Abstract
Bell states are a fundamental resource in photonic quantum information processing. These states have been generated successfully in many photonic degrees of freedom. Their manipulation, however, in the momentum space remains challenging. Here, we present a scheme for engineering the symmetry of two-photon states entangled in the transverse momentum degree of freedom through the use of a spatially variable phase object. We demonstrate how a Hong-Ou-Mandel interferometer must be constructed to verify the symmetry in momentum entanglement via photon “bunching/anti-bunching” observation. We also show how this approach allows generating states that acquire an arbitrary phase under the exchange operation.
© 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement
1. Introduction
Quantum entanglement, considered one of the most counterintuitive features of quantum mechanics [1], is now one of the most important resources for quantum information tasks. In quantum optics it has been used as a fundamental tool in quantum cryptography [2], quantum dense coding [3], quantum teleportation [4], and quantum computation [5]. A great number of experiments have investigated the production of photonic entangled states, which have played a critical role in many important applications in quantum information processing. Photon pair generation through Spontaneous Parametric Down Conversion (SPDC) has been used to demonstrate entanglement in polarization [6], path [7], spatial modes (e.g., Hermite-Gauss modes [8,9], Laguerre-Gauss modes [10,11]), energy-time [12] and time-bin [13] degrees of freedom, and some of them simultaneously [14–17]. The SPDC state can also provide a good approximation of a momentum-position Einstein-Podolsky-Rosen (EPR) state when looking at the transverse momentum decomposition [15].
Momentum entanglement, as a continuous degree of freedom, can allow, in principle, to reach the ultimate limits of high-dimensional entanglement [15]. In addition, high-dimensional quantum systems can allow entanglement to have high complexity and can be exploited for various quantum information tasks [18–20]. The momentum entangled state that naturally arises from SPDC is symmetric [21], i.e., the same state is obtained under the exchange of idler and signal photon. However, it is more challenging to generate antisymmetric momentum entanglement. One possible approach that exploits the pump symmetry has been explored in Ref. [8]. The competition between the symmetry of polarization entanglement and pump shaping was shown to affect the two-photon interference behavior.
Here, we demonstrate an approach to freely manipulate the relative phase defining the two-photon entangled state by introducing a spatially dependent phase distribution on one of the photons in the pair (namely, the idler) path. A phase jump applied between opposite values of the idler photon’s transverse momentum affects the exchange symmetry. A $\pi$-phase jump allows conversion of the symmetric SPDC state into an antisymmetric one. Intermediate phase jumps will generate antisymmetric states, which gain a general phase factor under exchange operation. We also demonstrate how a two-photon interference setup needs to be constructed in order to verify the symmetry of such a momentum entangled state. This work provides a new method for quantum state engineering and entanglement verification in the momentum degree of freedom, which may be exploited in quantum imaging protocols, high-dimensional quantum communications, quantum information processing, and quantum simulations.
2. Scheme
The scheme we propose is based on a Type-II SPDC source of photon pairs. Exploiting the fact that idler and signal photons are orthogonally polarized, we can spatially separate the two photons with a polarizing beamsplitter (PBS). The vertically polarized photons are then converted to horizontally polarized by a half-wave-plate, therefore the resulting two-photon state (in the transverse momentum degree of freedom) can be written as $| {\Psi } \rangle =\frac {1}{\sqrt {2}}\int d^2\mathbf {k}(| {\mathbf {k}} \rangle_s | {\mathbf {-k}} \rangle_i+ | {\mathbf {-k}} \rangle_s | {\mathbf {k}} \rangle_i).$ Note that we have assumed here a perfectly collimated pump in the thin-crystal limit. A phase object in the far-field of the crystal, placed in the idler path, implements the transformation $| {\mathbf {k}} \rangle_i \rightarrow e^{\phi (\mathbf {k})} | {\mathbf {k}} \rangle_i$. When post-selecting on correlated pairs of momentum values (i.e., $\mathbf {k_0}$ and $-\mathbf {k_0}$), we obtain the state:
The state symmetry can be analyzed through Hong-Ou-Mandel (HOM) interference. When the two photons are incident on a beamsplitter (BS), with the important requirement that the number of reflections up to the exit port of the BS has the same parity for both photons, they exit from the same output port if the relative phase is $\varphi =0$ (bunching), while they always exit from different ports if $\varphi =\pi$ (anti-bunching). This can be immediately seen when measuring the coincidence counts between the two output paths $a$ and $b$ of the BS. More generally, for arbitrary phases $\varphi$, the (normalized) coincidence count rate is
which can be inverted to obtain $\varphi$ (modulo $\pi$) that characterizes the state completely.3. Results
To experimentally test our scheme, we generated momentum entangled photon pairs in SPDC using a 5mm thick type-II PPKTP crystal pumped by a 405 nm continuous wave laser (the detailed experimental setup is illustrated in Fig. 1). The frequency-degenerate photon pairs are split in idler and signal path by a polarizing beamsplitter (PBS). A reconfigurable liquid crystal spatial light modulator (SLM) allows us to apply different phase patterns on the idler path. In particular, we implemented phase jumps along a vertical line centered on the SPDC cone. Idler and signal photons are then made to interfere at a 50:50 BS (after the signal polarization has been rotated to horizontal). The number of mirrors in the two paths was chosen in order to keep momentum anti-correlation at the BS output ports, i.e., ensuring that both photons are subject to the same number of reflections. The two output modes (paths $a$ and $b$) were then coupled to single-mode fibers in such a way that, on each path, opposite values of the transverse momentum were selected.
One thing to note is that this scheme requires photons with momentum $\mathbf {k}$ and $\mathbf {-k}$ to be present in both arms of the interferometer. Therefore, one cannot use a knife-edge prism or a D-shaped mirror to split the photons into two paths. This makes momentum entanglement manipulation using Type-I or Type-0 SPDC, where the photon pairs have the same polarization, much more difficult. The same technique can also be used for manipulating the transverse position entanglement between SPDC photons. This will require the parity of the number of reflections to be unequal in order to convert from a symmetric to an anti-symmetric position entangled state.
We recorded coincidence counts as a function of the path length difference $\Delta L$ between the two paths in the interferometer and for different phase jumps. The results are shown in Fig. 2, illustrating how applying a phase jump allows one to switch from two-photon bunching to two-photon anti-bunching, a clear indicator that the momentum entanglement has been converted from symmetric to anti-symmetric. The visibilities $v$ of the HOM dip in photon bunching and of the coalescence peak are defined as $v_\text {peak}=(C_{max}-C)/C$ and $v_\text {dip}=(C-C_{min})/C$, where $C_{max}$ and $C_{min}$ are the maximum and minimum coincidence counts at the peak and dip, respectively. $C$ is the coincidence count outside the dip/peak where the difference in the two path lengths is much larger than the coherence length of the SPDC photons.
In Fig. 3, we verify that the coincidences at $\Delta L=0$ follow Eq. (2). The visibilities for $\varphi =0$ and $\pi$ give a direct estimate of the fidelity between the realized state and the expected symmetric/antisymmetric entangled state. We obtained $v\sim 88\%$ and $v\sim 97\%$, for $\varphi =0$ and $\pi$, respectively. Intermediate cases correspond to the creation of entangled states which mimic two-particle states obeying anyonic statistics [22].
The visibilities do not quite reach 1 at $\varphi =0$ and $\pi$, which is due to the imperfections in the alignment and the BS not being exactly 50:50. We have found the alignment which gave the highest visibility in the peak often deviated slightly from the alignment which gave the highest visibility in the HOM dip; this can be a result of small imperfections in the alignment and SLM calibration. We have aligned the setup by maximizing the HOM peak, thus resulting in the visibility at $\varphi =\pi$ being higher than $\varphi =0$. Non-uniformity in the SLM will have only a small affect in our experiment as we are collecting photons from two small regions on the SLM. If photons were collected from larger regions by using multi-mode fibers or camera, then the SLM uniformity would need to be considered.
4. Conclusions and outlook
Measurement of state symmetry using HOM interference has been demonstrated in various degrees of freedom, such as polarization [23], frequency [24–26], and Orbital Angular Momentum [11]. Here, we introduced and demonstrated a new method that allows, for the first time, the manipulation of transverse momentum entanglement between SPDC photon pairs through the use of a reconfigurable phase object (SLM), which allows to locally tune the state symmetry. We also demonstrated how a HOM interferometer must be constructed in order to verify the momentum entanglement symmetry. Simultaneously generating a state with spatially variable symmetry with thousands of momentum entangled modes can be performed in the near future and directly observed with recently developed time-tagging camera technologies [27,28]. This ability to manipulate and measure thousands of entangled modes would be greatly beneficial in quantum imaging protocols as well as in high-dimensional quantum communications, quantum information processing, and quantum simulations. However, this will require a high visibility multimode HOM interference in the spatial domain, a task that necessitates a careful engineering of SPDC spatial correlations, which requires the generation of a SPDC state with very high spatial correlation and compensation for the different SPDC cone sizes associated to the orthogonal polarizations.
Funding
Joint Centre for Extreme Photonics; High-Throughput and Secure Networks Challenge Program at the National Research Council of Canada; Canada First Research Excellence Fund; Canada Research Chairs.
Acknowledgments
The authors would like to thank Dilip Paneru and Frédéric Bouchard for valuable discussions.
Disclosures
The authors declare no conflicts of interest.
Data Availability
Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.
References
1. A. Einstein, B. Podolsky, and N. Rosen, “Can quantum-mechanical description of physical reality be considered complete?” Phys. Rev. 47(10), 777–780 (1935). [CrossRef]
2. A. K. Ekert, “Quantum cryptography based on bell’s theorem,” Phys. Rev. Lett. 67(6), 661–663 (1991). [CrossRef]
3. C. H. Bennett and S. J. Wiesner, “Communication via one- and two-particle operators on einstein-podolsky-rosen states,” Phys. Rev. Lett. 69(20), 2881–2884 (1992). [CrossRef]
4. C. H. Bennett, G. Brassard, C. Crépeau, R. Jozsa, A. Peres, and W. K. Wootters, “Teleporting an unknown quantum state via dual classical and einstein-podolsky-rosen channels,” Phys. Rev. Lett. 70(13), 1895–1899 (1993). [CrossRef]
5. R. Raussendorf and H. J. Briegel, “A one-way quantum computer,” Phys. Rev. Lett. 86(22), 5188–5191 (2001). [CrossRef]
6. P. G. Kwiat, A. M. Steinberg, and R. Y. Chiao, “Observation of a “quantum eraser”: A revival of coherence in a two-photon interference experiment,” Phys. Rev. A 45(11), 7729–7739 (1992). [CrossRef]
7. T. B. Pittman, D. V. Strekalov, A. Migdall, M. H. Rubin, A. V. Sergienko, and Y. H. Shih, “Can two-photon interference be considered the interference of two photons?” Phys. Rev. Lett. 77(10), 1917–1920 (1996). [CrossRef]
8. S. P. Walborn, A. N. de Oliveira, S. Pádua, and C. H. Monken, “Multimode hong-ou-mandel interference,” Phys. Rev. Lett. 90(14), 143601 (2003). [CrossRef]
9. Y. Zhang, S. Prabhakar, C. Rosales-Guzmán, F. S. Roux, E. Karimi, and A. Forbes, “Hong-ou-mandel interference of entangled hermite-gauss modes,” Phys. Rev. A 94(3), 033855 (2016). [CrossRef]
10. E. Karimi, D. Giovannini, E. Bolduc, N. Bent, F. M. Miatto, M. J. Padgett, and R. W. Boyd, “Exploring the quantum nature of the radial degree of freedom of a photon via hong-ou-mandel interference,” Phys. Rev. A 89(1), 013829 (2014). [CrossRef]
11. Y. Zhang, F. S. Roux, T. Konrad, M. Agnew, J. Leach, and A. Forbes, “Engineering two-photon high-dimensional states through quantum interference,” Sci. Adv. 2(2), e1501165 (2016). [CrossRef]
12. J. D. Franson, “Bell inequality for position and time,” Phys. Rev. Lett. 62(19), 2205–2208 (1989). [CrossRef]
13. J. Brendel, N. Gisin, W. Tittel, and H. Zbinden, “Pulsed energy-time entangled twin-photon source for quantum communication,” Phys. Rev. Lett. 82(12), 2594–2597 (1999). [CrossRef]
14. D. V. Strekalov, T. B. Pittman, A. V. Sergienko, Y. H. Shih, and P. G. Kwiat, “Postselection-free energy-time entanglement,” Phys. Rev. A 54(1), R1–R4 (1996). [CrossRef]
15. J. C. Howell, R. S. Bennink, S. J. Bentley, and R. W. Boyd, “Realization of the einstein-podolsky-rosen paradox using momentum- and position-entangled photons from spontaneous parametric down conversion,” Phys. Rev. Lett. 92(21), 210403 (2004). [CrossRef]
16. J. T. Barreiro, N. K. Langford, N. A. Peters, and P. G. Kwiat, “Generation of hyperentangled photon pairs,” Phys. Rev. Lett. 95(26), 260501 (2005). [CrossRef]
17. X.-L. Wang, X.-D. Cai, Z.-E. Su, M.-C. Chen, D. Wu, L. Li, N.-L. Liu, C.-Y. Lu, and J.-W. Pan, “Quantum teleportation of multiple degrees of freedom of a single photon,” Nature 518(7540), 516–519 (2015). [CrossRef]
18. M. Krenn, M. Huber, R. Fickler, R. Lapkiewicz, S. Ramelow, and A. Zeilinger, “Generation and confirmation of a (100 x 100)-dimensional entangled quantum system,” Proc. Natl. Acad. Sci. 111(17), 6243–6247 (2014). [CrossRef]
19. J. Wang, S. Paesani, Y. Ding, R. Santagati, P. Skrzypczyk, A. Salavrakos, J. Tura, R. Augusiak, L. Mančinska, D. Bacco, D. Bonneau, J. W. Silverstone, Q. Gong, A. Acín, K. Rottwitt, L. K. Oxenløwe, J. L. O’Brien, A. Laing, and M. G. Thompson, “Multidimensional quantum entanglement with large-scale integrated optics,” Science 360(6386), 285–291 (2018). [CrossRef]
20. M. Erhard, M. Krenn, and A. Zeilinger, “Advances in high-dimensional quantum entanglement,” Nat. Rev. Phys. 2(7), 365–381 (2020). [CrossRef]
21. M. D’Angelo, Y.-H. Kim, S. P. Kulik, and Y. Shih, “Identifying entanglement using quantum ghost interference and imaging,” Phys. Rev. Lett. 92(23), 233601 (2004). [CrossRef]
22. L. Sansoni, F. Sciarrino, G. Vallone, P. Mataloni, A. Crespi, R. Ramponi, and R. Osellame, “Two-particle bosonic-fermionic quantum walk via integrated photonics,” Phys. Rev. Lett. 108(1), 010502 (2012). [CrossRef]
23. K. Mattle, H. Weinfurter, P. G. Kwiat, and A. Zeilinger, “Dense coding in experimental quantum communication,” Phys. Rev. Lett. 76(25), 4656–4659 (1996). [CrossRef]
24. S. Ramelow, L. Ratschbacher, A. Fedrizzi, N. K. Langford, and A. Zeilinger, “Discrete tunable color entanglement,” Phys. Rev. Lett. 103(25), 253601 (2009). [CrossRef]
25. A. Fedrizzi, T. Herbst, M. Aspelmeyer, M. Barbieri, T. Jennewein, and A. Zeilinger, “Anti-symmetrization reveals hidden entanglement,” New J. Phys. 11(10), 103052 (2009). [CrossRef]
26. F. Kaneda, H. Suzuki, R. Shimizu, and K. Edamatsu, “Direct generation of frequency-bin entangled photons via two-period quasi-phase-matched parametric downconversion,” Opt. Express 27(2), 1416–1424 (2019). [CrossRef]
27. M. Perenzoni, L. Pancheri, and D. Stoppa, “Compact spad-based pixel architectures for time-resolved image sensors,” Sensors 16(5), 745 (2016). [CrossRef]
28. A. Nomerotski, “Imaging and time stamping of photons with nanosecond resolution in timepix based optical cameras,” Nucl. Instrum. Methods Phys. Res., Sect. A 937, 26–30 (2019). [CrossRef]