Schumann Resonance and Sunspot Relations to Human Health Effects in Thailand
There is sensible scientific evidence to establish a trailof connection from the sun activity to human biological and health effects. This explains whysunspot numbers and indices of Geomagnetic Activity are correlated with serious human healtheffects in a large body of published studies. The key element is the role of the SchumannResonance signal that is detected by human brains and is used to synchronize diurnal andELF brain rhythms. The Schumann Resonance signal intensity is modulated and highlycorrelated with solar activity and the electron concentrations in the lowest layersof the ionosphere. The enhanced or weakened solar activity moves the level of the SRsignal outside the normal homeostatic range and, through the Melatonin mechanism, causeshealth problems and enhanced death rates in large human populations. A five-yearmonthly data-base is used to confirm the correlation between the climatic factors ofSunspot Number, Southern Oscillation Index and Global mean temperatureanomalies with the SR signal strength. The Sunspot Number emerges as the strongestfactor. A 19 year data-set of annual mortality rates in SE Asia is used to seek evidenceof correlations between human mortality rates and the sunspot number in order to supportand confirm the SR hypothesis. A wide range of mortalities that are associatedwith Melatonin reduction, are found to be significantly correlated with sunspot number,including cancer, cardiac and neurological mortality.
KeywordsMelatonin Solar Activity Signal Strength Sunspot Number Geomagnetic Activity
Unable to display preview. Download preview PDF.
- Balling, R. C., Jr. and Hilderbrandt, M.: 2000, Evaluation of the linkage between Schumann Resonance peak frequency values and global and regional temperatures, Climate Res. 16, 31–36.Google Scholar
- Bardasano, J. L., Cos, S., and Picazo, M. L.: 1989, Numerical variation in synaptic ribbons of rat pinealocytes under magnetic storm conditions and on calm days [in German], J. Hirnforsch. 30(60), 639–643.Google Scholar
- Burch, J. B., Reif, J. S., and Yost, M. G.: 1999b, Geomagnetic disturbances are associated with reduced nocturnal excretion of melatonin metabolite in humans, Neurosci. Lett. 266(3), 209–212.Google Scholar
- Cherry, N.J.: 2002, Schumann Resonances, a plausible biophysical mechanism for the human health effects of solar/geomagnetic activity, Natural Hazards 26, 279–331.Google Scholar
- Rapoport, S. I., Malinovskaia, N. K., Oraevskii, V. N., Komarov, F. I., Nosovskii, A. M., and Vetterberg, L.: 1997, Effects of disturbances of natural magnetic field of the Earth on melatonin production in patients with coronary heart disease, Klin. Med. (Mosk) 75(6), 24–26.Google Scholar
- Rapoport, S. I., Blodypakova, T. D., Malinovskaia, N. K., Oraevskii, V. N., Meshcheriakova, S. A., Breus, T. K., and Sosnovskii, A. M.: 1998, Magnetic storms as a stress factor, Biofizika 43(4), 632–639.Google Scholar
- Rapoport, S. I., Shalalova, A. M., Oraevskii, V. N., Malinovskaia, N. K., and Vetterberg, L.: 2001, Melatonin production in hypertonic patients during magnetic storms, Ter. Arkh. 73(12): 29–33.Google Scholar
- SEAMIC: 1997, Recent trends in health statistics in Southeast Asia 1974–1993, Publication No. 77, Southeast Asian Medical Information Center, Tokyo.Google Scholar
- Weydahl, A.., Sothern, R. B., Cornelissen, G., and Wetterberg, L.: 2001, Geomagnetic activity influences the Melatonin secretion at latitude 70 degrees N, Biomed. Parmacother. 55(Suppl. 1), 57s–62s.Google Scholar