys. 77, 513–577 (2005).

    ADS  MathSciNet  Article  Google Scholar 

  57. 57

    Kiviranta, M. et al. Multilayer fabrication process for josephson junction circuits cross-compatible over two foundries. IEEE Trans. Appl. Supercond. 99, 1–5 (2016).

    Article  Google Scholar 

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Acknowledgements

We thank K. Mølmer, Sir P. Knight, Y. Makhlin, C. Sabín, H. Briegel, W. Dür, D. Bruschi, G. Adesso and A. Simonsen for discussions and M. Kiviranta and L. Grönberg for contributions in fabrication. This work used the cryogenic facilities of the Low Temperature Laboratory infrastructure at OtaNano, Aalto University. We acknowledge financial support from FQXi, the Academy of Finland project 263457, the Center of Excellence ‘Low Temperature Quantum Phenomena and Devices’ (project 250280) and the FP7 iQuOEMS project 323924.

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P.L. and J.H. designed the sample. P.L. and P.J.H. were responsible for the experimental setup. P.L. performed the experiment and analysed the data. G.S.P. developed the theoretical model. P.L., P.H., and G.S.P. wrote the paper, and the results were discussed with all authors.

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Correspondence to Pasi Lähteenmäki or Pertti J. Hakonen.

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The authors declare no competing financial interests.

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Supplementary Figures 1-6, Supplementary Notes 1-8 and Supplementary References. (PDF 2241 kb)

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Lähteenmäki, P., Paraoanu, G., Hassel, J. et al. Coherence and multimode correlations from vacuum fluctuations in a microwave superconducting cavity. Nat Commun 7, 12548 (2016). https://doi.org/10.1038/ncomms12548

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