Environment-dependent fluctuations of potentiometric pH dynamics in geomagnetic field

References

• Anosov, V., and E. Truchan. 2003. New approach to impact of weak magnetic fields on living objects (rus), Doklady Akedemii Nauk: Biochemistry. Biophysics and Molecular Biology 392(5): 689–693.
   Google Scholar
• Baureacute Koch, C. L. M., M. Sommarin, B. R. R. Persson, L. G. Salford, and J. L. Eberhardt. 2003. Interaction between weak low frequency magnetic fields and cell membranes. Bioelectromagnetics 24:395–402. doi:10.1002/bem.10136.
   PubMed Web of Science ®Google Scholar
• Beckman Instruments. 1982. The Beckman Handbook of Applied Electrochemistry, (Irvine, Calif. : Beckman Instruments ; San Francisco, Calif. : Dist. by VWR Scientific).
   Google Scholar
• Cao, J., R. Cogdell, D. Coker, H.-G. Duan, J. Hauer, U. Kleinekathöfer, T. Jansen, T. Mančal, R. J. D. Miller, J. Ogilvie, et al. 2020. Quantum biology revisited. Science Advances 6:eaaz4888. doi:10.1126/sciadv.aaz4888.
   PubMed Web of Science ®Google Scholar
• Chen, Y., Z. Cai, Q. Feng, P. Gao, Y. Yang, X. Bai, B. Q. Tang, and T. Zang. 2019a. Evaluation of the extremely low-frequency electromagnetic field (ELF-EMF) on the growth of bacteria Escherichia coli. Cogent Biology 5:1625104. doi:10.1080/23312025.2019.1625104.
   Web of Science ®Google Scholar
• Chen, Y., Z. Cai, P. Gao, Q. Feng, X. Bai, and B. Tang. 2019b. Electronic transmission of nonlocal suppressive effect of Chinese herbal medicine to escherichia coli, Biology. Engineering and Medicine 4. doi:10.15761/BEM.1000163.
   Google Scholar
• DeMeo, J. 2012. Water as a resonant medium for unusual external environmental factors. Water Journal 3:1–47. doi:10.14294/WATER.2011.3.
   Google Scholar
• Halloy, J., F. Mondada, S. Kernbach, and T. Schmickl. 2013. Towards bio-hybrid systems made of social animals and robots. In Biomimetic and biohybrid systems, ed. N. F. Lepora, A. Mura, H. G. Krapp, P. F. M. J. Verschure, and T. J. Prescott, 384–86. Berlin, Heidelberg: Springer Berlin Heidelberg. doi:10.1007/978-3-642-39802-5_42.
   Google Scholar
• Hamann, H., S. Bogdan, A. Diaz-Espejo, L. Garcia Carmona, V. Hernandez-Santana, S. Kernbach, A. Kernbach, A. Quijano-Lopez, B. Salamat, and M. Wahby, Watchplant: Networked bio-hybrid systems for pollution monitoring of urban areas, ALIFE 2021: The 2021 Conference on Artificial Life, Prague, Czech Republic, 2021. doi:10.1162/isal_a_00377.
   Google Scholar
• Hamann, H., M. Soorati, M. Heinrich, D. Hofstadler, I. Kuksin, F. Veenstra, M. Wahby, S. Nielsen, S. Risi, T. Skrzypczak, et al., Flora robotica – An architectural system combining living natural plants and distributed robots, Proceedings of ECAL 2017: the 14th European Conference on Artificial Life, Lyon, France (2017) 16 doi:10.48550/arXiv.1709.04291.
   Google Scholar
• Hartinger, M. D., M. B. Moldwin, K. Takahashi, J. W. Bonnell, and V. Angelopoulos. 2013. Survey of the ULF wave Poynting vector near the Earth’s magnetic equatorial plane. Journal of Geophysical Research (Space Physics) 118:6212–27. doi:10.1002/jgra.50591.
   Web of Science ®Google Scholar
• Henderson, R. 2021. Biological geomagnetic field sensing. Preview 2021:34–36. doi:10.1080/14432471.2021.1880118.
   Google Scholar
• Hunter, L., J. Gordon, S. Peck, D. Ang, and J. F. Lin. 2013. Using the Earth as a polarized electron source to search for long-range spin-spin interactions. Science 339:928–32. doi:10.1126/science.1227460.
   PubMed Web of Science ®Google Scholar
• Jerman, I., R. Rusic, R. Krasovec, M. Skarja, and L. Mogilnicki. 2005. Electrical transfer of molecule information into water, its storage, and bioeffects on plants and bacteria. Electromagnetic Biology and Medicine 24:341–53. doi:10.1080/15368370500381620.
   Web of Science ®Google Scholar
• Kaznacheev, V., and L. Michailova. 1981. Ultraweak emissions in intercellular interactions (rus). Novosibirsk: Hauka.
   Google Scholar
• Kernbach, S. 2013. Replication attempt: Measuring water conductivity with polarized electrodes. Journal of Scientific Exploration 27:69–105.
   Google Scholar
• Kernbach, S. 2018. Biophysical effects of the circular poynting vector emitter. IJUS 19-20:78–97. doi:10.17613/sp8t-gz69.
   Google Scholar
• Kernbach, S. 2022. Electrochemical characterisation of ionic dynamics resulting from spin conversion of water isomers. Journal of the Electrochemical Society 169:067504. doi:10.1149/1945-7111/ac6f8a.
   Web of Science ®Google Scholar
• Kernbach, S., and O. Kernbach. 2014. On precise pH and dpH measurements (rus). IJUS 5:83–103.
   Google Scholar
• Kernbach, S., O. Kernbach, I. Kuksin, A. Kernbach, Y. Nepomnyashchiy, T. Dochow, and A. Bobrov. 2022. The biosensor based on electrochemical dynamics of fermentation in yeast Saccharomyces Cerevisiae. Environmental Research 213:113535. doi:10.1016/j.envres.2022.113535.
   PubMed Web of Science ®Google Scholar
• Kernbach, S., I. Kuksin, and O. Kernbach. 2017. On accurate differential measurements with electrochemical impedance spectroscopy. WATER 8:136–55. doi:10.14294/WATER.2016.8.
   Google Scholar
• Kim, Y., F. Bertagna, E. D’Souza, D. Heyes, L. Johannissen, E. Nery, A. Pantelias, A. Sanchez-Pedreco J, L. Slocombe, M. Spencer, et al. 2021. Quantum biology: An update and perspective. Quantum Reports 3:80–126. doi:10.3390/quantum3010006.
   Google Scholar
• Kobayashi, M., D. Kikuchi, and H. Okamura. 2009. Imaging of ultraweak spontaneous photon emission from human body displaying diurnal rhythm. PLoS ONE 4:e6256. doi:10.1371/journal.pone.0006256.
   PubMed Web of Science ®Google Scholar
• Korenbaum, V., T. Chernysheva, V. Galay, R. Galay, A. Ustinov, S. Zakharkov, and N. Bunkin. 2021. Possible effect of human-experimenter on homeopathic-like aqueous preparations. Water 13:1475. doi:10.3390/w13111475.
   Web of Science ®Google Scholar
• Lee, K. S., Y. P. Tan, L. H. Nguyen, R. P. Budoyo, K. H. Park, C. Hufnagel, Y. S. Yap, N. Mobjerg, V. Vedral, T. Paterek, et al. 2021. Entanglement between superconducting qubits and a tardigrade. arXiv 2112 07978:arXiv:2112.07978. doi:10.48550/ARXIV.2112.07978.
   Google Scholar
• Lin, L., W. Jiang, X. Xu, and P. Xu. 2020. A critical review of the application of electromagnetic fields for scaling control in water systems: Mechanisms, characterization, and operation. Npj Clean Water 3. doi:10.1038/s41545-020-0071-9.
   Web of Science ®Google Scholar
• Marletto, C., D. M. Coles, T. Farrow, and V. Vedral. 2018. Entanglement between living bacteria and quantized light witnessed by rabi splitting. Journal of Physics Communications 2:101001. doi:10.1088/2399-6528/aae224.
   Web of Science ®Google Scholar
• Meier, P. , Lohrum, A. , Gareiss, J. 1989. Practice and Theory of pH Measurement. Urdorf, Switzerland: Ingold Messtechnik.
   Google Scholar
• Montagnier, L., J. Aissa, E. D. Giudice, C. Lavallee, A. Tedeschi, and G. Vitiello. 2011. DNA waves and water. Journal of Physics: Conference Series 306:012007. doi:10.1088/1742-6596/306/1/012007.
   Google Scholar
• Pilla, A. A., and M. S. Markov. 1994. Bioeffects of weak electromagnetic fields. Rev Environ Health 10:155–69. doi:10.1515/reveh.1994.10.3-4.155.
   PubMedGoogle Scholar
• Qing, L., T. Miao, G. Peng, T. Jie, W. Bing, T. B. Qing, and W. Hong. 2021. The effect of high-penetrating emission on the growth, superoxide accumulation and atp/adp ratio in saccharomyces cerevisiae. Int. J. of Applied Electromagnetics and Mechanics 67:453–60. doi:10.3233/JAE-210054.
   Web of Science ®Google Scholar
• Rampl, I., V. Boudný, M. Cíž, A. Lojek, and P. Hyršl. 2009. Pulse vector magnetic potential and its influence on live cells, in: Proceedings of the 2009 International Conference on eHealth, Telemedicine, and Social Medicine, ETELEMED ’09, 99–107. Washington, DC, USA: IEEE Computer Society. doi:10.1109/eTELEMED.2009.47.
   Google Scholar
• Redouane, M., E. Abderrahmane, M. Salah, M. Monkade, E. B. Abdeslam, and A. Ghidan. 2020. Effect of electromagnetic fields on the pH of water under kinetic conditions. Fresenius Environmental Bulletin 29:7922–33.
   Web of Science ®Google Scholar
• Scholkmann, F. 2016. Long range physical cell-to-cell signalling via mitochondria inside membrane nanotubes: A hypothesis. Theor Biol Med Model 13:16. doi:10.1186/s12976-016-0042-5.
   PubMed Web of Science ®Google Scholar
• Tang, B., T. Li, X. Bai, M. Zhao, B. Wang, G. Rein, Y. Yang, P. Gao, X. Zhang, Y. Zhao, et al. 2018. Rate limiting factors for dna transduction induced by weak electromagnetic field. Electromagnetic Biology and Medicine 38:1–11. doi:10.1080/15368378.2018.1558064.
   Web of Science ®Google Scholar
• Vanhamäki, H., A. Viljanen, R. Pirjola, and O. Amm. 2013. Deriving the geomagnetically induced electric field at the Earth’s surface from the time derivative of the vertical magnetic field. Earth, Planets and Space 65:997–1006. doi:10.5047/eps.2013.03.013.
   Web of Science ®Google Scholar
• Vedral, V. 2010. Decoding Reality: The Universe as Quantum Information. Oxford: Oxford University Press.
   Google Scholar
• Voeikov, V. 2006. Fundamental role of water in bioenergetics. In Biophotonics and coherent systems, ed. L. V. Biology, V. L. V. Beloussov, and V. S. Martynyuk, 89–104. Boston, MA.: Springer. doi:10.1007/978-0-387-28417-0_7.
   Google Scholar
• Wang, Y., H. Wei, and Z. Li. 2018. Effect of magnetic field on the physical properties of water. Results in Physics 8:262–67. doi:10.1016/j.rinp.2017.12.022.
   Web of Science ®Google Scholar
• Zbinden, H., J. Brendel, N. Gisin, and W. Tittel. 2001. Experimental test of nonlocal quantum correlation in relativistic configurations. Phys. Rev. A 63:022111. doi:10.1103/PhysRevA.63.022111.
   Web of Science ®Google Scholar
• Zhang, J., S. Li, and W. Le. 2021. Advances of terahertz technology in neuroscience: Current status and a future perspective. iScience 24:103548. doi:10.1016/j.isci.2021.103548.
   PubMed Web of Science ®Google Scholar