Experimental Approach Towards Long-Range Interactions from 1.6 to 13798 km Distances in Bio-Hybrid Systems

Kernbach, Serge; Zamsha, Vitaliy; Kravchenko, Yurii

doi:10.14704/nq.2016.14.3.917

Cited by 4 publications

(4 citation statements)

References 18 publications

(18 reference statements)

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“…Assessing ME as a correlation of electromagnetic signals induced by biological systems stimulated further development of these methods for achieving ME. For instance, (Montagnier et al, 2011) reports about using DNA with magnetic fields and recorded EM signals, similar experiments are conducted by (Surinov, 2018) with mouses, (Smirnov, 2010) describes excitation by microwave radiation at 1.9mm with images of rats, (Krasnobrygev, 2009) excites spatially distributed materials by alternating magnetic field and analyzes their interactions with biological objects, (Maslobrod et al, 2014a) uses digital images and optical excitation for long-range biological ME with seeds, fungi and plant seedlings at 2000km distance, (Hachumova et al, 2014) utilizes low-frequency EM fields with acoustic and video signals, experiments in (Kernbach et al, 2016) are conducted by optical/electric field excitation with digital images and video signals. The list of such experiments and publications can be extended further.…”

Section: Physical and Biological Macroscopic Entanglementmentioning

confidence: 99%

“…The method consists in creating an entangled system with remote object and aqueous solution in measurement containers. Over 1000 performed experiments, in particular with LEDs excitation at 470nm, demonstrated the non-local signal (impact) transmission between such macro-systems (Akimov et al, 2001), (Kernbach, 2013a), (Kernbach et al, 2016). These experiments allow expressing the hypothesis that a remote object affects the EIS dynamics of aqueous solution in presence of optical excitation.…”

Section: Introductionmentioning

confidence: 99%

“…Multiple works (Akimov et al, 2001), (Maslobrod et al, 2014a), (Kernbach et al, 2016), (Smirnov, 2010) are devoted to the effect of non-local signal transmission. This effect is related to macroscopic entanglement (ME) (Palomaki et al, 2013), (Sperling and Walmsley, 2017), (Ockeloen-Korppi et al, 2018), (Vedral, 2008) and can be considered from several points of view: 1) as the ability to transmit signals between remote macro-systems; 2) to impose a nonlocal impact on a certain object; 3) to monitor remote objects.…”

Section: Introductionmentioning

confidence: 99%

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Distant monitoring of entangled macro-objects

Kernbach¹

2019

Neuroquantology

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The paper discusses application of long-range signal transmission system for distant monitoring of entangled macro-objects. The approach is based on electrochemical impedance spectroscopy with optical excitation within the framework of weak macroscopic entanglement. The 'activity index' is introduced as a characteristic of distant objects and its meaning is analysed for different experimental and environmental conditions. Probabilistic parameters of nonlocal measurements, methods for increasing their reproducibility and reliability, as well as various configurations of the measuring system are described. The results of calibration and control experiments with geographic, physical, biological and symbolic objects are represented. The system enables testing entangled macro-objects on possessing specific features/properties measured by multiple devices in parallel. Distant monitoring can be used as part of a system conducting interactions with biological objects, as well as for independent usage as diagnostic or surveillance equipment.

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Section: Physical and Biological Macroscopic Entanglementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Distant monitoring of entangled macro-objects

Kernbach¹

2019

Neuroquantology

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“…In many of these experiments, the absolute magnitude of the reported effects was small, requiring many repeated samples to detect the hypothesized psychophysical phenomena. In an attempt to improve experimental yields, the use of increasingly sensitive targets has been explored, including the direction of an electron's magnetic moment (i.e., its spin), ion transport in water, or the behavior of photons in optical interferometers (Bryan, R. A., 2006;Guerrer, 2019;Kernbach, Zamsha, & Kravchenko, 2016;Radin et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Psychophysical interactions with photon polarization: Two exploratory studies

Radin¹,

L²

2019

Preprint

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The present study explored possible psychophysical interactions between focused mental intention and the electromagnetic field vector, i.e., polarization. To detect the hypothesized effect, a laser beam was passed through horizontal and vertical polarizers. Participants were asked to focus their attention on the beam between the two polarizers while holding the intention for the beam’s polarization to rotate. If the photons’ electric field vector was affected, then the illumination intensity of the beam exiting the second polarizer should increase. Two exploratory experiments both showed results contrary to the hypothesis, with illumination decreasing during periods when intention was focused toward the beam as compared to periods where attention was withdrawn. Reanalysis of data from previously published experiments, also involving mental influence of beams of light, but designed for different purposes and originally analyzed in other ways, also showed a reduction in light intensity during periods of focused attention. These studies suggest that psychophysical interactions with light appears to result in scattering or absorbing photons. Further research is warranted to confirm these results.

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