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J. G. Muga and C. R. Leavens, “Arrival time in quantum mechanics,” Phys. Rep. 338, 353–438 (2000). [Crossref]

J. Damborenea, I. Egusquiza, G. Hegerfeldt, and J. Muga, “Measurement-based approach to quantum arrival times,” Phys. Rev. A 66, 052104 (2002). [Crossref]

M. Penz, G. Grübl, S. Kreidl, and P. Wagner, “A new approach to quantum backflow,” J. Phys. A 39, 423 (2005). [Crossref]

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B. K. Singh, H. Nagar, Y. Roichman, and A. Arie, “Particle manipulation beyond the diffraction limit using structured super-oscillating light beams,” Light: Sci. Appl. 6, e17050 (2017). [Crossref]

G. Yuan, E. T. Rogers, and N. I. Zheludev, ““Plasmonics” in free space: observation of giant wavevectors, vortices, and energy backflow in superoscillatory optical fields,” Light: Sci. Appl. 8, 2 (2019). [Crossref]

Aharonov, Y.

Y. Aharonov, S. Popescu, and J. Tollaksen, “A time symmetric formulation of quantum mechanics,” Phys. Today 63 (11), 27 (2010).

[Crossref] Y. Aharonov, D. Z. Albert, and L. Vaidman, “How the result of a measurement of a component of the spin of a spin-1/2 particle can turn out to be 100,” Phys. Rev. Lett 60, 1351 (1988).

[Crossref] Y. Aharonov, F. Colombo, I. Sabadini, D. Struppa, and J. Tollaksen, The Mathematics of Superoscillations (American Mathematical Society, 2017), Vol. 247.



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[Crossref]

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Y. Aharonov, D. Z. Albert, and L. Vaidman, “How the result of a measurement of a component of the spin of a spin-1/2 particle can turn out to be 100,” Phys. Rev. Lett 60, 1351 (1988).

[Crossref]

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G. Allcock, “The time of arrival in quantum mechanics III. The measurement ensemble,” Ann. Phys. (N. Y.) 53, 311–348 (1969).

[Crossref]

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G. R. Allcock, “The time of arrival in quantum mechanics I. Formal considerations,” Ann. Phys. (N. Y.) 53, 253–285 (1969).

[Crossref] G. R. Allcock, “The time of arrival in quantum mechanics II. The individual measurement,” Ann. Phys. (N. Y.) 53, 286–310 (1969).

[Crossref]

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[Crossref] M. Berry and S. Popescu, “Evolution of quantum superoscillations and optical superresolution without evanescent waves,” J. Phys. A 39, 6965 (2006).

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[Crossref]

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Bracken, A.

A. Bracken and G. Melloy, “Probability backflow and a new dimensionless quantum number,” J. Phys. A 27, 2197 (1994).

[Crossref]

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H. Bostelmann, D. Cadamuro, and G. Lechner, “Quantum backflow and scattering,” Phys. Rev. A 96, 012112 (2017).

[Crossref]

Chen, Y.

F. M. Huang, N. Zheludev, Y. Chen, and F. Javier Garcia de Abajo, “Focusing of light by a nanohole array,” Appl. Phys. Lett. 90, 091119 (2007).

[Crossref] F. M. Huang, Y. Chen, F. J. G. de Abajo, and N. I. Zheludev, “Optical super-resolution through super-oscillations,” J. Opt. A 9, S285 (2007).

[Crossref]

Coffey, V. C.

V. C. Coffey, “Advances in standoff detection make the world safer,” Photon. Spectra 47, 44–47 (2013).



Cohen, E.

B. Tamir and E. Cohen, “Introduction to weak measurements and weak values,” Quanta 2, 7–17 (2013).

[Crossref]

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Y. Aharonov, F. Colombo, I. Sabadini, D. Struppa, and J. Tollaksen, The Mathematics of Superoscillations (American Mathematical Society, 2017), Vol. 247.



Damborenea, J.

J. Damborenea, I. Egusquiza, G. Hegerfeldt, and J. Muga, “Measurement-based approach to quantum arrival times,” Phys. Rev. A 66, 052104 (2002).

[Crossref]

David, A.

de Abajo, F. J. G.

F. M. Huang, Y. Chen, F. J. G. de Abajo, and N. I. Zheludev, “Optical super-resolution through super-oscillations,” J. Opt. A 9, S285 (2007).

[Crossref]

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J. L. Gottfried, F. C. De Lucia, C. A. Munson, and A. W. Miziolek, “Laser-induced breakdown spectroscopy for detection of explosives residues: a review of recent advances, challenges, and future prospects,” Anal. Bioanal. Chem. 395, 283–300 (2009).

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[Crossref]

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J. Damborenea, I. Egusquiza, G. Hegerfeldt, and J. Muga, “Measurement-based approach to quantum arrival times,” Phys. Rev. A 66, 052104 (2002).

[Crossref]

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A. M. Wong and G. V. Eleftheriades, “An optical super-microscope for far-field, real-time imaging beyond the diffraction limit,” Sci. Rep. 3, 1715 (2013).

[Crossref]

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Eveson, S. P.

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Fewster, C. J.

S. P. Eveson, C. J. Fewster, and R. Verch, “Quantum inequalities in quantum mechanics,” in Annales Henri Poincaré (Springer, 2005), Vol. 6, pp. 1–30.



Froim, S.

Y. Eliezer, L. Hareli, L. Lobachinsky, S. Froim, and A. Bahabad, “Breaking the temporal resolution limit by superoscillating optical beats,” Phys. Rev. Lett. 119, 043903 (2017).

[Crossref]

Gjonaj, B.

Gottfried, J. L.

J. L. Gottfried, F. C. De Lucia, C. A. Munson, and A. W. Miziolek, “Laser-induced breakdown spectroscopy for detection of explosives residues: a review of recent advances, challenges, and future prospects,” Anal. Bioanal. Chem. 395, 283–300 (2009).

[Crossref]

Greenfield, E.

Grübl, G.

M. Penz, G. Grübl, S. Kreidl, and P. Wagner, “A new approach to quantum backflow,” J. Phys. A 39, 423 (2005).

[Crossref]

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F. Albarelli, T. Guaita, and M. G. Paris, “Quantum backflow effect and nonclassicality,” Int. J. Quantum Inf. 14, 1650032 (2016).

[Crossref]

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Halliwell, J.

J. Yearsley and J. Halliwell, “An introduction to the quantum backflow effect,” in Journal of Physics: Conference Series (IOP Publishing, 2013), Vol. 442, p. 012055.



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Hegerfeldt, G.

J. Damborenea, I. Egusquiza, G. Hegerfeldt, and J. Muga, “Measurement-based approach to quantum arrival times,” Phys. Rev. A 66, 052104 (2002).

[Crossref]

Huang, F. M.

F. M. Huang, Y. Chen, F. J. G. de Abajo, and N. I. Zheludev, “Optical super-resolution through super-oscillations,” J. Opt. A 9, S285 (2007).

[Crossref] F. M. Huang, N. Zheludev, Y. Chen, and F. Javier Garcia de Abajo, “Focusing of light by a nanohole array,” Appl. Phys. Lett. 90, 091119 (2007).

[Crossref]

Hurwitz, I.

Javier Garcia de Abajo, F.

F. M. Huang, N. Zheludev, Y. Chen, and F. Javier Garcia de Abajo, “Focusing of light by a nanohole array,” Appl. Phys. Lett. 90, 091119 (2007).

[Crossref]

Karimi, E.

Kreidl, S.

M. Penz, G. Grübl, S. Kreidl, and P. Wagner, “A new approach to quantum backflow,” J. Phys. A 39, 423 (2005).

[Crossref]

Leavens, C.

J. Muga, J. Palao, and C. Leavens, “Arrival time distributions and perfect absorption in classical and quantum mechanics,” Phys. Lett. A 253, 21–27 (1999).

[Crossref]

Leavens, C. R.

J. G. Muga and C. R. Leavens, “Arrival time in quantum mechanics,” Phys. Rep. 338, 353–438 (2000).

[Crossref]

Lechner, G.

H. Bostelmann, D. Cadamuro, and G. Lechner, “Quantum backflow and scattering,” Phys. Rev. A 96, 012112 (2017).

[Crossref]

Lobachinsky, L.

Y. Eliezer, L. Hareli, L. Lobachinsky, S. Froim, and A. Bahabad, “Breaking the temporal resolution limit by superoscillating optical beats,” Phys. Rev. Lett. 119, 043903 (2017).

[Crossref]

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R. Remez, Y. Tsur, P.-H. Lu, A. H. Tavabi, R. E. Dunin-Borkowski, and A. Arie, “Superoscillating electron wave functions with subdiffraction spots,” Phys. Rev. A 95, 031802 (2017).

[Crossref]

Makris, K. G.

Melloy, G.

A. Bracken and G. Melloy, “Probability backflow and a new dimensionless quantum number,” J. Phys. A 27, 2197 (1994).

[Crossref]

Miziolek, A. W.

J. L. Gottfried, F. C. De Lucia, C. A. Munson, and A. W. Miziolek, “Laser-induced breakdown spectroscopy for detection of explosives residues: a review of recent advances, challenges, and future prospects,” Anal. Bioanal. Chem. 395, 283–300 (2009).

[Crossref]

Modugno, M.

M. Palmero, E. Torrontegui, J. Muga, and M. Modugno, “Detecting quantum backflow by the density of a Bose-Einstein condensate,” Phys. Rev. A 87, 053618 (2013).

[Crossref]

Muga, J.

M. Palmero, E. Torrontegui, J. Muga, and M. Modugno, “Detecting quantum backflow by the density of a Bose-Einstein condensate,” Phys. Rev. A 87, 053618 (2013).

[Crossref] J. Damborenea, I. Egusquiza, G. Hegerfeldt, and J. Muga, “Measurement-based approach to quantum arrival times,” Phys. Rev. A 66, 052104 (2002).

[Crossref] J. Muga, J. Palao, and C. Leavens, “Arrival time distributions and perfect absorption in classical and quantum mechanics,” Phys. Lett. A 253, 21–27 (1999).

[Crossref]

Muga, J. G.

J. G. Muga and C. R. Leavens, “Arrival time in quantum mechanics,” Phys. Rep. 338, 353–438 (2000).

[Crossref]

Munson, C. A.

J. L. Gottfried, F. C. De Lucia, C. A. Munson, and A. W. Miziolek, “Laser-induced breakdown spectroscopy for detection of explosives residues: a review of recent advances, challenges, and future prospects,” Anal. Bioanal. Chem. 395, 283–300 (2009).

[Crossref]

Nagar, H.

B. K. Singh, H. Nagar, Y. Roichman, and A. Arie, “Particle manipulation beyond the diffraction limit using structured super-oscillating light beams,” Light: Sci. Appl. 6, e17050 (2017).

[Crossref]

Nemirovsky, J.

Palao, J.

J. Muga, J. Palao, and C. Leavens, “Arrival time distributions and perfect absorption in classical and quantum mechanics,” Phys. Lett. A 253, 21–27 (1999).

[Crossref]

Palmero, M.

M. Palmero, E. Torrontegui, J. Muga, and M. Modugno, “Detecting quantum backflow by the density of a Bose-Einstein condensate,” Phys. Rev. A 87, 053618 (2013).

[Crossref]

Paris, M. G.

F. Albarelli, T. Guaita, and M. G. Paris, “Quantum backflow effect and nonclassicality,” Int. J. Quantum Inf. 14, 1650032 (2016).

[Crossref]

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M. Penz, G. Grübl, S. Kreidl, and P. Wagner, “A new approach to quantum backflow,” J. Phys. A 39, 423 (2005).

[Crossref]

Pollak, H. O.

D. Slepian and H. O. Pollak, “Prolate spheroidal wave functions, Fourier analysis and uncertainty—I,” Bell Syst. Tech. J. 40, 43–63 (1961).

[Crossref]

Popescu, S.

Y. Aharonov, S. Popescu, and J. Tollaksen, “A time symmetric formulation of quantum mechanics,” Phys. Today 63 (11), 27 (2010).

[Crossref] M. Berry and S. Popescu, “Evolution of quantum superoscillations and optical superresolution without evanescent waves,” J. Phys. A 39, 6965 (2006).

[Crossref]

Remez, R.

Rogers, E. T.

G. Yuan, E. T. Rogers, and N. I. Zheludev, ““Plasmonics” in free space: observation of giant wavevectors, vortices, and energy backflow in superoscillatory optical fields,” Light: Sci. Appl. 8, 2 (2019).

[Crossref] E. T. Rogers and N. I. Zheludev, “Optical super-oscillations: sub-wavelength light focusing and super-resolution imaging,” J. Opt. 15, 094008 (2013).

[Crossref]

Roichman, Y.

B. K. Singh, H. Nagar, Y. Roichman, and A. Arie, “Particle manipulation beyond the diffraction limit using structured super-oscillating light beams,” Light: Sci. Appl. 6, e17050 (2017).

[Crossref]

Sabadini, I.

Y. Aharonov, F. Colombo, I. Sabadini, D. Struppa, and J. Tollaksen, The Mathematics of Superoscillations (American Mathematical Society, 2017), Vol. 247.



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[Crossref]

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Segev, M.

Shukla, P.

M. Berry and P. Shukla, “Pointer supershifts and superoscillations in weak measurements,” J. Phys. A 45, 015301 (2011).

[Crossref]

Singh, B. K.

Slepian, D.

D. Slepian and H. O. Pollak, “Prolate spheroidal wave functions, Fourier analysis and uncertainty—I,” Bell Syst. Tech. J. 40, 43–63 (1961).

[Crossref]

Struppa, D.

Y. Aharonov, F. Colombo, I. Sabadini, D. Struppa, and J. Tollaksen, The Mathematics of Superoscillations (American Mathematical Society, 2017), Vol. 247.



Tamir, B.

B. Tamir and E. Cohen, “Introduction to weak measurements and weak values,” Quanta 2, 7–17 (2013).

[Crossref]

Tavabi, A. H.

R. Remez, Y. Tsur, P.-H. Lu, A. H. Tavabi, R. E. Dunin-Borkowski, and A. Arie, “Superoscillating electron wave functions with subdiffraction spots,” Phys. Rev. A 95, 031802 (2017).

[Crossref]

Tollaksen, J.

Y. Aharonov, S. Popescu, and J. Tollaksen, “A time symmetric formulation of quantum mechanics,” Phys. Today 63 (11), 27 (2010).

[Crossref] J. Tollaksen, “Novel relationships between superoscillations, weak values, and modular variables,” J. Phys. Conf. Ser. 70, 012016 (2007).

[Crossref] Y. Aharonov, F. Colombo, I. Sabadini, D. Struppa, and J. Tollaksen, The Mathematics of Superoscillations (American Mathematical Society, 2017), Vol. 247.



Torrontegui, E.

M. Palmero, E. Torrontegui, J. Muga, and M. Modugno, “Detecting quantum backflow by the density of a Bose-Einstein condensate,” Phys. Rev. A 87, 053618 (2013).

[Crossref]

Tsur, Y.

R. Remez, Y. Tsur, P.-H. Lu, A. H. Tavabi, R. E. Dunin-Borkowski, and A. Arie, “Superoscillating electron wave functions with subdiffraction spots,” Phys. Rev. A 95, 031802 (2017).

[Crossref]

Vaidman, L.

Y. Aharonov, D. Z. Albert, and L. Vaidman, “How the result of a measurement of a component of the spin of a spin-1/2 particle can turn out to be 100,” Phys. Rev. Lett 60, 1351 (1988).

[Crossref]

Verch, R.

S. P. Eveson, C. J. Fewster, and R. Verch, “Quantum inequalities in quantum mechanics,” in Annales Henri Poincaré (Springer, 2005), Vol. 6, pp. 1–30.



Wagner, P.

M. Penz, G. Grübl, S. Kreidl, and P. Wagner, “A new approach to quantum backflow,” J. Phys. A 39, 423 (2005).

[Crossref]

Wong, A. M.

A. M. Wong and G. V. Eleftheriades, “An optical super-microscope for far-field, real-time imaging beyond the diffraction limit,” Sci. Rep. 3, 1715 (2013).

[Crossref]

Yearsley, J.

J. Yearsley and J. Halliwell, “An introduction to the quantum backflow effect,” in Journal of Physics: Conference Series (IOP Publishing, 2013), Vol. 442, p. 012055.



Yuan, G.

G. Yuan, E. T. Rogers, and N. I. Zheludev, ““Plasmonics” in free space: observation of giant wavevectors, vortices, and energy backflow in superoscillatory optical fields,” Light: Sci. Appl. 8, 2 (2019).

[Crossref]

Zacharias, T.

Zheludev, N.

F. M. Huang, N. Zheludev, Y. Chen, and F. Javier Garcia de Abajo, “Focusing of light by a nanohole array,” Appl. Phys. Lett. 90, 091119 (2007).

[Crossref]

Zheludev, N. I.