Possibility of high performance quantum computation by superluminal evanescent photons in living systems

Musha, Takaaki

doi:10.1016/j.biosystems.2009.03.002

Cited by 11 publications

(4 citation statements)

References 22 publications

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“…We believe that quantum theory is able to explain some of the above mysteries. As an example, recently it has been shown theoretically that the biological brain has the possibility to achieve large quantum bit computing at room temperature, superior when compared with the conventional processors [60].…”

Section: Discussionmentioning

confidence: 99%

Emission of Mitochondrial Biophotons and Their Effect on Electrical Activity of Membrane via Microtubules

Rahnama¹,

Tuszyński²,

Bókkon³

et al. 2011

J. Integr. Neurosci.

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In this paper we argue that, in addition to electrical and chemical signals propagating in the neurons of the brain, signal propagation takes place in the form of biophoton production. This statement is supported by recent experimental confirmation of photon guiding properties of a single neuron. We have investigated the interaction of mitochondrial biophotons with microtubules from a quantum mechanical point of view. Our theoretical analysis indicates that the interaction of biophotons and microtubules causes transitions/fluctuations of microtubules between coherent and incoherent states. A significant relationship between the fluctuation function of microtubules and alpha-EEG diagrams is elaborated on in this paper. We argue that the role of biophotons in the brain merits special attention.

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Section: Discussionmentioning

confidence: 99%

Emission of Mitochondrial Biophotons and Their Effect on Electrical Activity of Membrane via Microtubules

Rahnama¹,

Tuszyński²,

Bókkon³

et al. 2011

J. Integr. Neurosci.

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“…Hence, it can be seen that tunneling photons traveling in an evanescent mode can move at a superluminal speed. From the assumption that the evanescent photon is a superluminal particle, the author has shown that a microtubule in the biological brain can achieve quantum bit (qubit) computations on large data sets, which would account for the high performance computation as compared with conventional processors [19].…”

Section: Evanescent Superluminal Photons In the Microtubulementioning

confidence: 99%

Holographic View of the Brain Memory Mechanism Based on Evanescent Superluminal Photons

Musha¹

2012

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D. Pollen and M. Trachtenberg proposed the holographic brain theory to help explain the existence of photographic memories in some people. They suggested that such individuals had more vivid memories because they somehow could access a very large region of their memory holograms. Hameroff suggested in his paper that cylindrical neuronal microtubule cavities, or centrioles, function as waveguides for the evanescent photons for quantum signal processing. The supposition is that microtubular structures of the brain function as a coherent fiber bundle set used to store holographic images, as would a fiber-optic holographic system. In this paper, the author proposes that superluminal photons propagating inside the microtubules via evanescent waves could provide the access needed to record or retrieve a quantum coherent entangled holographic memory

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“…According to his paper, it is reasonably unlikely that the brain functions as a quantum computer at room temperature. Contrary to the Tegmark's calculation, Musha [7] has shown that the microtubule in a biological brain can perform computation satisfying the time scale required for quantum computation to achieve large quantum bits computation compared with the conventional silicon processors even at the room temperature from the assumption that the evanescent photon is a superluminal particle called tachyon.…”

Section: Introductionmentioning

confidence: 97%

“…The decoherence time for the quantum computation utilizing superluminal particle, Musha has shown the formula in his paper shown as [7]  …”

mentioning

confidence: 99%

Possibility to Realize the Brain-Computer Interface from the Quantum Brain Model Based on Superluminal Particles

Musha¹,

Sugiyama²

2011

JQIS

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R. Penrose and S. Hameroff have proposed an idea that the brain can attain high efficient quantum computation by functioning of microtubular structure of neurons in the cytoskelton of biological cells, including neurons of the brain. But Tegmark estimated the duration of coherence of a quantum state in a warm wet brain to be on the order of 10<sup>>–13 </supseconds, which is far smaller than the one tenth of a second associated with consciousness. Contrary to his calculation, it can be shown that the microtubule in a biological brain can perform computation satisfying the time scale required for quantum computation to achieve large quantum bits calculation compared with the conventional silicon processors even at the room temperature from the assumption that tunneling photons are superluminal particles called tachyons. According to the non-local property of tachyons, it is considered that the tachyon field created inside the brain has the capability to exert an influence around the space outside the brain and it functions as a macroscopic quantum dynamical system to meditate the long-range physical correlations with the surrounding world. From standpoint of the brain model based on superluminal tunneling photons, the authors theoretically searched for the possibility to realize the brain-computer interface that allows paralyzed patient to operate computers by their thoughts and they obtained the positive result for its realization from the experiments conducted by using the prototype of a brain-computer interface system

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Possibility of high performance quantum computation by superluminal evanescent photons in living systems

Cited by 11 publications

References 22 publications

Emission of Mitochondrial Biophotons and Their Effect on Electrical Activity of Membrane via Microtubules

Emission of Mitochondrial Biophotons and Their Effect on Electrical Activity of Membrane via Microtubules

Holographic View of the Brain Memory Mechanism Based on Evanescent Superluminal Photons

Possibility to Realize the Brain-Computer Interface from the Quantum Brain Model Based on Superluminal Particles

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