Nicolas Gisin

Last updated
Nicolas Gisin
Nicolas Gisin 201508.jpg
Born (1952-05-29) 29 May 1952 (age 71)
Geneva, Switzerland
CitizenshipSwiss
Alma mater University of Geneva
Known for Quantum nonlocality
Long distance quantum communication
Quantum cryptography and teleportation
Work on the foundations of quantum physics
Schrödinger–HJW theorem
Scientific career
Fields Physics, Quantum foundations
Institutions University of Geneva, Constructor University
Doctoral advisor Constantin Piron
Other academic advisors Gérard Emch

Nicolas Gisin (born 1952) is a Swiss physicist and professor at the University of Geneva, working on the foundations of quantum mechanics, quantum information, and communication. His work includes both experimental and theoretical physics. He has contributed work in the fields of experimental quantum cryptography and long-distance quantum communication over standard telecom optical fibers. He also co-founded ID Quantique, a company that provides quantum-based technologies.

Contents

Biography

Nicolas Gisin was born in Geneva on 29 May 1952. He received a degree in mathematics and a master's degree in physics before receiving his Ph.D. in Physics from the University of Geneva in 1981. His dissertation concerned quantum and statistical physics. After several years in the software and optical communication industries, Gisin joined the Group of Applied Physics at the University of Geneva in 1994, where he started working in optics. Since 2000, he has been the Director of the Department of Applied Physics, [1] leading a research group in Quantum information and quantum communication. The European Research Council awarded him with two successive ERC Advanced Grants. [2] [3] In 2009, he received the first biennial John Stewart Bell Prize [4] and, in 2011, he received the prize of the Geneva City. [5] In 2014, Switzerland awarded him the Swiss Science prize sponsored by the Foundation Marcel Benoist [6] and delivered by the National Government.

On 17 July 2014, Gisin published his book, Quantum Chance: Nonlocality, Teleportation, and Other Quantum Marvels, in which he explains modern quantum physics and its applications without using mathematics or difficult concepts. [7] The text has been translated from French into English, German, Chinese, Korean, and Russian.

Gisin played at the highest Swiss level and was president of Servette HC from 2000 to 2015, furthering his club to become the largest in Switzerland. In 2010 Servette HC was awarded the title “Club of the Year” by the European Hockey Federation. [8] [9] In 2014, the team won the Swiss championship for the first time in its century-long history.

Research

Awards

Related Research Articles

<span class="mw-page-title-main">Quantum teleportation</span> Physical phenomenon

Quantum teleportation is a technique for transferring quantum information from a sender at one location to a receiver some distance away. While teleportation is commonly portrayed in science fiction as a means to transfer physical objects from one location to the next, quantum teleportation only transfers quantum information. The sender does not have to know the particular quantum state being transferred. Moreover, the location of the recipient can be unknown, but to complete the quantum teleportation, classical information needs to be sent from sender to receiver. Because classical information needs to be sent, quantum teleportation cannot occur faster than the speed of light.

<span class="mw-page-title-main">Quantum entanglement</span> Correlation between quantum systems

Quantum entanglement is the phenomenon of a group of particles being generated, interacting, or sharing spatial proximity in such a way that the quantum state of each particle of the group cannot be described independently of the state of the others, including when the particles are separated by a large distance. The topic of quantum entanglement is at the heart of the disparity between classical and quantum physics: entanglement is a primary feature of quantum mechanics not present in classical mechanics.

A Bell test, also known as Bell inequality test or Bell experiment, is a real-world physics experiment designed to test the theory of quantum mechanics in relation to Albert Einstein's concept of local realism. Named for John Stewart Bell, the experiments test whether or not the real world satisfies local realism, which requires the presence of some additional local variables to explain the behavior of particles like photons and electrons. As of 2015, all Bell tests have found that the hypothesis of local hidden variables is inconsistent with the way that physical systems behave.

In the interpretation of quantum mechanics, a local hidden-variable theory is a hidden-variable theory that satisfies the principle of locality. These models attempt to account for the probabilistic features of quantum mechanics via the mechanism of underlying, but inaccessible variables, with the additional requirement that distant events be statistically independent.

Quantum networks form an important element of quantum computing and quantum communication systems. Quantum networks facilitate the transmission of information in the form of quantum bits, also called qubits, between physically separated quantum processors. A quantum processor is a machine able to perform quantum circuits on a certain number of qubits. Quantum networks work in a similar way to classical networks. The main difference is that quantum networking, like quantum computing, is better at solving certain problems, such as modeling quantum systems.

<span class="mw-page-title-main">Optical parametric oscillator</span>

An optical parametric oscillator (OPO) is a parametric oscillator that oscillates at optical frequencies. It converts an input laser wave with frequency into two output waves of lower frequency by means of second-order nonlinear optical interaction. The sum of the output waves' frequencies is equal to the input wave frequency: . For historical reasons, the two output waves are called "signal" and "idler", where the output wave with higher frequency is the "signal". A special case is the degenerate OPO, when the output frequency is one-half the pump frequency, , which can result in half-harmonic generation when signal and idler have the same polarization.

In quantum optics, a NOON state or N00N state is a quantum-mechanical many-body entangled state:

Time-bin encoding is a technique used in quantum information science to encode a qubit of information on a photon. Quantum information science makes use of qubits as a basic resource similar to bits in classical computing. Qubits are any two-level quantum mechanical system; there are many different physical implementations of qubits, one of which is time-bin encoding.

Quantum cloning is a process that takes an arbitrary, unknown quantum state and makes an exact copy without altering the original state in any way. Quantum cloning is forbidden by the laws of quantum mechanics as shown by the no cloning theorem, which states that there is no operation for cloning any arbitrary state perfectly. In Dirac notation, the process of quantum cloning is described by:

In theoretical physics, quantum nonlocality refers to the phenomenon by which the measurement statistics of a multipartite quantum system do not allow an interpretation with local realism. Quantum nonlocality has been experimentally verified under a variety of physical assumptions. Any physical theory that aims at superseding or replacing quantum theory should account for such experiments and therefore cannot fulfill local realism; quantum nonlocality is a property of the universe that is independent of our description of nature.

In quantum information and quantum computing, a cluster state is a type of highly entangled state of multiple qubits. Cluster states are generated in lattices of qubits with Ising type interactions. A cluster C is a connected subset of a d-dimensional lattice, and a cluster state is a pure state of the qubits located on C. They are different from other types of entangled states such as GHZ states or W states in that it is more difficult to eliminate quantum entanglement in the case of cluster states. Another way of thinking of cluster states is as a particular instance of graph states, where the underlying graph is a connected subset of a d-dimensional lattice. Cluster states are especially useful in the context of the one-way quantum computer. For a comprehensible introduction to the topic see.

Quantum lithography is a type of photolithography, which exploits non-classical properties of the photons, such as quantum entanglement, in order to achieve superior performance over ordinary classical lithography. Quantum lithography is closely related to the fields of quantum imaging, quantum metrology, and quantum sensing. The effect exploits the quantum mechanical state of light called the NOON state. Quantum lithography was invented at Jonathan P. Dowling's group at JPL, and has been studied by a number of groups.

SARG04 is a 2004 quantum cryptography protocol derived from the first protocol of that kind, BB84.

Quantum cryptography is the science of exploiting quantum mechanical properties to perform cryptographic tasks. The best known example of quantum cryptography is quantum key distribution, which offers an information-theoretically secure solution to the key exchange problem. The advantage of quantum cryptography lies in the fact that it allows the completion of various cryptographic tasks that are proven or conjectured to be impossible using only classical communication. For example, it is impossible to copy data encoded in a quantum state. If one attempts to read the encoded data, the quantum state will be changed due to wave function collapse. This could be used to detect eavesdropping in quantum key distribution (QKD).

<span class="mw-page-title-main">Sandu Popescu</span> British physicist

Sandu Popescu is a Romanian-British physicist working in the foundations of quantum mechanics and quantum information.

The six-state protocol (SSP) is the quantum cryptography protocol that is the version of BB84 that uses a six-state polarization scheme on three orthogonal bases.

Continuous-variable (CV) quantum information is the area of quantum information science that makes use of physical observables, like the strength of an electromagnetic field, whose numerical values belong to continuous intervals. One primary application is quantum computing. In a sense, continuous-variable quantum computation is "analog", while quantum computation using qubits is "digital." In more technical terms, the former makes use of Hilbert spaces that are infinite-dimensional, while the Hilbert spaces for systems comprising collections of qubits are finite-dimensional. One motivation for studying continuous-variable quantum computation is to understand what resources are necessary to make quantum computers more powerful than classical ones.

Quantum foundations is a discipline of science that seeks to understand the most counter-intuitive aspects of quantum theory, reformulate it and even propose new generalizations thereof. Contrary to other physical theories, such as general relativity, the defining axioms of quantum theory are quite ad hoc, with no obvious physical intuition. While they lead to the right experimental predictions, they do not come with a mental picture of the world where they fit.

Barbara Kraus is an Austrian physicist specializing in quantum information, quantum entanglement, and quantum key distribution. She is a University Professor at the TUM School of Natural Sciences at the Technical University of Munich.

Antonio Acín Dal Maschio is a Spanish theoretical physicist, currently an ICREA professor at ICFO – The Institute of Photonic Sciences in Castelldefels, near Barcelona.

References

  1. Leader of the Group of Applied Physics
  2. ERC Quantum Correlations [ permanent dead link ]
  3. ERC Macroscopic Entanglement in Crystals [ permanent dead link ]
  4. "First John Stewart Bell Prize ceremony". Archived from the original on 2017-06-22. Retrieved 2015-09-28.
  5. "Prix de la Ville de Genève". Archived from the original on 2016-03-04. Retrieved 2015-09-28.
  6. Video of the Marcel Benoist Prize Ceremony
  7. Gislim, Nicolas (2014). Quantum Chance: Nonlocality, Teleportation and Other Quantum Marvels. Springer International.
  8. EuroHockey Club Of The Year
  9. Photos of the EuroHockey Club Of the Year
  10. Muller, A.; Bréguet, J.; Gisin, N. (1993). "Experimental demonstration of quantum cryptography using polarized photons in optical-fiber over more than 1 km" . Europhys. Lett. 23 (6): 383. doi:10.1209/0295-5075/23/6/001. S2CID   121806881.
  11. Muller, A.; Zbinden, H.; Gisin, N. (1995). "Underwater quantum coding" (PDF). Nature. 378 (6556): 449. doi:10.1038/378449a0. S2CID   4237561.
  12. Muller, A.; Zbinden, H.; Gisin, N. (1996). "Quantum cryptography over 23 km in installed under-lake telecom fibre" . Europhys. Lett. 33 (5): 335. doi:10.1209/epl/i1996-00343-4. S2CID   250916473.
  13. Stucki, D.; Gisin, N.; Guinnard, O.; Ribordy, G.; Zbinden, H. (2002). "Quantum Key Distribution over 67 km with a plug&play system". New Journal of Physics. 4: 41. arXiv: quant-ph/0203118 . doi:10.1088/1367-2630/4/1/341. S2CID   16704961.
  14. Korzh, B.; et al. (2015). "Provably secure and practical quantum key distribution over 307 km of optical fibre" . Nature Photonics Letter. 9: 163–168. arXiv: 1407.7427 . doi:10.1038/nphoton.2014.327. S2CID   59028718.
  15. Tittel, W.; Brendel, J.; Zbinden, H.; Gisin, N. (1998). "Violation of Bell inequalities by photons more than 10 km apart". Physical Review Letters. 81 (17): 3563–3566. arXiv: quant-ph/9806043 . doi:10.1103/PhysRevLett.81.3563. S2CID   55712217.
  16. Tittel, W.; Brendel, J.; Gisin, N.; Zbinden, H. (1999). "Long-distance Bell-type tests using energy-time entangled photons". Phys. Rev. A. 59 (6): 4150–4163. arXiv: quant-ph/9809025 . doi:10.1103/PhysRevA.59.4150. S2CID   119095575.
  17. Gisin, N.; Zbinden, H. (1999). "Bell inequality and the locality loophole: Active versus passive switches". Phys. Lett. A. 264 (2–3): 103–107. arXiv: quant-ph/9906049 . doi:10.1016/S0375-9601(99)00807-5. S2CID   15383228.
  18. Zbinden, H.; Brendel, J.; Gisin, N.; Tittel, W. (2001). "Experimental test of nonlocal quantum correlation in relativistic configurations" (PDF). Physical Review A. 63 (2): 022111. arXiv: quant-ph/0007009 . doi:10.1103/PhysRevA.63.022111. S2CID   44611890.
  19. Stefanov, A.; Zbinden, H.; Gisin, N.; Suarez, A. (2002). "Quantum correlations with spacelike separated beam splitters in motion: Experimental test of multisimultaneity". Phys. Rev. Lett. 88 (12): 120404. arXiv: quant-ph/0110117 . doi:10.1103/PhysRevLett.88.120404. PMID   11909434. S2CID   119522191.
  20. Salart, D.; Baas, A.; Branciard, C.; Gisin, N; Zbinden, H. (2008). "Testing the speed of 'spooky action at a distance'". Nature. 454 (7206): 861–864. arXiv: 0808.3316 . doi:10.1038/nature07121. PMID   18704081. S2CID   4401216.
  21. Marcikic, I.; de Riedmatten, H.; Tittel, W.; Zbinden, H.; Gisin, N. (2003). "Long-distance teleportation of qubits at telecommunication wavelengths". Nature. 421 (6922): 509–513. arXiv: quant-ph/0301178 . doi:10.1038/nature01376. ISSN   1476-4687. PMID   12556886. S2CID   118877331 . Retrieved 2023-07-26.
  22. Landry, Olivier; Houwelingen, J. A. W. van; Beveratos, Alexios; Zbinden, Hugo; Gisin, Nicolas (2007-02-01). "Quantum teleportation over the Swisscom telecommunication network". JOSA B. 24 (2): 398–403. arXiv: quant-ph/0605010 . doi:10.1364/JOSAB.24.000398. ISSN   1520-8540. S2CID   1377852 . Retrieved 2023-07-26.
  23. Ribordy, Grégoire; Gautier, Jean-Daniel; Zbinden, Hugo; Gisin, Nicolas (1998-04-20). "Performance of InGaAs/InP avalanche photodiodes as gated-mode photon counters". Applied Optics. 37 (12): 2272–2277. arXiv: quant-ph/0605042 . doi:10.1364/AO.37.002272. ISSN   2155-3165. PMID   18273153.
  24. Afzelius, Mikael; Simon, Christoph; de Riedmatten, Hugues; Gisin, Nicolas (2009-05-21). "Multimode quantum memory based on atomic frequency combs". Physical Review A. 79 (5): 052329. arXiv: 0805.4164 . doi:10.1103/PhysRevA.79.052329. S2CID   55205943.
  25. A solid-state light-matter interface at the single-photon level, H. de Riedmatten, M. Afzelius, M. Staudt, Ch. Simon and N. Gisin, Nature, 456, 773-777 (2008).
  26. Quantum storage of photonic entanglement in a crystal, Ch. Clausen, I. Usmani, F. Bussieres, N. Sangouard, M. Afzelius, H. de Riedmatten and N. Gisin, Nature, 469, 508-511 (2011).
  27. Heralded quantum entanglement between two crystals, I. Usmani, Ch. Clausen, F. Bussieres, N. Sangouard, M. Afzelius and N. Gisin, Nature Photonics 6, 234-237 (2012).
  28. Quantum teleportation from a telecom-wavelength photon to a solid-state quantum memory, F. Bussières, Ch. Clausen et al., Nature Photonics 8, 775-778 (2014).
  29. Stochastic quantum dynamics and relativity, N. Gisin, Helvetica Physica Acta 62, 363-371 (1989).
  30. Relevant and irrelevant nonlinear Schrodinger equations, N. Gisin and M. Rigo, Phys. A, 28, 7375- 7390 (1995).
  31. Quantum cloning without signalling, N. Gisin, Phys. Lett. A 242, 1 (1998).
  32. From Bell's theorem to secure quantum key distribution, A. Acin, N. Gisin and L. Masanes, Phys. Rev. Lett. 97, 120405 (2006).
  33. Device-independent security of quantum cryptography against collective attacks, A. Acin, N. Brunner, N. Gisin, S. Massar, S. Pironio and V. Scarani, Phys. Rev. Lett. 98, 230501 (2007).
  34. Device-independent quantum key distribution secure against collective attacks, S. Pironio, A. Acin, N. Brunner, N. Gisin, S. Massar and V. Scarani, New Journal of Physics, 11, 1-25 (2009).
  35. Quantum measurements and stochastic processes, N. Gisin, Phys. Rev. Lett. 52, 1657 (1984).
  36. The Quantum State Diffusion model applied to open systems, N. Gisin and I.C. Percival, J. Phys. A, 25, 5677-5691 (1992).
  37. Polarization mode dispersion of short and long single mode fibers, N. Gisin, J.P. Von Der Weid and J.P. Pellaux, IEEE J. Lightwave Technology, 9, 821-827 (1991).
  38. Polarization mode dispersion: Time domain versus Frequency domain, N. Gisin and J.P. Pellaux, Optics Commun., 89, 316-323 (1992).
  39. Optical Telecom Networks as Weak Quantum Measurements with Post-selection, N. Brunner, A. Acin, D.Collins, N. Gisin et V. Scarani, Physical Review Letters, 91, 180402 (2003).
  40. Renou, Marc-Olivier; Bäumer, Elisa; Boreiri, Sadra; Brunner, Nicolas; Gisin, Nicolas; Beigi, Salman (September 2019). "Genuine Quantum Nonlocality in the Triangle Network". Physical Review Letters. 123 (14). American Physical Society (APS): 140401. doi:10.1103/physrevlett.123.140401. ISSN   1079-7114.
  41. Pusey, Matthew F. (September 30, 2019). "Quantum Correlations Take a New Shape". Physics. 12 (106). York, United Kingdom: American Physical Society.
  42. Renou, Marc-Olivier; Trillo, David; Weilenmann, Mirjam; Le, Thinh P.; Tavakoli, Armin; Gisin, Nicolas; Acín, Antonio; Navascués, Miguel (December 2021). "Quantum theory based on real numbers can be experimentally falsified". Nature. 600 (7890). Springer Science and Business Media LLC: 625–629. doi:10.1038/s41586-021-04160-4. ISSN   1476-4687.
  43. Renou, Marc-Olivier; Acín, Antonio; Navascués, Miguel (1 April 2023). "Quantum Physics Falls Apart without Imaginary Numbers". Scientific American.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.