Abstract

Qudit entanglement is an indispensable resource for quantum information processing since increasing dimensionality provides a pathway to higher capacity and increased noise resilience in quantum communications, and cluster-state quantum computations. In continuous-variable time–frequency entanglement, encoding multiple qubits per photon is only limited by the frequency correlation bandwidth and detection timing jitter. Here, we focus on the discrete-variable time–frequency entanglement in a biphoton frequency comb (BFC), generating by filtering the signal and idler outputs with a fiber Fabry–Pérot cavity with 45.32 GHz free-spectral range (FSR) and 1.56 GHz full-width-at-half-maximum (FWHM) from a continuous-wave (cw)-pumped type-II spontaneous parametric downconverter (SPDC). We generate a BFC whose time-binned/frequency-binned Hilbert space dimensionality is at least 324, based on the assumption of a pure state. Such BFC’s dimensionality doubles up to 648, after combining with its post-selected polarization entanglement, indicating a potential 6.28 bits/photon classical-information capacity. The BFC exhibits recurring Hong–Ou–Mandel (HOM) dips over 61 time bins with a maximum visibility of 98.4% without correction for accidental coincidences. In a post-selected measurement, it violates the Clauser–Horne–Shimony–Holt (CHSH) inequality for polarization entanglement by up to 18.5 standard deviations with an S-parameter of up to 2.771. It has Franson interference recurrences in 16 time bins with a maximum visibility of 96.1% without correction for accidental coincidences. From the zeroth- to the third-order Franson interference, we infer an entanglement of formation (Eof) up to 1.89 ± 0.03 ebits—where 2 ebits is the maximal entanglement for a 4 × 4 dimensional biphoton—as a lower bound on the 61 time-bin BFC’s high-dimensional entanglement. To further characterize time-binned/frequency-binned BFCs we obtain Schmidt mode decompositions of BFCs generated using cavities with 45.32, 15.15, and 5.03 GHz FSRs. These decompositions confirm the time–frequency scaling from Fourier-transform duality. Moreover, we present the theory of conjugate Franson interferometry—because it is characterized by the state’s joint-temporal intensity (JTI)—which can further help to distinguish between pure-state BFC and mixed state entangled frequency pairs, although the experimental implementation is challenging and not yet available. In summary, our BFC serves as a platform for high-dimensional quantum information processing and high-dimensional quantum key distribution (QKD).

Highlights

  • Qudit entanglement is a fundamental differentiator of quantum information processing over classical systems in computing, communications, simulations, and metrology

  • Three high-dimensional BFCs35 were created by sending the signal-idler photon pairs through one of three Fabry–Pérot fiber cavities, whose free-spectral range (FSR) are 45.32, 15.15, and 5.03 GHz, with least 324, based on the assumption that our biphoton frequency comb (BFC) is a pure state

  • We find that the product of the time-binned and frequency-binned Schmidt numbers is similar for the 45.32 GHz and 15.15 GHz BFCs: KT;[45] GHzKΩ;[45] GHz ffi KT;[15] GHzKΩ;[15] GHz; (12)

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Summary

Introduction

Qudit entanglement is a fundamental differentiator of quantum information processing over classical systems in computing, communications, simulations, and metrology. The resulting BFC biphoton—as predicted by standard perturbation theory with the signal-idler differential group delay suppressed, see for example62—can be expressed as: produced with the same SPDC source and a 5.03 GHz FSR, 0.46 GHz FWHM linewidth cavity, we got spectral correlations over 19 frequency bins but only seven HOM-interference recurrences.

Results
Conclusion

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