Skip to main content
NCBI home page
Scientific Reports logoLink to Scientific Reports
. 2013 Jul 5;3:2143. doi: 10.1038/srep02143

All-Versus-Nothing Proof of Einstein-Podolsky-Rosen Steering

Jing-Ling Chen 1,2,a, Xiang-Jun Ye 1,2, Chunfeng Wu 2,6, Hong-Yi Su 1,2, Adán Cabello 3, L C Kwek 2,4, C H Oh 2,5
PMCID: PMC3701892  PMID: 23828242

Abstract

Einstein-Podolsky-Rosen steering is a form of quantum nonlocality intermediate between entanglement and Bell nonlocality. Although Schrödinger already mooted the idea in 1935, steering still defies a complete understanding. In analogy to “all-versus-nothing” proofs of Bell nonlocality, here we present a proof of steering without inequalities rendering the detection of correlations leading to a violation of steering inequalities unnecessary. We show that, given any two-qubit entangled state, the existence of certain projective measurement by Alice so that Bob's normalized conditional states can be regarded as two different pure states provides a criterion for Alice-to-Bob steerability. A steering inequality equivalent to the all-versus-nothing proof is also obtained. Our result clearly demonstrates that there exist many quantum states which do not violate any previously known steering inequality but are indeed steerable. Our method offers advantages over the existing methods for experimentally testing steerability, and sheds new light on the asymmetric steering problem.

Quantum nonlocality is an invaluable resource in numerous quantum information protocols. It is part of a hierarchical structure1: quantum states that have Bell nonlocality2 form a subset of Einstein-Podolsky-Rosen steerable states which, in turn, form a subset of entangled states. The concept of steering can historically be traced back to Schrödinger's reply3 to the Einstein-Podolsky-Rosen argument4, and it has since been rigorously formulated by Wiseman, Jones, and Doherty1.

Within the steering scenario, Alice prepares a bipartite system, keeps one particle and sends the other one to Bob. She announces that the Bob's particle is entangled with hers, and thus that she has the ability to “steer” the state of Bob's particle at a distance. This means that she could prepare Bob's particle in different states by measuring her particle using different settings. However, Bob does not trust Alice; Bob worries that she may send him some unentangled particles and fabricate the results using her knowledge about the local hidden state (LHS) of his particles. Bob's task is to prove that no such hidden states exist.

The study of Bell nonlocality have witnessed phenomenal developments to date with important widespread applications5,6,7. Its existence can be demonstrated through two different approaches: the first concerns the violations of Bell inequalities, and the second relies on an all-versus-nothing (AVN) proof without inequalities8,9,10,11. The AVN proof shows a logical contradiction between the local-hidden-variable models and quantum mechanics, and thus offers an elegant argument of the nonexistence of local-hidden-variable models. What is possible with Bell nonlocality and local hidden variables should also be possible with steering and local hidden states. In stark contrast to Bell nonlocality, the study of steering is still at its infancy. Recent works like Refs. 1,12 put steering on firmer grounds. Like Bell nonlocality, this topic is generally of broad interest, as it hinges on questions pertaining to the foundations of quantum physics13, and at the same time reveals new possibilities for quantum information14. Einstein-Podolsky-Rosen steering can be detected through the violation of a steering inequality, which rules out the LHS model in the same spirit in which the violation of a Bell inequality rules out the local-hidden-variable model. Recently, several steering inequalities have been proposed and experimentally tested15,16,17,18. Nevertheless, steering is far from being completely understood and the subject deserves further investigation.

The AVN proof for Bell nonlocality8,9,10,11 has been developed to rule out any local-hidden-variable models. Likewise, it is interesting to find out if there an analogous AVN proof which can rule out any LHS models for steering. The purpose of this work is to present an affirmative answer to this question by showing that Einstein-Podolsky-Rosen steering without inequalities exists in a two-qubit system. This proof is an analogy of AVN argument for Bell nonlocality without inequalities, and offers advantages over the existing methods for experimentally testing steerability as well as shedding new light on the asymmetric steering problem. In addition, a steering inequality based on the AVN proof is also obtained.

Results

Steering without inequalities for two qubits

The two-setting steering scenario can be described as follows: at the beginning, Alice prepares a two-qubit state ρAB. She keeps one qubit and sends the other to Bob. She then announces that it is entangled with the one she holds (see Fig. 1), and that she could remotely “steer” his state by projective measurements Inline graphic, with Inline graphic the measurement direction, a (with a = 0, 1) the Alice's measurement result, Inline graphic the 2 × 2 identity matrix, and Inline graphic the vector of the Pauli matrices. Bob then asks Alice to perform two projective measurements Inline graphic and Inline graphic (with Inline graphic) on her qubit and to tell him the measurement results of a. After Alice's measurement has been done, Bob obtains the four conditional states Inline graphic. Alice could cheat Bob if there exists an ensemble Inline graphic (see the gray box with colored particles in Fig. 1) and a stochastic map Inline graphic from ξ to a, such that the following equations hold,

graphic file with name srep02143-m1.jpg

In order for Bob to be convinced that Alice can steer his state, Bob needs to be sure that no such hidden states are indeed possible. If we demand that Bob's states possess an LHS description, then his density matrices should satisfy Eq. (1). A contradiction among the four equations, meaning that they cannot have a common solution of Inline graphic and Inline graphic, convinces Bob that an LHS model does not exist and that Alice can steer the state of his qubit.

Figure 1. The steering scenario illustration.

Figure 1

Open in a new tab

Alice first prepares a two-qubit state and keeps one qubit. She then sends the other qubit to Bob and announces that it is entangled with the one she possesses (see the pair of red balls and green arrows). Thus she could remotely “steer” Bob's state by projective measurements. However, Bob does not trust Alice and he worries that she may fabricate the results using her knowledge about LHS. In the two-setting steering scenario, Bob asks Alice to perform two specific projective measurements on her qubit (see the red dashed arrow) and to let him know the measurement results (see the blue dashed arrow). After Alice's measurement (see the measurement device), Bob obtains four conditional states (see the dashed circle). Alice could cheat Bob if there exists an ensemble (see the gray box with colored particles) and a stochastic map, such that the set of equations (1) holds. To be convinced that Alice can steer his state, Bob needs to confirm that no such hidden states are possible.

It is worth mentioning that the set of equations (1) plays an analogous role to the one in the standard Greenberger-Horne-Zeilinger (GHZ) argument8. The principal difference between the arguments is that the set of equations in (1) deal with density matrices whereas in the GHZ argument, each equation pertains to the outcomes of measurements and therefore corresponds to real numbers. The constraints imposed by LHS model on density matrices are much stricter than constraints imposed by real numbers. This provides an intuitive explanation as to why AVN proof would work for the Einstein-Podolsky-Rosen steering of two-qubit states.

Suppose that Alice initially prepares a product state ρAB = |ψA〉〈ψA| Inline graphic |ψB〉〈ψB|. It can be verified that, for any projective measurement Inline graphic (with Inline graphic and Inline graphic) performed by Alice, Bob always obtains two identical pure normalized conditional states as Inline graphic, (a = 0, 1), which means that Alice cannot steer Bob's state. Moreover, Bob can obtain two identical pure normalized conditional states if and only if ρAB is a direct-product state. Hence, hereafter we assume that Inline graphic and Inline graphic are two different pure states, i.e., Inline graphic.

For a general ρAB, Inline graphic are not pure. If they are pure, then ρAB possesses the following uniform form:

graphic file with name srep02143-m29.jpg

where Inline graphic are eigenstates of Inline graphic, Inline graphic is a 2 × 2 complex matrix under the positivity condition of ρAB, and Inline graphic is the Hermitian conjugation of Inline graphic.

For ρAB, it is not difficult to find that Inline graphic if and only if ρAB is separable, and the state ρAB admits a LHS (which means that it is not steerable) if and only if Inline graphic (see the Methods section). In a two-setting steering protocol of Inline graphic, if Bob can obtain two different pure normalized conditional states along Alice's projective direction Inline graphic (or Inline graphic), the following three propositions are equivalent: (i) Inline graphic. (ii) ρAB is entangled. (iii) No LHS model exists for Bob's states, so ρAB is steerable (in the sense of Alice steering Bob's state). We thus have our steering argument concluded, and that is given any two-qubit entangled state, the existence of certain projective measurement by Alice so that Bob's normalized conditional states are two different pure states provides a criterion for Alice-to-Bob steerability.

Although the standard GHZ argument is elegant for providing a full contradiction between local-hidden-variable model and quantum mechanics (with 100% success probability), its validity is only limited to some pure states with high symmetry, such as N-qubit GHZ states and cluster states with N ≥ 319. Hardy attempted to extend the GHZ argument to an arbitrary two-qubit system9. However, Hardy's argument works for only 9% of the runs of a specially constructed experiment. Moreover, Hardy's proof is not valid for two-qubit maximally entangled state. To overcome this, Cabello proposed an AVN proof for two observers, each possessing a two-qubit maximally entangled state10,11. Nowadays, there is no AVN proof of Bell nonlocality for a genuine two-qubit state presented. However, we show that for any two-qubit entangled state ρAB, if there exists a projective direction Inline graphic such that Bob's normalized conditional states Inline graphic become two different pure states, then Alice can steer Bob's state. Our steering argument is not only valid for two-qubit pure states, but it is also applicable to a wider class of states including mixed states.

The AVN proof versus the known steering inequalities

Let us compare our result with the known steering inequalities. First, they play different roles in demonstrating steering: steering inequality follows a similar approach to the Bell inequality for Bell nonlocality, while steering without inequality serves as an analogous counterpart to the GHZ test of Bell nonlocality without Bell inequalities.

Secondly, our argument shows that there are many quantum steerable states that do not violate any known steering inequalities. For an example, consider the state

graphic file with name srep02143-m2.jpg

where |Ψ(θ)〉 = cos θ|00〉 + sin θ|11〉, |Φ(θ)〉 = cos θ|10〉 + sin θ|01〉. It is entangled when V ∈ [0, 1/2) ∪ (1/2, 1] and θ ∈ (0, π/2). It can be easily verified that, for state (2), after Alice performs an Inline graphic-direction measurement on her qubit, Bob's normalized conditional states are just two different pure states, cos θ|0〉 + sin θ|1〉 and cos θ|0〉 − sin θ|1〉. Thus, based on our AVN proof of steering, Alice can always steer Bob's state using just a two-setting protocol Inline graphic. On the other hand, a class of N-setting steering inequality Inline graphic has been introduced in Ref. 15 to show the ability of Alice steering Bob's state. By running a numerical check of a 10-setting steering inequality of the above form, we observe that, for some regions of V and θ, the steering inequality cannot detect the steering of state (2)(as shown in Fig. 2 a). The colors denote different violation values, as shown in the legend. The blank region indicates that the steerability of state (2) cannot be detected by resorting to this inequality.

Figure 2.

Figure 2

Open in a new tab

(a) Detecting steerability of the state (2) using the ten-setting steering inequalities.We explore the steering of state (2) via violation of the ten-setting inequality presented in Ref. 15. The colors denote different values of quantum violation, as scaled in the legend. The blank region indicates that steerability of (2) cannot be detected by this inequality. With the replacement Inline graphic and Inline graphic in the above inequality, one obtains a similar steering inequality Inline graphic to show Bob's ability of steering Alice's state. The inequality Inline graphic yields the same violation region. This indicates that steering inequalities in Ref. 15 cannot reveal asymmetric steering. (b) Detecting steerability using the steering inequality (3). We show the steering of the state ρcol through violation of inequality (3). Quantum prediction of the left-hand-side of the inequality always succeeds 0 unless V = 0 or θ = 0, π/2.

Finally, unlike quantum entanglement and Bell nonlocality, the definition of steering is asymmetric1,20. Our AVN proof can shed light on this problem. The state (2) is not symmetric under a permutation of Alice and Bob (even with local unitary transformations acting on the state). The known steering inequalities in Ref. 15 do not reveal asymmetric steering (see Fig. 2 a). However, our argument presents a promising way to reveal asymmetric steering. According to our AVN proof, the state (2) exhibits two-setting asymmetric steering. On one hand, Alice can always steer Bob's state using just the two-setting protocol Inline graphic. On the other hand, after Bob has performed a projective measurement along an arbitrary Inline graphic-direction on his qubit, Alice's normalized conditional states can never be cast into two different pure states, allowing for the existence of LHS models. Take the state with parameters V = 3/5 and θ = π/8 as an example (whose corresponding point is outside of the colored region in Fig. 2 a): Numerical results show that, for any two-setting protocol Inline graphic, there is always a solution of LHS for Alice's conditional states. In short, this example illustrates a state in which the steering scenario is not interchangeable. This result can be of practical importance, since asymmetric steering has applications in one-way quantum cryptography21 and may have potential applications in other fields of quantum information processing.

A steering inequality

It is known that a Bell inequality can be derived from the GHZ argument22. This is also the case for the steering without inequalities argument. The steering inequality equivalent to the AVN proof reads

graphic file with name srep02143-m3.jpg

subject to the constraint Inline graphic. Here Inline graphic are projectors as Inline graphic, Inline graphic, Inline graphic, with Inline graphic orthogonal to Inline graphic, Inline graphic, Inline graphic, Inline graphic, and Inline graphic is the upper bound for the LHS model. Its physical implication can be described as follows: Suppose Alice performs a projective measurement in the Inline graphic-direction and finds that Bob can obtain two different pure normalized conditional states, then Inline graphic. They then perform a joint-measurement Inline graphic (in which Alice's measurement direction is perpendicular to Inline graphic-direction). According to Lemma 2 (see the Methods section), the LHS model requires Inline graphic, thus the probability Inline graphic is bounded by CLHS. However, with quantum mechanics, this bound is always exceeded due to a non-vanishing Inline graphic.

As an instance, we investigate the steering of state Inline graphic, with color noise Inline graphic by using our inequality (3). We find that Bob's conditional states on Alice's projective measurement in the z-direction are two different pure states |0〉〈0| and |1〉〈1|, and the upper bound is CLHS = (1 + V | cos 2θ|)/4. The quantum prediction of the left-hand-side of inequality (3) reads Inline graphic for θ ∈ [0, π/4], and Inline graphic for θ ∈ [π/4, π/2], which do not vanish unless V = 0 or θ = 0, π/2 (see Fig. 2 b). The violation of the inequality clearly demonstrates that the state ρcol possesses steerability except V = 0 or θ = 0, π/2.

Discussion

We have presented an AVN proof of Einstein-Podolsky-Rosen steering for two qubits without inequalities based on a two-setting steering protocol. The argument is valid for any two-qubit entangled state, both pure and mixed. We show that many quantum states that do not violate any known steering inequalities are indeed steerable states. This provides a new perspective for understanding steerability and offers an elegant argument for the nonexistence of LHS models without resorting to steering inequalities. The result also sheds new light on the asymmetric steerability – a phenomenon with no counterpart in quantum entanglement and Bell nonlocality. The result is testable through measurements of Bob's conditional states and provides a simple alternative to the existing experimental method for detecting steerability15,16,17,18. Theoretically, a two-setting steering protocol can be used to show that no LHS models exist for ρAB if the state satisfies the condition given in our AVN argument. Experimentally, the determination of the steerability of a quantum state can be done by performing quantum state tomography23 on Bob's qubit. Moreover, a steering inequality is obtained from our AVN argument, and this inequality offers another way to test steerability of states. Like Bell nonlocality whose importance has only been realized with the rapid development of quantum information science, we anticipate further developments in this exciting area.

Methods

We prove two Lemmas in the section. The steerability of ρAB is equivalent to that of the state Inline graphic. It is always possible for Alice to choose an appropriate unitary matrix Inline graphic that rotates the direction Inline graphic to the direction Inline graphic. Therefore, we can initially set Inline graphic by studying the state Inline graphic instead of ρAB. After Alice performs a projective measurement in the Inline graphic-direction, Bob's unnormalized conditional states are

graphic file with name srep02143-m5.jpg
graphic file with name srep02143-m4.jpg

with Inline graphic, Inline graphic, Inline graphic, and Inline graphic. Then one has

graphic file with name srep02143-m82.jpg

Lemma 1

Inline graphic if and only if Inline graphic is separable.

Proof

Look at the form of Inline graphic, obviously Inline graphic implies Inline graphic is separable. To prove the converse, one needs the definition of separability: Inline graphic, where τAi and τBi are, respectively, Alice and Bob's local density matrices, and pi > 0 satisfy Inline graphic. For convenience, let Inline graphic denote the element of Alice's density matrix τAi. By calculating Inline graphic and Inline graphic, one has Inline graphic, Inline graphic and Inline graphic be two pure states that are orthogonal to |ϕ1〉 and |ϕ2〉, respectively. Notice that Inline graphic, thus, for any index i, we have Inline graphic, which results in

graphic file with name srep02143-m6.jpg

Since Inline graphic, they cannot be simultaneously perpendicular to the state τBi, thus Inline graphic, which yields Inline graphic due to positivity condition of τAi. So Inline graphic. Lemma 1 is henceforth proved.

Lemma 2

The state Inline graphic admits a local-hidden-state (LHS) model (which means that it is not steerable) if and only if Inline graphic.

Proof

Inline graphic implies Inline graphic is separable, thus Inline graphic admits a LHS model. Now we focus on the proof of necessity. If Alice's measurement setting is Inline graphic, then one has

graphic file with name srep02143-m8.jpg
graphic file with name srep02143-m7.jpg

Substitute Eqs. (4a)(4b)(6a)(6b) into Eq. (1) and due to Inline graphic and Inline graphic, one immediately has ρξ ∈ {|ϕ1〉〈ϕ1|, |ϕ2〉〈ϕ2|} for any ξ. Based on which, Eqs. (6a) (6b) are valid only if Inline graphic, with αx, Inline graphic. Similarly, if Alice's measurement setting is Inline graphic, then one has Inline graphic, with αy, Inline graphic. If there exists a LHS model for Bob's states, then Inline graphic, with α = αx + y, β = βx + y. Substitute Inline graphic into Eq. (5), we have

graphic file with name srep02143-m118.jpg

with Inline graphic and Inline graphic. Now we construct the following two projectors: Inline graphic, Inline graphic, where |χ1〉 is the eigenvector of Tα with eigenvalue Inline graphic, and |χ2〉 is the eigenvector of Tβ with eigenvalue Inline graphic. Because Inline graphic is a density matrix, one has

graphic file with name srep02143-m126.jpg

This leads to Inline graphic. Lemma 2 is henceforth proved.

Three measurement settings were mentioned in the proof of Lemma 2. This does not mean that we need a three-setting protocol to show steering. For a given entangled state Inline graphic, a two-setting protocol is enough to demonstrate steering. Lemma 2 shows that Inline graphic and Inline graphic cannot be linearly expanded of |ϕ1〉〈ϕ1| and |ϕ2〉〈ϕ2| simultaneously (because that means Inline graphic and ρAB is separable). For a given Inline graphic, if Inline graphic, then using Inline graphic to demonstrate steering, otherwise using Inline graphic.

Author Contributions

J.L.C. initiated the idea. J.L.C., X.J.Y., H.Y.S. and C.W. established the proof. J.L.C., C.W., A.C., L.C.K. and C.H.O. wrote the main manuscript text. H.Y.S. and X.J.Y. prepared figures 1 and 2. All authors reviewed the manuscript.

Acknowledgments

J.L.C. is supported by the National Basic Research Program (973 Program) of China under Grant No. 2012CB921900 and the NSF of China (Grant Nos. 10975075 and 11175089). A.C. is supported by the Spanish Project No. FIS2011-29400. This work is also partly supported by the National Research Foundation and the Ministry of Education, Singapore (Grant No. WBS: R-710-000-008-271).

Reprints and permission information is available at www.nature.com/reprints.

References

  1. Wiseman H. M., Jones S. J. & Doherty A. C. Steering, entanglement, nonlocality, and the Einstein-Podolsky-Rosen paradox. Phys. Rev. Lett. 98, 140402 (2007). [DOI] [PubMed] [Google Scholar]
  2. Bell J. S. On The Einstein Podolsky Rosen Paradox. Physics (Long Island City, N.Y.) 1, 195 (1964). [Google Scholar]
  3. Schrödinger E. Discussion of probability relations between separated systems. Proc. Cambridge Philos. Soc. 31, 555–563 (1935). [Google Scholar]
  4. Einstein A., Podolsky B. & Rosen N. Can Quantum-Mechanical Description of Physical Reality Be Considered Complete? Phys. Rev. 47, 777 (1935). [Google Scholar]
  5. Ekert A. K. Quantum cryptography based on Bells theorem. Phys. Rev. Lett. 67, 661 (1991). [DOI] [PubMed] [Google Scholar]
  6. Brukner Č., Żukowski M., Pan J.-W. & Zeilinger A. Bells Inequalities and Quantum Communication Complexity. Phys. Rev. Lett. 92, 127901 (2004). [DOI] [PubMed] [Google Scholar]
  7. Pironio S. et al. Random numbers certified by Bell's theorem. Nature (London) 464, 1021 (2010). [DOI] [PubMed] [Google Scholar]
  8. Greenberger D. M., Horne M. A. & Zeilinger A. in Bell's Theorem, Quantum Theory, and Conceptions of the Universe (eds Kafatos M.) 69 (Kluwer, Dordrecht, Holland, 1989). [Google Scholar]
  9. Hardy L. Nonlocality for two particles without inequalities for almost all entangled states. Phys. Rev. Lett. 71, 1665 (1993). [DOI] [PubMed] [Google Scholar]
  10. Cabello A. Bell's Theorem without Inequalities and without Probabilities for Two Observers. Phys. Rev. Lett. 86, 1911 (2001). [DOI] [PubMed] [Google Scholar]
  11. Cabello A. “All versus Nothing” Inseparability for Two Observers. Phys. Rev. Lett. 87, 010403 (2001). [DOI] [PubMed] [Google Scholar]
  12. Jones S. J., Wiseman H. M. & Doherty A. C. Entanglement, Einstein-Podolsky-Rosen correlations, Bell nonlocality, and steering. Phys. Rev. A 76, 052116 (2007). [DOI] [PubMed] [Google Scholar]
  13. Oppenheim J. & Wehner S. The Uncertainty Principle Determines the Nonlocality of Quantum Mechanics. Science 330, 1072 (2010). [DOI] [PubMed] [Google Scholar]
  14. Branciard C., Cavalcanti E. G., Walborn S. P., Scarani V. & Wiseman H. M. One-sided device-independent quantum key distribution: Security, feasibility, and the connection with steering. Phys. Rev. A 85, 010301(R) (2012). [Google Scholar]
  15. Saunders D. J., Jones S. J., Wiseman H. M. & Pryde G. J. Experimental EPR-steering using Bell-local states. Nature Phys. 6, 845 (2010). [Google Scholar]
  16. Smith D. H. et al. Conclusive quantum steering with superconducting transition edge sensors. Nature Comm. 3, 625 (2012). [DOI] [PMC free article] [PubMed] [Google Scholar]
  17. Bennet A. J. et al. Arbitrarily loss-tolerant Einstein-Podolsky-Rosen steering allowing a demonstration over 1 km of optical fiber with no detection loophole. Phys. Rev. X 2, 031003 (2012). [Google Scholar]
  18. Wittmann B. et al. Loophole-free quantum steering. New J. Phys. 14, 053030 (2012). [Google Scholar]
  19. Scarani V., Acín A., Schenck E. & Aspelmeyer M. Nonlocality of cluster states of qubits. Phys. Rev. A 71, 042325 (2005). [Google Scholar]
  20. Händchen V. et al. Observation of one-way EinsteinPodolskyRosen steering. Nature Photonics 6, 596 (2012). [Google Scholar]
  21. Olsen M. K. & Bradley A. S. Bright bichromatic entanglement and quantum dynamics of sum frequency generation. Phys. Rev. A 77, 023813 (2008). [Google Scholar]
  22. Mermin N. D. Extreme quantum entanglement in a superposition of macroscopically distinct states. Phys. Rev. Lett. 65, 1838 (1990). [DOI] [PubMed] [Google Scholar]
  23. James D. F. V., Kwiat P. G., Munro W. J. & White A. G. Measurement of qubits. Phys. Rev. A 64, 052312 (2001). [Google Scholar]

Articles from Scientific Reports are provided here courtesy of Nature Publishing Group

RESOURCES