Abstract
It has been shown how evanescent photons, produced in highly-coherent excited quantum states of liquid water, could be considered in order to perform quantum computations in a completely novel and still unexplored fashion by considering the formation of excited coherent quantum domains in liquid water, associated to cold vortex of quasi-free electrons, and their interaction through the mutual exchange of virtual evanescent photons, by quantum tunnel effect. Furthermore, the use of metamaterials to enclose water molecules, in order to form suitable waveguide for the evanescent photons generated inside water coherent domains, could allow for the implementation of a superfast network of interacting coherent domains able to represent a basic architecture for a novel kind of quantum hyper-computer based on the coherent dynamics of liquid water. This introduces a new frontier in the field of quantum computation, whose applications to both theoretical and advanced-technology fields (from the simulation of complex quantum systems to biotechnology, artificial intelligence, data encryption and decryption, etc.) would be very deep and nowadays unimaginable.
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References
Preparata, G.: QED coherence in matter. World Scientific, Singapore, London, New York (1995)
Caligiuri, L.M., Musha, T.: The Superluminal Universe: from Quantum Vacuum to Brain Mechanism and beyond. NOVA, New York (2016)
Caligiuri, L.M., Musha, T.: Quantum hyper-computing by means of evanescent photons, J. Phys. Conf. Ser. 1251(1), 012010 (2019)
Caligiuri, L.M., Musha, T.: Accelerated quantum computation by means of evanescent photons and its prospects for optical quantum hypercomputers and artificial intelligence. In: Proceedings of the 2019 International Conference on Engineering, Science, and Industrial Applications (ICESI), Tokyo, Japan, 22–24 August 2019. https://doi.org/10.1109/ICESI.2019.8862999
Caligiuri, L.M.: Quantum (Hyper)computation by means of water coherent domains – Part I: the physical level. In: Caligiuri, L.M., (ed.), Frontier in Quantum Computing, NOVA, New York (2020)
Caligiuri, L.M.: Quantum (hyper)computation by means of water coherent domains – Part II: the computational level. In: Caligiuri, L.M., (ed.), Frontier in Quantum Computing, NOVA, New York (2020)
Del Giudice, E., Tedeschi, A.: Water and autocatalysis in living matter. Electromagn. Biol. Med. 28, 46–52 (2009)
Buzzacchi, M., Del Giudice, E., Preparata, G.: Coherence of the glassy state. Int. J. Mod. Phys. B 16(25), 3771–3786 (2001)
Llyod, S.: Ultimate physical limit to computation. Nature 406, 1047–1054 (2000)
Margolus, N., Levitin, L.B.: The maximum speed of dynamical evolution. Physica D 120(1–2), 188–195 (1998)
Del Giudice, E., Spinetti, P.R., Tedeschi, A.: Water dynamics at the root of metamorphosis in living organisms. Water 2, 566–586 (2010)
Caligiuri, L.M.: Super-coherent quantum dynamics of zero-point field and superluminal interaction in matter. In: Amoroso, R.L., Kauffman, L.H., Rowlands, P., Albertini, G. (eds.) Unified Field Mechanics II: Formulation and Empirical Tests, pp. 331–343. World Scientific, Singapore, London, New York (2018)
Caligiuri, L.M., Musha, T.: Superluminal photons tunneling through brain microtubules modelled as metamaterials and quantum computation. In: Tiwari, A., Arul Murugan, N., Ahula, R., (eds.) Advanced Engineering Materials and Modeling, pp. 291–333. Wiley Scrivener Publishing LLC, New Jersey (2016)
Caligiuri, L.M.: The Quantum Phase Operator and its Role in Quantum Computing. In: Caligiuri, L.M., (ed.), Frontier in Quantum Computing, NOVA, New York (2020)
Bono, I., Del Giudice, E., Gamberale, L., Henry, M.: Emergence of the coherent structure of liquid water. Water 4, 510–532 (2012)
Caligiuri, L.M.: A new quantum – relativistic model of tachyon. J. Phys. Conf. Ser. 1251, 012009 (2019)
Nimitz, G.: On virtual phonons, photons and electrons. Found. Phys. 39, 1246–1355 (2009)
Enders, A., Nimitz, G.: 1992 On superluminal barrier traversal, J. Phys. I, France 2, 1693 (1992)
Andrews, D., Bradshaw, D.S.: The role of virtual photons in nanoscale photonics. Ann. Phys. 3–4, 173–186 (2014)
Nielsen, M.A., Chuang, I.L.: Quantum Computation and Quantum Information (10th, Anniversary Cambridge University Press, Cambridge (2016)
Le Bellac, M.: A short Introduction to Quantum Information and Quantum Computation. Cambridge University Press, Cambridge (2006)
Franson, J.D., Jacobs, B.C., Pittman, T.B.: Quantum computing using single photons and the Zeno effect. Phys. Rev. 70, 062302 (2004)
Brizhik, L., Del Giudice, E., Jorgensen, S.E., Marchettini, N., Tiezzi, E.: The role of electromagnetic potentials in the evolutionary dynamics of ecosystems. Ecol. Model. 220, 1856–1869 (2009)
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Caligiuri, L.M. (2022). Accelerated Quantum Computation based on Quantum Coherent Dynamics of Evanescent Photons in Liquid Water. In: Arai, K. (eds) Intelligent Computing. Lecture Notes in Networks and Systems, vol 283. Springer, Cham. https://doi.org/10.1007/978-3-030-80119-9_8
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DOI: https://doi.org/10.1007/978-3-030-80119-9_8
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