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. 2018 May 4;7:18009. doi: 10.1038/lsa.2018.9

Entanglement beating in free space through spin–orbit coupling

Eileen Otte 1, Carmelo Rosales-Guzmán 2,*, Bienvenu Ndagano 2, Cornelia Denz 1, Andrew Forbes 2
PMCID: PMC6060074  PMID: 30839563

Abstract

It is well known that the entanglement of a quantum state is invariant under local unitary transformations. This rule dictates, for example, that the entanglement of internal degrees of freedom of a photon remains invariant during free-space propagation. Here, we outline a scenario in which this paradigm does not hold. Using local Bell states engineered from classical vector vortex beams with non-separable degrees of freedom, the so-called classically entangled states, we demonstrate that the entanglement evolves during propagation, oscillating between maximally entangled (purely vector) and product states (purely scalar). We outline the spin–orbit interaction behind these novel propagation dynamics and confirm the results experimentally, demonstrating spin–orbit coupling in paraxial beams. This demonstration highlights a hitherto unnoticed property of classical entanglement and simultaneously offers a device for the on-demand delivery of vector states to targets, for example, for dynamic laser materials processing, switchable resolution within stimulated emission depletion (STED) systems, and a tractor beam for entanglement.

Keywords: classical entanglement, complex light fields, entanglement oscillation, spin–orbit coupling

Introduction

Under local unitary operations, for example, when propagating through a unitary channel, the degree of entanglement does not change. This finding is true for both non-local entanglement, that is, light fields (including single photon, multi-photons or coherent light) that simultaneously exist in physically separated locations, and for local entanglement, that is, between the internal degrees of freedom of a single photon. Recently, it has become of interest to study the latter and to mimic the former using vector states of classical light1, 2, 3, 4, 5, 6, 7, 8, 9, 10. This approach is possible because the central feature of entanglement, non-separability, is not limited to quantum systems: classical vector beams are likewise non-separable, for example, in their polarization and spatial modes. However, whether such fields can be called ‘classically entangled’ is an open question1, 7, in practice, this property has been exploited for real-time quantum error correction11, communication12, 13, 14, 15, 16, laser materials processing17, 18, 19 and metrology20, 21, 22. In addition, in imaging23, 24, 25, 26, where tightly focused radially polarized fields are known to produce the narrowest spot size27, 28, 29, 30, classically entangled light fields allow super-resolution microscopy techniques31, 32.

Here, we demonstrate that entanglement can evolve during propagation in free space using classically entangled vector vortex beams, which are non-separable in orbital and spin angular momentum. We engineer superpositions of these beams to prove the dynamic change of entanglement upon propagation through spin–orbit (SO) coupling. Such SO coupling33 has been observed through the spin-Hall effect of light at planar interfaces, by non-paraxial light (tightly focused by high numerical aperture lenses), and with paraxial light in anisotropic and inhomogeneous structures, for example, using geometric phase34. Here, we show that it is possible with paraxial light in free space. Through this SO coupling, we demonstrate entanglement beating from fully entangled (completely non-separable) to no entanglement (fully separable), and by a phase adjustment, we evince the possible transport of entanglement, which is reminiscent of tractor beams for particle transport35, 36, 37, 38. This realization may open new avenues in quantum and classical communication as well as in improved materials processing (where vector beams and scalar polarized beams are crucial) and enhanced switchable imaging in stimulated emission depletion (STED) microscopy.

Materials and methods

Concept

Consider a vector beam that is composed of a superposition of two orthogonally polarized Laguerre–Gaussian modes Inline graphic given by9

graphic file with name lsa20189e1.jpg

where we assume a propagation in the ±z-direction, approximated by the factor Inline graphic, where Inline graphic is the wave vector expressed in terms of the wavelength λ, as k=2π/λ. The kets Inline graphic and Inline graphic represent the unit vector of right- and left-handed circular polarization states, respectively, and α defines the phase relation between the two states. The indices Inline graphic and p denote the azimuthal and radial degrees of freedom, respectively, the former being related to the orbital angular momentum (OAM) of the Laguerre–Gaussian (LG) beam. In the following description, we will restrict ourselves to the case in which Inline graphic and p1=p2=p, but it can be extended to other cases. Equation (1) can be conveniently written as39

graphic file with name lsa20189e2.jpg

where Inline graphic are represented by the ket Inline graphic and the relative weightings of Inline graphic and Inline graphic by a. Moreover, Inline graphic satisfies the normalization condition Inline graphic.

The degree of non-separability (classical entanglement) Inline graphic of a vector field as defined by Equation (2) can be computed using tools from quantum mechanics. Here, we consider the entanglement entropy, originally derived for quantum states40, 41 and later extended to classical non-separable states39 as

graphic file with name lsa20189e3.jpg

Consequently, if we analyze a vector beam Inline graphic under a unitary transformation, that is, propagation in free space along the ±z-direction (Equation (1)), where a=1/2 for all z values, we observe a spatially invariant degree of entanglement Inline graphic.

Remarkably, we can engineer a light field Inline graphic with a z-dependent degree of entanglement Inline graphic by combining two orthogonal vector beams Inline graphic and Inline graphic, coaxially propagating in opposite directions, as illustrated in Figure 1a. For example, these orthogonal fields can be generated by setting Inline graphic and Inline graphic in Equation (1), namely,

Figure 1.

Figure 1

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Schematic representation of the investigated field with a z-dependent degree of entanglement. (a) Concept, (b) phase change of the radial/azimuthal beam (top/bottom) relative to the initial phase, (c) absolute value of the relative phase difference between the radial and azimuthal beam, (d) change in polarization upon intensity (top) with the corresponding degree of entanglement E (bottom) for superimposed counter-propagating radial and azimuthal vector beams, all depending on the propagation distance z (kzz∈[0,π]). Further, b and c include the respective polarization distributions per distance.

graphic file with name lsa20189e4.jpg

and

graphic file with name lsa20189e5.jpg

with a phase distribution as a function of z as shown in Figure 1b, top and bottom, respectively, for the case Inline graphic, p=0. The normalized field that results from such a superposition takes the form

graphic file with name lsa20189e6.jpg

whose polarization evolution upon propagation for the regarded example is shown in Figure 1c and 1d, respectively. Here, Figure 1c includes the change in the relative phase between the superimposed beams, which represents the origin of the resultant z-variant polarization structure. The new engineered state Inline graphic undergoes an oscillatory transition between fully vector and fully scalar modes of light, which can be described by the SO interaction33. The total angular momentum of our field always satisfies Jz=0 (for superposition beams constructed from the Inline graphic subspace) but with oscillatory spin and orbit components that vary as SzInline graphic and Inline graphic, respectively. As a result of the out-of-phase oscillation for opposite helicities, as the OAM component increases, the spin component decreases concomitantly to conserve the total angular momentum (see Supplementary Information).

This variation between the scalar and vector modes manifests itself through a change in the degree of entanglement, as defined by Equation (3), which for the new light field Inline graphic takes the form

graphic file with name lsa20189e7.jpg

(details with respect to the calculations can be found within the Supplementary Information). Thus, the state undergoes a periodic variation in the degree of entanglement as a function of z, as illustrated in Figure 1d, bottom, while the intensity profile remains constant. Full entanglement, that is, maximal non-separability Inline graphic is achieved at z=/4, Inline graphic, whereas non-entanglement, that is, complete separability Inline graphic is observed at z=(2n+1)λ/8, Inline graphic. Note that space-variant entanglement of the form Inline graphic can be realized by any OAM subspace Inline graphic by the superposition of orthogonal vector fields Inline graphic and Inline graphic, as long as they carry the same radial order p1,2(VB1,2)=p. In contrast, if we superimpose two counter-propagating scalar modes of opposite helicity and orthogonal polarization, the degree of entanglement will remain constant (see Supplementary Information).

This unique property of the field Inline graphic provides a means to facilitate the transport of a chosen degree of entanglement across arbitrary distances, by simply applying a phase adjustment ϕ, which is reminiscent of tractor beams35, 36, 37, 38. To illustrate this approach, we can replace the propagation factor in Equation (1) by the factor Inline graphic. In this way, the maximum degree of entanglement Inline graphic, for example, can be transported to a position Inline graphic according to the expression

graphic file with name lsa20189e8.jpg

This means that any chosen state can be conveyed to a specific position in space, along the propagation axis, by simply adjusting the phase ϕ. Moreover, by applying a time-dependent phase shift ϕ(t), it is possible to impart a time-dependent movement of a regarded maximum with an axial velocity given by

graphic file with name lsa20189e9.jpg

Experimental details

A simple method to generate a light field Inline graphic with local entanglement beating is via an interferometric approach. An exemplary system is sketched in Figure 2a. By combining a Sagnac interferometer with a half-wave plate (diagonally oriented), a single incident vector beam, for example, radially polarized, can be used for the generation of a standing wave according to Equations (4), (5), (6), whose local degree of entanglement E oscillates upon propagation. Note that in each arm of the interferometer, counter-propagating (green arrows) vector modes of orthogonal polarization will give rise to a classically entangled standing wave, as indicated by a red curve in one of the arms.

Figure 2.

Figure 2

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Sketch of the experimental concept: approach of (a) counter- and (b) co-propagating vector modes for the realization/investigation of the light field Inline graphic. (c) Applied system for generation (red box) and analysis (blue box, (e)) of Inline graphic with experimental steps indicated in (d). λ/2, half-wave plate; λ/4, quarter-wave plate; BS1,2, beam splitter; CCD, camera; L1,2, lens; M, mirror; SLM1,2, spatial light modulator.

Even if this approach of counter-propagating beams is very intuitive, the investigation of the light field Inline graphic would be challenging because any measuring device inserted in the path would destroy the oscillatory behavior of the light field Inline graphic. Here, we propose an alternative approach that allows us to quantify the spatially varying degree of entanglement. This approach is based on the engineered superposition of co-propagating orthogonally polarized vector modes, as visualized in Figure 2b. By applying digital propagation, we can artificially counter-propagate the two modes (red arrows), which physically co-propagate in the same direction (green arrows), enabling us to investigate the light field Inline graphic along the beam path.

The digital propagation of a light field Inline graphic propagating in the z-direction is based on the angular spectrum42, 43, according to which Inline graphic, where Inline graphic are the coordinates in real space, and Inline graphic are the Fourier and inverse Fourier transforms, respectively. Next, by the application of Fourier holograms in combination with a phase shift ±kzz, encoded on a spatial light modulator (SLM), we were able to digitally propagate a light field in the ±z-direction. To independently control the phase shift of each vector mode, for the artificial generation of counter-propagating vector modes, we developed a new method that facilitates the generation of any vector beam using a multiplexing approach enabled by an SLM44. This method allows not only simultaneous generation of multiple vector modes, but also their independent manipulation, such as digital propagation.

The idea behind our method is to encode a superposition of different holograms, each with a different spatial carrier frequency (blazed grating), on a single SLM. Thus, each beam is sent to different transverse positions in space, which allows manipulation of their polarization independently, as required for vector beam generation. For example, to generate a radially polarized vector beam, we multiplexed the corresponding holograms to create two helical LG beams with opposite topological charges Inline graphic on the SLM. A half-wave plate placed in the path of one beam changes its polarization from horizontal to vertical. Both beams were then recombined and passed through a quarter-wave plate to change the horizontal and vertical polarizations into left- and right-circular polarizations, respectively, thus generating the desired vector beam45.

In the present case, where we realized a superposition of two cylindrical vector beams VB1,2 (see Figure 2c, red box, and Figure 2d), four vortex beams were multiplexed in the SLM (SLMl; Fourier holograms), manipulated accordingly and (counter-) propagated digitally (Fourier relation between SLMl and SLM2 by lens L1) to investigate the desired field Inline graphic within the observation plane (SLM2). In this way, the detection system can remain static while the created vector beams artificially propagate in opposite directions. Beyond this, digital propagation, encoded on the SLM as a phase shift ϕ, facilitates the realization of a chosen degree of entanglement at the observation plane, which is similar to the case of tractor beams.

Theory of entanglement entropy

For the analysis of the light field Inline graphic, we determined the degree of classical entanglement, that is, the degree of non-separability, in different (x, y)-planes. An appropriate tool for this concern is the quantum mechanics entanglement entropy39, 40

graphic file with name lsa20189e10.jpg

with Inline graphic. Here, s is the length of the Bloch vector, given by Inline graphic with i={1, 2, 3}, where 〈σi〉 are the expectation values of the Pauli operators. These values are obtained by a set of 12 normalized, on-axis intensity measurements or six identical measurements for two different basis states39, 41.

We chose circular polarization as a basis. As a consequence, the projection measurements are given by two modes that carry the OAM of topological charge Inline graphic and Inline graphic, in addition to four superposition states represented by Inline graphic with Inline graphic (φ: azimuthal angle in polar coordinates). In the case at hand, we investigate the vector modes of first order (cf. Results and Discussion section), and hence, the projection measurements are performed for Inline graphic.

According to Table 1, the expectation values 〈σi〉 are calculated from

Table 1. Normalized intensity measurements Iuv for the determination of the expectation values 〈σi〉.

graphic file with name lsa20189t1.jpg

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graphic file with name lsa20189e11.jpg
graphic file with name lsa20189e12.jpg
graphic file with name lsa20189e13.jpg

To determine the entanglement entropy E experimentally, we measure the on-axis intensity values Iuv with u, v∈{1, 2, 3}, as indicated in Figure 2c, blue box, and Figure 2e. Therefore, polarization projections are performed by the use of a quarter-wave plate (λ/4) set to ±45° in combination with a polarization-sensitive spatial light modulator (SLM2) and OAM projections by a phase pattern on this modulator. The respective phase pattern carries the information of all six OAM projections, in which each of them is assigned to another spatial carrier frequency46. The application of this demultiplexing hologram results in six outputs on the CCD camera. Figure 2e positioned in Fourier relation with the observation plane (SLM2) by a lens (L2), which enables a single-shot measurement for each polarization basis.

For the entanglement entropy analysis in different (x, y)-planes of the light field, artificial propagation in the z-direction is applied. Further, the intensities Iuv for different planes are normalized by I11 + I12 + I21 + I22 for left- and right-circular polarization basis.

Results and discussion

To verify that the field Inline graphic follows the entanglement dynamics predicted by Equation (7), we experimentally generated and superimposed two orthogonal vector beams (according to Equations (4) and (5)), using the setup shown in Figure 2c, as indicated by the red box. For simplicity but without the loss of generality, we chose first-order radially and azimuthally polarized modes with Inline graphic and p=0. Magnifications of the different sections of the generation process are shown in Figure 2d. The desired light field Inline graphic for a specific z-position is realized in the Fourier plane (SLM2, observation plane) of SLM1.

The artificially generated field Inline graphic can be separated into its Inline graphic and Inline graphic parts, with each including two counter-propagating LG modes of the same helicity. For each polarization, one mode propagates in the +z-direction, and the other propagates in the -z-direction, which is achieved through digital propagation enabled by SLM1. The digital propagation was encoded as Inline graphic, in which we chose ϕ to be a discrete phase offset of –π/4. Using a CCD camera positioned in the observation plane, we recorded the intensity profile of the Inline graphic and Inline graphic components separately by shutting beams 3 and 4 or 1 and 2 (cf. Figure 2c and 2d), respectively. The results are shown in Figure 3. In Figure 3b, we show the simulated transverse intensity profile of Inline graphic when a horizontally aligned polarizer is positioned in front of the CCD, thus reflecting the polarization distribution illustrated in Figure 3a and Figure 1. The normalized intensity profiles for the Inline graphic (beam 1+2) and Inline graphic (beam 3+4) polarization components are shown in Figure 3c and 3d, respectively, for the different positions kzz + ϕ∈[0, π] (arrow at the bottom). For both the Inline graphic and Inline graphic parts, we observe a sinusoidal variation in the intensity that depends on kzz+ϕ, which represents a longitudinal interference pattern of included beams. Furthermore, the variation in intensity for Inline graphic and Inline graphic is out of phase, that is, the Inline graphic components carry maximum intensity while the Inline graphic parts are at minimum, and vice versa. This behavior is attributed to the phase shift Inline graphic, which was used to create orthogonally polarized vector beams (cf. Equation (6)). Moreover, these counter-fluctuating intensities evince the variation between pure vector and pure scalar states for Inline graphic If the Inline graphic Inline graphic polarized components are at a maximum, while the Inline graphic Inline graphic parts disappear, then Inline graphic is represented solely by the Inline graphic Inline graphic components, and thus, the light field is purely scalar with Inline graphic. In contrast, if the Inline graphic and Inline graphic parts are of equal intensity, then Inline graphic is a pure vector mode with Inline graphic. Between these extreme cases, a smooth transition is found (cf. Figure 3b).

Figure 3.

Figure 3

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Intensity profile of the investigated light field Inline graphic for various z-positions in units of kzz + ϕ (ϕ=−π/4) with corresponding polarization structure in (a). (b) Normalized intensity profile of the field Inline graphic, passing through a horizontally aligned polarizer (data from simulation). Experimental results of counter-oscillating intensities for (c) Inline graphic and (d) Inline graphic polarization components.

Entanglement oscillation

To quantitatively verify the longitudinal entanglement oscillation of Inline graphic, we performed an entanglement entropy analysis while digitally propagating the field. Using this approach, we determined the degree of entanglement Inline graphic as a function of kzz + ϕ. The respective experimental method is visualized in Figure 2c (blue box) and Figure 2e.

Figure 4a shows typical intensity images obtained in experiments per z-distance and from which E is computed. The illustrated case corresponds to the scalar field shown in Figure 4b. Figure 4b–4d shows the intensity values, normalized and arranged in the form of Table 1. Here, we show three cases: scalar, semi-vector and vector beam, with the corresponding values E=0.01, 0.32 and 0.94, respectively. The complete set of experimental E values obtained as a function of the propagation distance z is presented in Figure 5. Here, the degree of entanglement (Figure 5a) and the normalized intensity of the right-/left-handed circularly polarized light IR,L (Figure 5b) are illustrated as a function of kzz + ϕ. Errors of kzz + ϕ are given by SLM flickering (±π/16), whereby error bars for E (±0.05) or IR,L (±0.03) are given by inaccuracies within the experimental method/ system.

Figure 4.

Figure 4

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(a) Typical intensity images acquired by a CCD camera to determine the degree of entanglement E in the case of a scalar beam. The corresponding intensities Iuv with u,v∈{1, 2, 3}, arranged according to Table 1 for the cases of a (b) scalar, (c) semi-vector and (d) vector beams, with corresponding values of E=0.01, 0.32, 0.94.

Figure 5.

Figure 5

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Propagation dynamics of entanglement: (a) Entanglement analysis of pure radial vector mode (black triangles) and the light field Inline graphic. Measured E as a function of kzz + ϕ (ϕ=−π/4) of the latter is marked by black circles filled according to the ratio between the Inline graphic and Inline graphic parts (see scale bar). Exemplary modes are shown as green insets. The black dashed curve represents the theoretical fit according to Equation (7). (b) Respective intensity IR,L of the Inline graphic (red fit, black filled diamonds) and Inline graphic (blue fit, black hollow diamonds) components of Inline graphic, oscillating out of phase.

For comparison, we experimentally performed an entanglement analysis of a pure radial vector mode (beam 1+3). As theoretically expected (cf. Materials and Methods, Theory), this beam reveals an entanglement entropy of approximately E=1 for all propagation distances, as depicted by the black triangles in Figure 5a. In contrast, the entanglement dynamics of the light field Inline graphic given by Equation (6) confirms our theoretical predictions, oscillating between pure scalar and pure vector, as shown in Figure 5a. The data are represented by black circles filled according to the ratio between the included Inline graphic (blue) and Inline graphic (red) polarized parts (see scale bar). The green insets indicate the modes of light at specific positions. The experimental results reflect the theoretical description in Equation (7) with kzz replaced by kzz + ϕ' perfectly, as illustrated by the corresponding fit in Figure 5a (black dashed curve). The fitting parameter ϕ' has a value of −0.71 and, thus, almost matches the chosen setting of ϕ=−π/4.

Figure 5b shows simultaneously determined counter-fluctuating intensity curves for Inline graphic (blue fit, black hollow diamonds) and Inline graphic (red fit, black filled diamonds). Obviously, these curves mirror the propagation dynamics of entanglement and the involved variation in the ratio between Inline graphic and Inline graphic, as demonstrated in Figure 5a. A slight shift with respect to the positions of the extrema of Inline graphic and Inline graphic can be observed, which reflects the deviation between ϕ and ϕ'. Our findings prove that by adjusting ϕ, it is possible to transport a desired degree of entanglement in Inline graphic to a predefined z-position.

Discussion

Our results highlight the fact that it is possible to engineer vectorial light fields whose degree of non-separability oscillates in free-space, from fully vector to scalar, as a function of the propagation distance, through spin–orbit coupling. While we have restricted ourselves to first-order vector vortex beams for the demonstration, the concept that we outline here is more general and can be applied to higher-order vector vortex modes as well as, in principle, any vector state with judicious choice of degree of freedom.

The surprising result is that our entanglement dynamics occur in free space under unitary conditions. We emphasize that while we have performed our experiments with coherent light for convenience, the same results are obtained for local entanglement of the internal degrees of freedom of a single photon. Neither theory nor experiments differentiate between these two cases, and thus, we address topical questions as to the notion of local and classical entanglement and its propagation dynamics.

An important aspect of this work is the practical approach to the generation and propagation of the fields. It is possible to engineer the desired effect using a Sagnac interferometer in which an input radially polarized vector beam is split into two beams traveling along each arm: one of the beams is switched to azimuthal polarization, with a half-wave plate, and interfered with the radially polarized beam. In the third arm, both beams propagate in opposite directions while bearing orthogonal states of polarization, and they thus generate a standing wave whose degree of entanglement varies along the propagation axis. This generating approach does not allow one to experimentally verify the spatially variant degree of entanglement. We offer a more powerful approach that utilizes digital generation and propagation enabled by an SLM. This approach allowed us to manipulate each vector beam independently and, among other options, perform digital propagation on each. Hence, both vector beams propagate in a collinear fashion in a manner that simulates propagation in opposite directions. This approach of generation and propagation enabled us to realize any state of Inline graphic with a chosen degree of entanglement that can be adapted in real time by simply changing the displayed hologram.

Importantly, this approach allows us not only to monitor the degree of non-separability but also to provide on-demand specific states to the observer's positions. We believe that this method will enhance several noteworthy applications, namely, STED microscopy, optical trapping, quantum key distribution (QKD) and laser material processing systems, which we summarize graphically in Figure 6. For example, rapid changing of the mode type from circularly polarized light for cutting to radially polarized light for drilling would have clear benefits in processing materials with lasers17, 18, 19, while switching from a tight spot with radially polarized light to a donut beam with azimuthally polarized light (after an objective lens) is precisely the requirement for STED31, 32. In addition, the presented configuration paves the way for novel QKD approaches using a prepare-and-measure BB84 QKD protocol, with vector and scalar OAM modes as the orthogonal and mutually unbiased bases47, 48. This approach adds a new level of security to QKD protocols, since (as it has been noted to us) this work can be extended to a third dimension by considering the longitudinal mode function. Further, this tripartite description facilitates classical studies of GHZ-like states (see Supplementary Information), an exciting opportunity for further work with classically entangled states.

Figure 6.

Figure 6

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Exemplary applications of virtually counter-propagated, orthogonally polarized vector modes: (a) adjusting the mode at the focal region for, for example, STED microscopy systems, optical trapping or (b) laser material processing by digital propagation (phase shift ϕ), to create radially polarized beams for drilling and circularly polarized beams for cutting; (c) illustration of a novel quantum key distribution approach for the delivery of Alice's states to Bob.

Conclusions

We have demonstrated that by exploiting complex modes of light, it is possible to have an oscillating degree of local entanglement during propagation, even though the medium is considered to be unitary, that is, a medium in which the entanglement should not change. The result is a demonstration of spin–orbit coupling in paraxial light beams in free space. We have shown this effect with entangled internal degrees of freedom of polarization and spatial modes, and while our experiment was classical, the results hold equally well for local entanglement of the internal degrees of freedom of a single photon. In addition, we have demonstrated the concept behind the first tractor beam for local entanglement, which would be able to deliver a known degree of entanglement to some target plane. Our approach highlights intriguing questions about the notion of entanglement dynamics, opens a new topic in spin–orbit coupling and offers a new tool for a myriad of applications that would benefit from holographically controlled availability of vector and scalar states of light at the target plane.

Author contributions

The experiments were performed by EO and CRG, with theoretical input from BN. All of the authors contributed to the data analysis, interpretation of the results and writing of the manuscript. AF conceived the idea and supervised the project.

Acknowledgments

EO acknowledges financial support from the German Research Foundation DFG (EXC 1003 – CiM, TRR61), CRG from the Claude Leon foundation, and BN from the National Research Foundation of South Africa. We would like to thank Thomas Konrad and Andrea Aiello for useful advice, as well as the referees for pointing us toward the spin–orbit coupling and the tripartite GHZ-like description.

Footnotes

Note: Supplementary Information for this article can be found on the Light: Science & Applications’ website(http://www.nature.com/lsa).

The authors declare no conflict of interest.

Supplementary Material

Supplementary Information
Click here for additional data file. (465KB, pdf)

References

  1. Spreeuw RJC. A classical analogy of entanglement. Found Phys 1998; 28: 361–374. [Google Scholar]
  2. Pereira LJ, Khoury AZ, Dechoum K. Quantum and classical separability of spin-orbit laser modes. Phys Rev A 2014; 90: 053842. [Google Scholar]
  3. Guzman-Silva D, Brüning R, Zimmermann F, Vetter C, Gräfe M et al. Demonstration of local teleportation using classical entanglement. Laser Photonics Rev 2016; 10: 317–321. [Google Scholar]
  4. Souza CER, Huguenin JAO, Khoury AZ. Topological phase structure of vector vortex beams. J Opt Soc Am A 2014; 31: 1007–1012. [DOI] [PubMed] [Google Scholar]
  5. Vieira AR, Hor-Meyll M, Khoury AZ. Spin-orbit mode selection with a modified Sagnac interferometer. J Opt Soc Am B 2013; 30: 1623–1626. [Google Scholar]
  6. Pinheiro ARC, Souza CER, Caetano DP, Huguenin JAO, Schmidt AGM et al. Vector vortex implementation of a quantum game. J Opt Soc Am B 2013; 30: 3210–3214. [Google Scholar]
  7. Karimi E, Boyd RW. Classical entanglement? Science 2015; 350: 1172–1173. [DOI] [PubMed] [Google Scholar]
  8. Karimi E, Leach J, Slussarenko S, Piccirillo B, Marrucci L et al. Spin-orbit hybrid entanglement of photons and quantum contextuality. Phys Rev A 2010; 82: 022115. [Google Scholar]
  9. Galvez EJ, Khadka S, Schubert WH, Nomoto S. Poincaré-beam patterns produced by nonseparable superpositions of Laguerre-Gauss and polarization modes of light. Appl Opt 2012; 51: 2925–2934. [DOI] [PubMed] [Google Scholar]
  10. Aiello A, Töppel F, Marquardt C, Giacobino E, Leuchs G. Quantum-like nonseparable structures in optical beams. New J Phys 2015; 17: 043024. [Google Scholar]
  11. Ndagano B, Perez-Garcia B, Roux FS, McLaren M, Rosales-Guzmán C et al. Characterizing quantum channels with non-separable states of classical light. Nat Phys 2017; 13: 397–402. [Google Scholar]
  12. Souza CER, Borges CVS, Khoury AZ, Huguenin JAO, Aolita L et al. Quantum key distribution without a shared reference frame. Phys Rev A 2008; 77: 032345. [Google Scholar]
  13. Vallone G, D'Ambrosio V, Sponselli A, Slussarenko S, Marrucci L et al. Free-space quantum key distribution by rotation-invariant twisted photons. Phys Rev Lett 2014; 113: 060503. [DOI] [PubMed] [Google Scholar]
  14. Milione G, Nguyen TA, Leach J, Nolan DA, Alfano RR. Using the nonseparability of vector beams to encode information for optical communication. Opt Lett 2015; 40: 4887–4890. [DOI] [PubMed] [Google Scholar]
  15. Li PY, Wang B, Zhang XD. High-dimensional encoding based on classical nonseparability. Opt Express 2016; 24: 15143–15159. [DOI] [PubMed] [Google Scholar]
  16. Milione G, Lavery MPJ, Huang H, Ren YX, Xie GD et al. 4 × 20 Gbit/s mode division multiplexing over free space using vector modes and a q-plate mode (de)multiplexer. Opt Lett 2015; 40: 1980–1983. [DOI] [PubMed] [Google Scholar]
  17. Nivas JJJ, Cardano F, Song ZM, Rubano A, Fittipaldi R et al. Surface structuring with polarization-singular femtosecond laser beams generated by a q-plate. Sci Rep 2017; 7: 42142. [DOI] [PMC free article] [PubMed] [Google Scholar]
  18. Niziev VG, Nesterov AV. Influence of beam polarization on laser cutting efficiency. J Phys D 1999; 32: 1455–1461. [Google Scholar]
  19. Meier M, Romano V, Feurer T. Material processing with pulsed radially and azimuthally polarized laser radiation. Appl Phys A 2007; 86: 329–334. [Google Scholar]
  20. Töppel F, Aiello A, Marquardt C, Giacobino E, Leuchs G. Classical entanglement in polarization metrology. New J Phys 2014; 16: 073019. [Google Scholar]
  21. Berg-Johansen S, Töppel F, Stiller B, Banzer P, Ornigotti M et al. Classically entangled optical beams for high-speed kinematic sensing. Optica 2015; 2: 864–868. [Google Scholar]
  22. D'Ambrosio V, Spagnolo N, del Re L, Slussarenko S, Li Y et al. Photonic polarization gears for ultra-sensitive angular measurements. Nat Commun 2013; 4: 2432. [DOI] [PMC free article] [PubMed] [Google Scholar]
  23. Biss DP, Youngworth KS, Brown TG. Dark-field imaging with cylindrical-vector beams. Appl Opt 2006; 45: 470–479. [DOI] [PubMed] [Google Scholar]
  24. Zhan QW. Cylindrical vector beams: from mathematical concepts to applications. Adv Opt Photonics 2009; 1: 1–57. [Google Scholar]
  25. Chen R, Agarwal K, Sheppard CJR, Chen XD. Imaging using cylindrical vector beams in a high-numerical-aperture microscopy system. Opt Lett 2013; 38: 3111–3114. [DOI] [PubMed] [Google Scholar]
  26. Segawa S, Kozawa Y, Sato S. Demonstration of subtraction imaging in confocal microscopy with vector beams. Opt Lett 2014; 39: 4529–4532. [DOI] [PubMed] [Google Scholar]
  27. Dorn R, Quabis S, Leuchs G. Sharper focus for a radially polarized light beam. Phys Rev Lett 2003; 91: 233901. [DOI] [PubMed] [Google Scholar]
  28. Youngworth KS, Brown TG. Focusing of high numerical aperture cylindrical-vector beams. Opt Express 2000; 7: 77–87. [DOI] [PubMed] [Google Scholar]
  29. Zhan QW, Leger JR. Focus shaping using cylindrical vector beams. Opt Express 2002; 10: 324–331. [DOI] [PubMed] [Google Scholar]
  30. Lerman GM, Stern L, Levy U. Generation and tight focusing of hybridly polarized vector beams. Opt Express 2010; 18: 27650–27657. [DOI] [PubMed] [Google Scholar]
  31. Török P, Munro PRT. The use of Gauss-Laguerre vector beams in STED microscopy. Opt Express 2004; 12: 3605–3617. [DOI] [PubMed] [Google Scholar]
  32. Hao X, Kuang CF, Wang TT, Liu X. Effects of polarization on the de-excitation dark focal spot in STED microscopy. J Opt 2010; 12: 115707. [Google Scholar]
  33. Bliokh KY, Rodríguez-Fortuño FJ, Nori F, Zayats AV. Spin–orbit interactions of light. Nat Photonics 2015; 9: 796–808. [Google Scholar]
  34. Marrucci L, Manzo C, Paparo D. Optical spin-to-orbital angular momentum conversion in inhomogeneous anisotropic media. Phys Rev Lett 2006; 96: 163905. [DOI] [PubMed] [Google Scholar]
  35. Novitsky A, Qiu CW, Wang HF. Single gradientless light beam drags particles as tractor beams. Phys Rev Lett 2011; 107: 203601. [DOI] [PubMed] [Google Scholar]
  36. Brzobohatý O, Karásek V, Šiler M, Chvátal L, Čižmár T et al. Experimental demonstration of optical transport, sorting and self-arrangement using a ‘tractor beam’. Nat Photonics 2013; 7: 123–127. [Google Scholar]
  37. Ruffner DB, Grier DG. Optical conveyors: a class of active tractor beams. Phys Rev Lett 2012; 109: 163903. [DOI] [PubMed] [Google Scholar]
  38. Gorlach AA, Gorlach MA, Lavrinenko AV, Novitsky A. Matter-wave tractor beams. Phys Rev Lett 2017; 118: 180401. [DOI] [PubMed] [Google Scholar]
  39. McLaren M, Konrad T, Forbes A. Measuring the nonseparability of vector vortex beams. Phys Rev A 2015; 92: 023833. [Google Scholar]
  40. Wootters W. Entanglement of formation and concurrence. Quantum Inf Comput 2001; 1: 27–44. [Google Scholar]
  41. Hill S, Wootters WK. Entanglement of a pair of quantum bits. Phys Rev Lett 1997; 78: 5022–5025. [Google Scholar]
  42. Goodman JW. Introduction to Fourier Optics. 2 edn. New York: McGraw-Hill; 1996.
  43. Rosales-Guzmán C, Forbes A. How to Shape Light with Spatial Light Modulators. SPIE Press; 2017.
  44. Rosales-Guzmán C, Bhebhe N, Mahonisi N, Forbes A. Multiplexing 200 spatial modes with a single hologram. J Opt 2017; 19: 113501. [Google Scholar]
  45. Rosales-Guzmán C, Bhebhe N, Forbes A. Simultaneous generation of multiple vector beams on a single SLM. Opt Express 2017; 25: 25697–25706. [DOI] [PubMed] [Google Scholar]
  46. Ndagano B, Sroor H, McLaren M, Rosales-Guzmán C, Forbes A. Beam quality measure for vector beams. Opt Lett 2016; 41: 3407–3410. [DOI] [PubMed] [Google Scholar]
  47. Ndagano B, Nape I, Perez-Garcia B, Scholes S, Hernandez-Aranda RI et al. A deterministic detector for vector vortex states. Sci Rep 2017; 7: 13882. [DOI] [PMC free article] [PubMed] [Google Scholar]
  48. Sit A, Bouchard F, Fickler R, Gagnon-Bischoff J, Larocque H et al. High-dimensional intracity quantum cryptography with structured photons. Optica 2017; 4: 1006–1010. [Google Scholar]

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