Abstract
An invisibility cloak provides a way to hide an object under the detection of waves. A good cloak guides the incident waves through the cloaking shell with few distortion. Even if one day a nearly perfect cloak is built, some important quantum effects, such as dephasing of the electron spin or photon polarization, may still remain. In this work, we consider the possibility that using the temporal steering of these degrees of freedom to detect the existence of an invisibility cloak.
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Introduction
Invisibility cloak based on the transformation design method (TDM) has attracted great attentions in the past decade1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18. The main idea of the TDM is to perform the coordinate transformation on the wave equation of the corresponding cloaking wave to create the hiding region (Fig. 1). To keep the form of the equation invariant, the metric tensors are combined with the specific parameters, which are usually the properties of the material of the cloaking shell. For instance, the TDM for electromagnetic waves1,2,3 reinterprets the effect of the coordinate transformation in conductivity and permeability of the original non-transformed system. Similarly, cloaking of matter waves4,5,6,7,8,19,20,21,22,23 requires a proper design of the effective mass and potential of the cloaking shell. There are also other kinds of cloak, such as cloaking of elastic waves9,10,11,12,13,14, liquid waves15,16, heat flows17,18, etc. Waves incident onto the cloak designed by the TDM are guided through the cloaking shell without any scattering and distortion.
Einstein-Podolsky-Rosen (EPR) steering24,25,26,27 is one of the quantum correlations that allows one party to remotely prepare some specific states for the other party via choosing different measurement settings. The degree of the non-locality of EPR steering is stronger than the entanglement but weaker than the Bell non-locality26. EPR steering can be verified via the steering inequalities27, which are built on the fact that the correlations cannot be explained by the local hidden state model. Apart from the correlations between two (or more) parties, quantum correlations may also occur in single party at different times. For example, Leggett and Garg derived an inequality28,29 under the assumption of macroscopic realism and non-invasive measurement. It can be used to verify the quantum coherence of a macroscopic system under the weak measurements30. Recently, a temporal analog of the steering inequality—the temporal steering inequality31—also focuses on the correlations of a single party at different times. Moreover, the classical bound of temporal steering inequality is found to have deep connection with the quantum cryptography.
Motivated by these developments, we ask the question: how to crack an invisibility cloak when a nearly perfect cloak is built? Given the fact that some quntum effect, such as dephasing, is almost inevitable for the waves passing through a material, we consider the possibility that using the temporal steering to crack the invisibility cloak. For concreteness, we consider the invisibility cloak of the electromagnetic waves and the electron matter waves. We assume the polarizations of the incident electromagnetic waves suffer a phase damping when passing through the cloaking shell. Secondly, since the spin of the incident matter waves (e.g., an electron) may interact with the hiding object when passing through the cloaking shell, we assume the incident particle experiences a coherent coupling. The feature of temporal steering inequality is that the temporal steering parameter always maintains the maximal value if the wave does not interact with other ancillary systems (or environment). Our results show that the temporal steering parameter of the incident waves varies with the traveling time in the cloaking shell and therefore the temporal steering may be used to crack the invisibility cloak.
Results
Transformation design method for waves
One of the crucial points in the TDM for waves is to perform the appropriate coordinate transformation on the spatial (time-independent) wave equation from the coordinate system q to and keep the form invariant1,7,8
where reinterprets the effect of the coordinate transformation in the material properties of the cloaking shell.
The behavior of the incident waves can be visualized through the current density J, with the continuity equation
where is the probability density of the wave function. The incident plane wave could be the electromagnetic wave (photons) or the matter wave (electrons). One can use the relation, , to obtain the classical trajectory of the incident particle32. In classical limit, the velocity vector v is tangent to the particle trajectory. Therefore, the trajectory of the incident waves can be obtained from the current density (Fig. 2).
Moreover, it is necessary to estimate the time interval ts of the incident particle staying inside the cloaking shell. The phase of the incident wave after passing through the shell of a perfect cloak should be the same as that traveling in free space. Thus, the time intervals for different trajectories should be the same. As an example, we consider two trajectories, representing the path that the particles travel from x = −L to x = +L with and without passing through the shell, respectively (Fig. 2). The time interval ts can then be easily obtained
where is the velocity of the incident particle outside the cloak.
Temporal steering inequality
Now, we briefly describe the concept of the temporal steering inequality31. Consider a two-level system sent into one of the channels λ with the probability qλ. During the transmission, there are two observers, Alice and Bob. Firstly, Alice performs the measurement on the system at time tA along the basis i with the outcomes . Then, the system is suffered from the influence of the channel for a time interval before Bob receives it. When Bob receives the system at time tB, he obtains the outcomes by performing the measurement along the same setting i. If Alice's choice of measurement has no influence on the state that Bob receives, the following temporal steering inequality holds
and the bound that quantum mechanics gives is
where N(=2 or 3) is the number of the mutually unbiased measurements that Bob implements on the system, and
with
Here, Bob's expectation value conditioned on Alice’s result is defined as
Here, we would like to use two measurement settings, the and bases, rather than three. Since three measurement settings are sufficient to perform the quantum state tomography, using the temporal steering inequality thus requires fewer resources. We use one of the features of the temporal steering parameter in equation (4) to detect the quantum cloak (inset of Fig. 3): If the system does not suffer any interaction, quantum mechanics predicts that always maintains the maximal value 2. If varies with time, the system is subject to some dynamics.
Cracking electromagnetic cloak by using the temporal steering.
We assume the incident photons suffer a phase damping with decay rate γ when traveling through the cloaking shell. The state of the polarizations can be described by the density matrix , where , with and being the horizontal and vertical polarizations, respectively. The initial state is prepared in the maximally mixed state
The evolution of the polarizations inside the cloaking shell can be obtained by solving the following Markovian master equation with Lindblad form33,34
where σz is the Pauli-z matrix. From equations (4), (9) and (10) the steering parameter can be obtained straightforwardly
where ts is defined in equation (3). Here, the two bases are and . The dynamics of the temporal steering parameter of the polarizations is plotted in Fig. 3. We can see that the temporal steering parameter varies with time inside the shell (ts). Therefore, the electromagnetic cloak is cracked by using the temporal steering.
Cracking quantum cloak by using the temporal steering
In this section, we use the temporal steering parameter to detect the dynamics of the spin of a quantum particle inside the cloaking shell. For simplicity, we consider the incident matter wave with the spin-1/2 degree of freedom, e.g. electrons. We further assume the spin of the electron experiences the coherent coupling from the ancillary spin hidden inside the cloaking shell. The state of the incident spin can be described as , where , with and being the spin-up and spin-down state, respectively. The interaction Hamiltonian can be written as , where and are the raising and lowering operators of the i th spin and is the coupling strength. The evolution of the entire system inside the cloaking shell can be obtained by the quantum Liouville equation
The state of the incident electron ρ1(t) can be obtained by tracing out the ancillary electron, i.e. . We choose the initial state as
The temporal steering parameter is then written as
where the two bases are Pauli and . From Fig. 4, we can see that varies with time, indicating the incident electron is influenced by the hiding spin. Therefore, the quantum cloak is cracked by using the temporal steering.
Discussion
One may notice that there are other ways to crack the electromagnetic cloak. For example, using the classical polarized fields, one can measure the alternation of the coherence due to the dephasing effect. Besides, if the electromagnetic cloak is designed within a finite frequency range, the cloak can be easily detected by using the electromagnetic waves with the frequency outside that range. To crack the quantum cloak, a simple way is to detect whether the direction of the spin is changed. However, this method requires the measurement direction of the receiver to be synchronized with that of the sender. In the temporal steering scenario, there is no such constraint, i.e. the steering inequality still holds even if the bases are not synchronized31. Another way to crack the quantum cloak is the quantum state tomography. In this case, one has to use three bases (for qubit system) to perform the tomography, whereas one only needs two bases for the temporal steering inequality. One may also use the degree of entanglement to detect the cloak: preparing initially the entangled pair, sending one of them into the shell and measuring the degradation of the entanglement. In conclusion, the temporal steering provides one of the feasible ways to crack both the electromagnetic and quantum cloak.
Additional Information
How to cite this article: Chen, S.-L. et al. Detecting the existence of an invisibility cloak using temporal steering. Sci. Rep. 5, 15571; doi: 10.1038/srep15571 (2015).
References
Pendry, J. B., Schurig, D. & Smith, D. R. Controlling electromagnetic fields. Science 312, 1780–1782 (2006).
Leonhardt, U. Optical conformal mapping. Science 312, 1777–1780 (2006).
Schurig, D. et al. Metamaterial electromagnetic cloak at microwave frequencies. Science 314, 977–980 (2006).
Zhang, S., Genov, D. A., Sun, C. & Zhang, X. Cloaking of matter waves. Phys. Rev. Lett. 100, 123002 (2008).
Lin, D.-H. & Luan, P.-G. Cloaking of matter waves under the global aharonov-bohm effect. Phys. Rev. A 79, 051605 (2009).
Lin, D.-H. Cloaking two-dimensional fermions. Phys. Rev. A 84, 033624 (2011).
Chen, S.-L. & Lin, D.-H. Multidimensional transformation design method for matter waves. Phys. Rev. A 86, 043606 (2012).
Chang, Y.-H. & Lin, D.-H. Parabolic transformation cloaks for unbounded and bounded cloaking of matter waves. Phys. Rev. A 89, 012705 (2014).
Milton, G. W., Briane, M. & Willis, J. R. On cloaking for elasticity and physical equations with a transformation invariant form. New Journal of Physics 8, 248 (2006).
Cummer, S. A. & Schurig, D. One path to acoustic cloaking. New Journal of Physics 9, 45 (2007).
Norris, A. N. Acoustic cloaking theory. Proceedings of the Royal Society of London A: Mathematical, Physical and Engineering Sciences 464, 2411–2434 (2008).
Farhat, M., Guenneau, S. & Enoch, S. Ultrabroadband elastic cloaking in thin plates. Phys. Rev. Lett. 103, 024301 (2009).
Brun, M., Guenneau, S. & Movchan, A. B. Achieving control of in-plane elastic waves. Applied Physics Letters 94, 061903 (2009).
Stenger, N., Wilhelm, M. & Wegener, M. Experiments on elastic cloaking in thin plates. Phys. Rev. Lett. 108, 014301 (2012).
Farhat, M., Enoch, S., Guenneau, S. & Movchan, A. B. Broadband cylindrical acoustic cloak for linear surface waves in a fluid. Phys. Rev. Lett. 101, 134501 (2008).
Zhang, S., Xia, C. & Fang, N. Broadband acoustic cloak for ultrasound waves. Phys. Rev. Lett. 106, 024301 (2011).
Guenneau, S., Amra, C. & Veynante, D. Transformation thermodynamics: cloaking and concentrating heat flux. Opt. Express 20, 8207–8218 (2012).
Schittny, R., Kadic, M., Guenneau, S. & Wegener, M. Experiments on transformation thermodynamics: Molding the flow of heat. Phys. Rev. Lett. 110, 195901 (2013).
Liao, B., Zebarjadi, M., Esfarjani, K. & Chen, G. Cloaking core-shell nanoparticles from conducting electrons in solids. Phys. Rev. Lett. 109, 126806 (2012).
Liao, B., Zebarjadi, M., Esfarjani, K. & Chen, G. Isotropic and energy-selective electron cloaks on graphene. Phys. Rev. B 88, 155432 (2013).
Fleury, R. & Alù, A. Quantum cloaking based on scattering cancellation. Phys. Rev. B 87, 045423 (2013).
Fleury, R. & Alù, A. Manipulation of electron flow using near-zero index semiconductor metamaterials. Phys. Rev. B 90, 035138 (2014).
Oliver, D., Garcia, J. H., Rappoport, T. G., Peres, N. M. R. & Pinheiro, F. A. Cloaking resonant scatterers and tuning electron flow in graphene. Phys. Rev. B 91, 155416 (2015).
Schrödinger, E. Discussion of probability relations between separated systems. Mathematical Proceedings of the Cambridge Philosophical Society 31, 555–563 (1935).
Reid, M. D. Demonstration of the Einstein-Podolsky-Rosen paradox using nondegenerate parametric amplification. Phys. Rev. A 40, 913–923 (1989).
Wiseman, H. M., Jones, S. J. & Doherty, A. C. Steering, entanglement, nonlocality and the Einstein-Podolsky-Rosen paradox. Phys. Rev. Lett. 98, 140402 (2007).
Cavalcanti, E. G., Jones, S. J., Wiseman, H. M. & Reid, M. D. Experimental criteria for steering and the Einstein-Podolsky-Rosen paradox. Phys. Rev. A 80, 032112 (2009).
Leggett, A. J. & Garg, A. Quantum mechanics versus macroscopic realism: Is the flux there when nobody looks? Phys. Rev. Lett. 54, 857–860 (1985).
Emary, C., Lambert, N. & Nori, F. Leggett-garg inequalities. Reports on Progress in Physics 77, 016001 (2014).
Palacios-Laloy, A. et al. Experimental violation of a Bell's inequality in time with weak measurement. Nature Physics 6, 442–447 (2010).
Chen, Y.-N. et al. Temporal steering inequality. Phys. Rev. A 89, 032112 (2014).
Sakurai, J. J . Modern Quantum Mechanics (Revised Edition) (Addison : Wesley, 1993), 1 edn.
Lindblad, G. On the generators of quantum dynamical semigroups. Communications in Mathematical Physics 48, 119–130 (1976).
Gorini, V., Kossakowski, A. & Sudarshan, E. C. G. Completely positive dynamical semigroups of N-level systems. Journal of Mathematical Physics 17, 821 (1976).
Acknowledgements
The authors would like to thank D.-H. Lin for the discussion. This work is supported partially by the National Center for Theoretical Sciences and Ministry of Science and Technology, Taiwan, grant number MOST 103-2112-M-006-017-MY4.
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Y.-N.C. planned the project, with discussion with S.-L.C. and C.-S.C. C.-S.C. and S.-L.C. developed the examples and numerical simulations. S.-L.C. and Y.-N.C. wrote the manuscript. All authors reviewed the manuscript.
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Chen, SL., Chao, CS. & Chen, YN. Detecting the existence of an invisibility cloak using temporal steering. Sci Rep 5, 15571 (2015). https://doi.org/10.1038/srep15571
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DOI: https://doi.org/10.1038/srep15571
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