MAGNOTRON TECHNOLOGY based most on Non-bipolar magnetic fields tuning.
• The MAGNOTRON Engine (1) creates a specific electromagnetic field (Modulated EMF (2)) that modulated from a sensor (3). The created EMF (2) modulated by the electron-vibration activity (energizes the specific material structure) using for this a specific sensor (3).
• This primary magnetic field interferes with other environmental present EMF’s (4) and creates the necessary conditions for interaction, which appears between the MAGNOTRON SENSOR and the specific material structure (5).
• The EMF (2) tuned to the specific material structure (5).
Non-bipolar magnetic field (Concerns non-bipolar magnetic field flow (Lonetree 2013) )
Engineer Lonetree describes the non-bipolar field phenomenon "As the outer core rotates, a magnetic north and south pole is created. During this process, another form of magnetism is produced, in Bipolar nature. This magnetism that has no north or south. It's just pure magnetic energy. Most of this free energy is absorbed by the primary bipolar (North/South) sector, but a portion of it can reach and penetrate the surface of our planet. Inside the earth, non-bipolar magnetism takes the form of a "swirl-like" (spiral or circular) shape, showing up and down movement." (Lonetree, Miller,2013)
Figures below shown (1->2 , 3->4, 5->6 …) the way that magnetic tune phenomenon is realized in ‘SAED’ engines.
Under the effect of static magnetic field, the cores (as Hydrogen does) are limited by the quantum mechanics to turned in one of the two directions, that of magnetic field (fundamental situation) or opposite to this (whipped up situation). The cores that are found in fundamental situation is at a small percentage (1,4 cores in total 1.000.000 cores) more from those that are found in whipped up situation. Because this small surEWS of cores in fundamental situation, there is a total magnetization of small size in the direction of magnetic field and from this emanates finally the signal from the explosive structure.
This total magnetization (M) in the direction of the magnetic field is the resultant of vectors of the magnetic propensity cores that are found in precession movement round the axis of static magnetic field (Ho) and with some phase difference , the one of the other. (FIGURE 2). In order to apply effectively an additional force on a object that it executes precession movement, this force should be nutationed by the object’s precession frequency (tune or resonance).
More for this tech publish at :
https://www.academia.edu/35409148/MAGNOTRON _MTR_tech_in_material_detection.pdf
‘3 LEVEL SECURITY BULGARIA LTD’ Sensors & Technology in material detection. Material detection is done based on theMagnetic tuned phenomenon, a technology that detects all common nitrogen based explosives (including ammunition), potassium chlorine - based explosives and liquid explosives from 5 to > 20.000 meters distance.
Furthermore SAED technologies are able to detect human bodies and dirty bombs (Uranium wastes). WMTS
technology is certified by 4 patents, owned by ‘3 LEVEL SECURITY BULGARIA LTD’.
IN GENERAL : ‘SAED’ tech MAGNOTRON systems :
• Has Alternating Electromagnetic Signals that creating Magnetic Fields.
• Has MTR rotated by the user holding the system, creating Angular Momentum.
• Depending on the creating Magnetic Fields, different types of Explosives and humans can be detected.
• When the user is trying to move the MTR out of the direction (line) of the explosive, magnetic tune * is experienced and detection is achieved.
‘SAED’ detector’s operation is based on the ATTRACTION created by the particular explosive substance on the MTR of the system. This phenomenon is based on the magnetic tune phenomenon between the explosive and the ‘SAED’ system’s MTR . When trying to take out the MTR from the magnetic field, the user experiences difficulty. Magnetic Tune is experienced on the MTR . The magnetic tune is detected. When MTR stops and point to a direction then the user knows that detection is done.
Using the MAGNOTRON system, a new operational dimension is given to the ability to localize explosive explosives from any (pin point, medium or long distance). This way, large areas can be “cleaned” from explosives. Measurements with the ‘MAGNOTRON’ have to be taken from two points for locating the explosives. From the first point, measurement gives the direction (line) where explosives are located. From the second point, measurement (line) gives the location that explosives are located. The location is where the second measurement line, crosses the first measurement line. From a third point, measurement (line) confirms the location of the explosives.
The lines of direction from the three (or more) measurement points must be projected on a Map environment (GIS system depending on coordinates and no on map pixels) for better understanding of what is detected. Known location areas of Military bases, already shown on the Map can be excluded from the search.
In case of magnetic tuned appliance (‘SAED’) those radiofrequencies, emitted by the various cores of (hydrogen, coal, Nitrogen, Cl etc) the explosive that is searched, creates a magnetic field (98) which the resultant (93) tuned with the resultant of a magnetic field created from : (NEXT FIGURE)
1. The magnetic field of the appliance it shelf (22)
2. The magnetic field emitted from the appliance operators (102) body (97)
3. The magnetic field that created from the initial (96) impulse (movement) of the appliance MTR (15 & 71) in the horizontal level.
In the magnetic tuned phenomenon, finally, actively participates earths magnetic field (103) and any other capable to influence and to tune with the above, magnetic field happens to exist in the environment space, as drops of rain, humidity, underground waters etc. Tuned our magnetic tuned appliance to the frequency of some core precession, it resembles with our radio tuned in some radio or television stations emission frequency.
Magnetic tuned occurs at cores as Nitrogen (a chemical element that has the symbol N, atomic number of 7 and atomic mass 14.00674 u) , Cl ( Element Symbol is Cl, atomic number is 17, and atomic mass is 35.453) , and others. As a result ‘SAED’ systems detects all common nitrogen based explosives (including ammunition) and potassium chlorine - based explosives,
In next FIGURES appears the phenomenon of explosive structures magnetic tune, as it is controlled repeated (that is to say lasts as long as the emission radiation from the appliance lasts) from the ‘SAED’ system.
During the ‘cores -relaxation’ process from the explosive that `bombers' each time by the appliance and operators radiation – who participates actively in the experiment - the cores system returns in the initial balance situation, with the cores to expel energy , emitting radiation of frequency equal with the frequency of tuned in the region of radiofrequencies and transporting part of their energy in the around molecules. The energy that expels appears to be photons, the emission of which as it is well known, creates a MAGNETIC FIELD round the explosive structure. That magnetic field draws continuously the aerials of ‘SAED’ appliance, revealing so much the existence and the place that the detection of explosives is found. Some photos from spectrograph represented below.
During Magnetic tuned phenomenon on MAGNOTRON series sensors ENGINES machines a number of known phenomena take place.
Magnetic field produced from MAGNOTRON series sensor engine travels fast in earth’s physical electric potential.
Telluric Currents are very helpful to this fast travel photons.
The CYPRUS GEOPATHETIC RESEARCH INSTITUTE , the research institute of MAGNOTRON ltd, has done a lot of work in this geoenergy flux phenomena. www.cgri.gr
In , EMR is considered to be produced when by acting on them. are responsible for emission of most EMR because they have low mass, and therefore are easily accelerated by a variety of mechanisms. Rapidly-moving electrons are most sharply accelerated when they encounter a region of force, so they are responsible for producing much of the highest frequency electromagnetic radiation observed in nature. Quantum processes can also produce EMR, such as when atomic nuclei undergo gamma decay, and processes such as neutral pion decay.
Nuclear quadrupole * resonance spectroscopy or NQR is a chemical analysis technique related to nuclear magnetic resonance (NMR.
http://en.wikipedia.org/wiki/Nuclear_quadrupole_resonance
Next pictures are from the study: Field Gyroscope and Its Social Impact Dr. Mark Krinker, Applied PhysTech Research Group
FG: Field Gyroscope
PICTURE ABOVE : Measuring phase borders of a human body (IGA-1, Y. Kravchenko);
Prof. N.P. Myshkin’s and Crookes’ Experiments: At the joint of 19th and 20th Centuries, Russian Prof. N. Myshkin conducted series of the experiments on the Crookes radiometer. • The results contradicted the common sense.
N.P. Myshkin’s Experiments: The blades of the radiometer experienced rotation even in the darkness, without a visible light. Myshkin defined these mysterious forces as some ponderomotive forces.
Twisting Forces: “……in the emptiness of the Crookes tube, the process of a radiation is accompanied with origination of such a pair of forces for the irradiating body, which tends to rotate it counterclockwise, while the process of light absorption is accompanied with a clockwise rotation of the body.” N.P. Myshkin
Landmarks:
• 1922. E. Cartan speaks out the hypothesis : The Space around a
spinning matter gains a torsion.
• E. Cartan, A. Einstein: Torsion Fields –the very First Claims: Any
rotation creates a specific field they called a Torsion Field. But
this remains a pure theoretical construction for the decades.
• Late 1950’s- First experiments of Dr. N.A. Kozyrev with a non-stationary gyroscope.
• 1960’s- Kozyrev claims a weight reduction at the nonstationary rotation of the gyroscope.
• 1960’s-1980’s- Prof. A.I Veinik, Belorus Academy: The Chronal (Temporal) Field Conception as an explanation of these phenomena. He controlled a time flowing with the spinning processes.
• 1989: Another verification of Kozyrev’s experiments: H. Hayasaka and S. Takeuchi (Japan) published results of their experiments, in which they showed that the fall-time of freely falling spinning gyroscope depends on the angular velocity
1991: Russian theoretical physicist G.I.Shipov showed that the anomaly behavior of gyroscopic systems was caused by the appearance of the torsion fields, generated by spinning masses.
• 1990s- Theory of Torsion Fields (TF) by A.E Akimov. He develops TF generators and receivers.
• 1993: G. I. Shipov- Theory of Physical Vacuum. • Shipov: Torsion Fields are the fields of Inertia. He introduces 6 angle coordinates into Einstein’s Gravity-Curvature equation, relating, therefore, a curvature of the space and the gravitation to the spinning.
The Earth's surface and the ionosphere create an electrodynamic cavity that produces micropulses in the magnetic field at extremely low frequencies, from about 25 Hz to 10 Hz. Most of the micropulse energy is concentrated at about 10 Hz. Solar flares disperse charged particles in the earth's field, causing magnetic storms. These particles, which have already entered the outer boundaries of the field (the van Allen zones), which protects us from the absorption of these and other cosmic high-energy rays. (Becker, 1998).
The effect of
induction is to change the intensity of the magnetic field, which
will generate electricity in whatever conductive is present.
Therefore, daily variations in the intensity of the geomagnetic
field produce end-drafts running through the ground near the
surface.
These final currents produce their own magnetic field that will
strengthen or weaken the geomagnetic field depending on its
polarization. The change in magnetic field is proportional to the
change in telluric current, following a ratio known in science.
(Hessler, Wescott, 1959).
When two different types of geological subsoil are in contact, a
conductivity inconsistency is created, which can weaken or
strengthen daily magnetic fluctuations, sometimes for hundreds of
percent. (Rikitake, Honkura, 1986).
This change in the magnetic
field creates further electric charges, so in these areas the
electrical currents of the soil are much higher than in the
surrounding area. The ground electrical currents attract electrified
air molecules of the opposite charge.
Rocks such as basalt, volcanic lava, limestone, granite and others
with high clay, magnetite, iron, magnesium or other metals have high
electrical conductivity and are therefore channels for any current,
e.g. that produced by the passage of water. In particular, granite
always emits radon and irradiated neutrons. Radon and radiation
create ions. (Burke, Halberg, 2005).
Rocks rich in copper are particularly conductive, as copper is the
second most conductive electrical metal after pure gold. Rocks rich
in quartz create the piezoelectric effect, as they are able to store
electric loads like any other mineral, so they are used in watches.
The soil's ability to generate electricity is also commensurate with
its water content. (Burke, Halberg, 2005).
The presence of limestone has a strong interaction with the passage of water, as its geology is perfect for the production of natural electricity. Electrons are removed from the rain water as it passes through the rock's porosity, by a process called adsorption. (Mizutani et al, 1976)
So the water molecules now have a positive load and have left a
negative burden on the chalk. The phenomenon is twice as strong as
water dissolves into chalk. The calcium carbonate molecules will be
broken down, causing the removal in the water of a calcium molecule
with double positive load (ion), leaving a double negative load on
the rock.
The overall result is that the chalk has a significant negative load
and the passing water is positive. As we know, the opposite is
attracted and thus creates electric charge on the ground. The
movement of water alone will create a magnetic field, whose change
depends on the rock's porosity, and the chalk is extremely porous.
(Martin et al, 1982)
‘Current concentrations of 2,5 * 10-4 amps/m² can be generated by the continuous movement of groundwater to a sufficient aquifer are defined. These continuous currents (DC) are enough to create magnetic abnormalities exceeding 200 nT in both Menindee Trough (Australia) and Karoo Vasin (South Africa).
The final currents associated with the activity of the ionosphere can be detected by the variations in magnetic induction, but the continuous offsets associated with the potential for flow and geo-chemical activity (SP anomalies) are overshadowed by noise. Consequently, some regional magnetic abnormalities can be wrongly attributed to the variations in magnetic susceptibility with residues explained by residual magnetism."(Cull, Tucker, 1986)
Scientists have studied at the La Fournaise volcano near Madagascar,
how water flow underground through volcanic rocks can generate
electricity. (Adler et al, 1999)
Also, a team of scientists, measuring in Popo, a Mexican volcano, noticed similar results, measuring very high electrical loads in this site, coming from the geological background. (Markson, Nelson, 1970).
The ability of water to generate electric charge can be seen with a
Kelvin water dropper (Thompson, 1872).
Bioelectromagnetism is a science that researches the electric, electromagnetic, and magnetic phenomena which occur in biological tissues. These include: the reaction of excitable tissue, the electric currents and potentials, the magnetic field of the body, the response cells to electromagnetic stimulation as well as the tissue's electric and magnetic properties (Malmivuo & Plonsey, 1995). Natural electromagnetic energy constitutes a common parameter in all organisms on the planet. According to Becker, nature favors organisms that are capable to receive information from the environment cosmos through electromagnetic signals and to adjust consequently their inner processes (Becker & Marino, 2010). He also mentions that “electromagnetic energy was used by the body to integrate, interrelate, harmonize, and execute diverse physiological processes”.
The various bioelectric processes of the cell membrane constitute very important functions in biology. The cell membrane potential can be used in various ways. The membrane potential is changed rapidly when the channels for sodium ions are opened. Intercellular communication of the nervous system occurs through rapidly moving electric signals. A change in membrane potential is responsible for life: when the sperm enters the egg at, ion channels are turned on; access of other sperm is prevented by the resultant membrane potential. The transmission of information and control signals occurs due to the electric nature of biological tissues; therefore it is vital for life. Examples include vision, audition- signals sent from the periphery to the brain; movement - signals sent from the brain to muscles; homeostasis- electric signals mediating heart rate and contraction. The healing effects of bioelectromagnetism were known in medicine throughout its history; the first written mention appeared on ancient 4000 B.C Egyptian hieroglyph describing the electric sheatfish.
Healing and health are dependent on cell electricity: they run at -20 to -25 mV (Tennant, 2013). The growth of new cells for healing can occur at -50 mV; in chronic sickness and pain, cell voltage drops below -20 mV. Voltage also controls oxygen levels, which also drop in case of voltage drop; as a result ATP production is reduced significantly. Furthermore, various parasites, viruses and fungi get activated after oxygen level reduction, which further induces chronic disease. Electromagnetic fields are also responsible for transfer information from the environment to the organism. Informational interactions have a significant role in biological processes; these include the transmitting, coding, and storing information. The amount of information and not the amount of energy introduced into the system is the one responsible for biological effects due to these interactions. It is the informational signal that redistributes the energy in the system, and regulates the various processes. Concerning geophysical factors, electromagnetic forces constitute the most important medium for transferring information.
With the appropriate frequency range and field type employed, they transmit information where living organisms are located, regardless of meteorological conditions and the time of the day, in rivers, seas, within the earth's crust, and finally in the organisms' tissues. Low-strength electromagnetic fields within the physiological frequency range can induce changes in the electroencephalogram, the electrocardiogram, biological rhythms, calcium metabolism; within non-physiological frequencies and intensities electromagnetic fields stimulates adaptive homeostatic behavior (Becker & Marino, 2010). According to (Presman, 1970) natural electromagnetic fields had an important role in the organisms' evolution, specifically the extremely low frequency spectrum which is similar to biologic signals frequencies. Periodic changes in natural electromagnetic environment can affect vital function such as the rhythm of the important physiologic processes, space orientation of animals. Furthermore, in pathologic situations, changes in the electromagnetic environment induced by solar flares, lightning discharges and others, can induce disruption of physiologic processes. (Larter & Ortoleva, 1981) discuss that natural electric fields function as patterning system in early development; they also present their relation to information storage, conservation and breaking of symmetry, as well as mechanisms applied to an electrically controlled self-organizing system. According to Presman, isolated organs and cells are less sensitive to electromagnetic fields, solutions of macromolecules are even less sensitive, whereas entire organisms are most sensitive (Presman, 1970).
Positive and negative magnetic fields
Scientists have discovered that positive and negative parts of dipolar magnetic fields can have various effects on the human body (Trivieri, 2002). The physiological effects of positive magnetic fields include:
Acid production • Oxygen deficiency • Cellular edema • Exacerbation of existing symptoms • Infection acceleration • Biological disorganization • Pain and inflammation increase • Wakefulness and action • Catabolic hormone production • Toxic end-products of metabolism • Free radical production • Acceleration of brain electrical activity
They have also been associated with cancer, depression, chromosomal abnormalities, inflammation and learning difficulties.
The physiological effects of negative parts of magnetic fields include:
• PH normalization • Body oxygenation • Cellular edema resolution • Symptoms reduction • Infection inhibition • Biological normalization • pain and inflammation reduction • Rest, relaxation, and sleep • Anabolic hormone production • Metabolically produced toxins clearing • Free radical elimination • Slows down electrical activity of the brain
They have also been used effectively in the treatment of cancer, rheumatoid arthritis, headaches and migraines, insomnia and other sleep disorders, circulatory problems, fractures and pain.
Scalar or longitudinal waves
Scalar waves are non-hertzian longitudinal electric or magnetic waves (Meyl K. , 2003).
In physics, a quantity described as "scalar" only contains information about its magnitude. In contrast, a "vector" quantity contains information both about its magnitude and about its direction.
Some examples of scalar waves include: acoustic waves, waves in water, mechanical waves of compression or rarefaction; plasma waves and biophotons; the longitudinal waves used by Tesla - they were potential vortex wave that can identify as neutrino radiation (Meyl K. , 2003)
Electromagnetic waves are transverse hertzian waves with vector quantities derived as solutions to a set of vector wave equations; examples include cosmic radiation, x-rays, microwaves, radio waves.
Earth radiation, according to (Meyl K. , 2003) has also standing wave nature, which can be interpreted as slowed down neutrino radiation. Areas with geophysical anomalies are considered be points of interference of such longitudinal waves.
Humans - Mechanisms
The presence of magnetite and magnetic crystals in the brain, the area of the ethmoid and ears ( (Kirshivink, Kobayashi-Kirshivink, & Woodford, 1992), (Marinaga, 1992), (Ruttan, Persinger, & Koren, 1990)) • The presence of iron in the blood • The body’s composition of 70% water, which has high electrical conductivity and creates magnetic crystals (Fesenko & Gluvstein, 1995) • The property of the tissues to function as semiconductors without special resistance, known as non-thermal effect (Oschman, 2000) • The production of electromagnetic fields from the heart and the brain, the electrical transmission of signals through the nerves. The strongest electromagnetic field is that of the heart, 100 times larger than that of the brain (McCraty R. , 2003). According to Becker (Becker & Marino, Electromagnetism life, 2010), the human body uses electromagnetic energy for the integration, interrelation, harmonization, and execution of various biological processes.
Humans and all living organisms are a network of reception, production and emission of electromagnetic fields. The electrical processes of various biological systems, the cells' iron content, the proteins' function as semiconductors of the cell membrane as well as the intra and extracellular water as liquid crystals constitute biology as receiver, producer, and transmitter of electromagnetic information. It is known that cell body microtubules are conductors of electromagnetic waves (f = 1013 Hz and their harmonics), which coordinate cellular functions (Rahnama, Tuszynski, & Bόkkon, 2011), whereas centrosomes contain silicon oxides which emit and receive electromagnetic signs.
Low strength electromagnetic fields within the physiological frequency range can induce changes in brain waves, heart rate, biological rhythms, calcium metabolism as well as human behavior. Electromagnetic fields outside the physiological frequency and intensity range can generate adaptive homeostatic reactions in humans. (Becker & Marino, 2010)
Bioinformatics has demonstrated that communication within the human body is both electrical and chemical. Information is contained within nerve electrical stimuli as well as biochemical compounds-signals. The cells contain various information receptors, functional structures and biochemical pathways for information translation and transfer from the nucleus for execution (Oschman, 2000). There is also data supporting that the earth’s magnetic fields are carriers of biologically information connecting living systems. Therefore our throughs, emotions and intentions expressing through the bodys electromagnetic fields, matter and that coherent, cooperative intent can impact global events and the quality of life on Earth (McCraty, 2014).
The human body's resonance
Human beings have both a mechanical as well as an energetic nature. There are various sources of energetic stimuli which interact with the essential ones for the function of the cell, the organ and the organism.
The human body has the capacity to resonate with a variety of fields, including infrasounds, low and high frequency natural waves, gamma rays and others (Persinger, 2014)
Concerning the human body, there are fundamental electromagnetic frequencies it produces, which characterize its structure and function (Andreev, Beliy, & Sit’ko, 1984). Resonance between tissue and cell coordination by very high frequency and low intensity radio waves was discovered by Russian and Ukrainian radio physicists, who recorded resonant frequencies of humans, animals as well as biological and chemical substances (Kositsky, Nizhelska, & Ponezha, 2001). Furthermore, the transmission and recording of very low intensity photons from the human body demonstrated different frequency signatures for each organ (Cohen & Popp, 2003).
The existence of a DC perineural field, which produces DC magnetic fields the brain has also been measured by a SQUID magnetometer; constant in the order of one billionth of the intensity of the geomagnetic field, which is in average about 50.000 nT (Oschman, Energy Medicine, the scientific basis., 2000).
Rocard, demonstrated that most individuals are sensitive to gradients between 200 -300 nT/m (Rocard, 1964). The limit for interacting with subsurface activity for most sensitive people is a gradient of 10 nT/m.
Harvalik (Harvalik, 1978) demonstrated that the most sensitive regions of the body are in the area of the renal and adrenal glands, as well as within the brain, especially the pineal gland. Sensitivity is reduced in kidney dysfunction episodes. Furthermore, changes in the static magnetic fields' direction can lead to melatonin synthesis reduction in the pineal gland. The two most fundamental magnetic fields on the biosphere are: the one within living organisms, generated by ion transfer to the nerves, as well as by the heart and brain, and the one generated by the earth's liquid core and rotation. The interaction between the two fields is evident; according to Becker (Becker & Selden, The Body Electric, 1998) the geomagnetic field is responsible for maintaining the system of controlling bodily functions within normal range.
Cell growth and repair, based on cell division regulation, is synchronized with the Earth's magnetic field, according to Becker (Becker & Selden, 1998). This is evident as the process of cell division overall occurs in several longer stages, which overall last one day, including breaking down, alignment and equal distribution of cell chromosomes as well as cellular DNA duplication of all.
The geomagnetic field can induce changes that exceed the capability of human adaptation, the regulatory activities can be greatly affected, such as the central nervous system, hormonal, neurotransmitter, cellular, electrophysiological, membrane-related and others (Stoupel E. , 1999).
The magnetic isotope effect ( (Buchachenko, 2009) (Buchachenko, Kouznetsov, & Berdinsky, 2006)) may also contribute to biological effects of magnetobiological interactions; 30 minutes exposure at 1 μΤ frequency or time varying magnetic fields can induce discernible changes in molecular signaling pathways.
Correlation experiments
Various experiments have been done that demonstrate apparent correlations between a variety of geophysical anomalies and different diseases.
Shitov (Shitov A. , 2010) found strong correlation between various diseases and geophysical anomalies (Fig. 1), including intrusions, magnetic anomalies and faults.
The highest and most stable relationships were found between prevalence rates of blood diseases, diseases of nervous, respiratory and genitourinary systems, total morbidity and gamma radiation anomalies (Shitov A. , 2010). In the research done by Rudnik (Rudnik & Melnikov, 2010) it was clearly shown that cancer incidence rate was greatly augmented in the intersection of fault lines.
Aschoff, a physician, was the first to use the blood's electromagnetic oscillations, which are measurable by a simple blood test. After 20,000 tests, he noticed that people with electromagnetically oscillating blood lived without exception in a disrupted geopathic zone, either in their sleeping area or in their workplace. Individuals with only magnetically oscillating blood were not exposed to a geopathic disorder and were healthy. Due to the stress from the electric current and radiation (mostly gamma ray) emitted by a geopathic zone, the blood loses its natural structure and becomes electrically polarized in the opposite charge. He also mentions that neutron radiation emitted by geopathic zones can cause mutations in the cells. (Aschoff D. , 2014), (Aschoff, et al., 1994),
Hacker, also a medical doctor, reports that longitudinal scalar waves emitted at different locations can cause various effects symptoms on biology. Together with his team, they conducted randomized double blind clinical trial, 52 test persons in 2 locations, one identified with a geophysical anomaly and the other one neutral.
They carried out GDV analysis (Gas Discharge Visualization) as well as ImmunoglobulinA (IgA) and A-Amylase measurements. The results were coherent, as in higher GDV mean area, IgA levels were also higher, indicative of relaxation, and in the geopathic zones with lower GDV Mean Area, A-amylase was higher, indicative of stress state. (Hacker, Augner, & Pauser, 2012).
In another study, body voltage and skin resistance were measured using a biofeedback system, both on detected geophysical anomalies and neutral zones; the results showed clear correlation between the measured parameters and the locations (Dharnadhikari, 2011).
Another important study was carried out in Vilnius University, directed by Sliaupa (Sliaupa, et al., 2004) to observe the effect of four geological factors on human health: (1) potential fields, (2) concentration of geochemical elements in the soil, (3) tectonics, (4) landscape. The study reveals strong statistical correlation of gravity and magnetic fields, some landscape features and chemical elements with human diseases, such as cancer, schizophrenia, suicides, respiratory, cardiac-vascular diseases (Sliaupa, et al., 2004).
According to the study “the human health is shown to have some statistical correlation with the Earth's fields. This relationship is essentially strong as regards the magnetic field. The intensity of the potential field is of less importance than its variability. The latter commonly reflects the more complex tectonic fabric of the Earth's crust. This influence is, however, of different type, it may be positive with respect to some diseases whereas negative with regard to other diseases. Infection and respiratory disease events increase in number with increasing variability of the gravity field, whereas the variability of the magnetic field has a reverse correlation. It is commonly believed that the gravity field reflects more deep variations in the composition of the Earth's crust, whereas the magnetic field mirrors shallower geological bodies. The local variations of the magnetic field, by contrast, increase risk of cancer (very strong positive statistic load), cardiacvascular and schizophrenia” (Sliaupa, et al., 2004).
The study continues: “Some chemical elements contained in the soil seem to have some impact on the human health. This influence, similarly to potential fields, may be either positive or negative. Only cancer shows positive statistic relationship with Ti, Zr, (in other words this elements increase the risk level), whereas the other diseases ((schizophrenia, suicides, respiratory, cardio vascular) are remedies by Pb, Sn, Y, I, Rb, Sr reach environment. In geological terms, these two groups form two different correlation classes. The former is related to mineral association resistive to denudation (they are expected in re-deposited sandy lithologies), whereas the latter is typical for carbonaterich lithologies, also for the higher biogenic matter content.” (Sliaupa, et al., 2004)
Extremely low frequencies are part of the natural terrestrial radiation. According to Carpenter (Carpenter, Sage, & David, 2012), ELF intensity can result with chronic exposure in DNA damage, affect cellular communication, cellular metabolism and repair, cancer surveillance within the body; neurological effects, cognitive function and memory; depression; cardiac effects; pathological leakage of the blood-brain barrier; and impairment of normal immune function, fertility and reproduction.
DNA
The DNA, according to research, is antenna for electromagnetic fields, so it becomes evident that it can be effected from fluctuations in these fields (Blank & Goodman, 2011).
Stoupel (Stoupel, et al., 2005 ) demonstrated that genetic expression can be affected by changes in geomagnetic activity associated with the solar cycle. According to research, gene and/or protein expression in certain types of cells can be altered by electromagnetic fields, even at low intensities lower (Carpenter, Sage, & David, 2012). Extremely-low frequency has also been correlated with DNA damage; in studies of genotoxicity and extremely-low frequency exposure, 66% showed DNA damage and 44% no significant effect (Carpenter, Sage, & David, 2012). DNA activates the production of stress protein when exposed to extremely low frequency electromagnetic fields; the biochemical pathway that is activated is non-thermal (Carpenter, Sage, & David, 2012). Changes in DNA electron transfer are an action mechanism resulting from non-thermal extremely low frequency electromagnetic fields; production of stress proteins due to electromagnetic field exposure can be activated by various frequencies of the spectrum. Environment levels of 0.5 to 1.0 μT are considered thresholds for extremely low frequencies triggering stress on biological systems; DNA damage, a cause of cancer, can take place at levels below these limits (Carpenter, Sage, & David, 2012).
Tesla (1905) wrote, “the earth is found to be alive with electrical vibrations”. The Radcliffe tower he created, was an energy generator that would not function if it did not “grip the earth”.
The
Earth's
electromagnetic
field
is
largely
a
result
of
the
interaction
between
the
magnetic
field,
which
comes
from
the
planet's
melted
iron-nickel
core,
and
the
charged
ionosphere
gases.
There
are
daily
fluctuations
in
the
earth's
geomagnetic
field,
which
depend
on
daily
solar
movement
from
solar
winds.
It
varies
by
lunar
day
and
month,
and
there
is
also
an
annual
change
as
they
revolve
around
the
sun.
Bibliography
Abrahams, P. (2002). Soils: their implications to human health. Science of the Total Environment(291), 1-32.
Adams, M. (1997). "Were early Native Americans aware of naturally occurring radiation?". Society for Scientific Exploration Conference.
Adey, W. (1980). Frequency and power windowing in tissue interactions with weak electromagnetic fields. Proceedings of the IEEE(68), 119-125.
Adler, M. P., Le Mouel, J. L., & Zlotnicki, J. (1999) Electrokinetic and magnetic fields generated by flow through a fractured zone: a sensitivity study for la Fournaise volcano. Geophysical research letters., 26(6), 795-798.
Aggett, P., & Rose, S. (1987). Soil and congenital malformations. Experientia(43), 104-108.
Ahmed, Z., & Wieraszko, A. (2008). The mechanism of magnetic field-induced increase of excitability in hippocampal neurons. Brain Research(1221), 30-40.
Åkerstedt, T. A.-E. (1999). A 50-Hz electromagnetic field impairs sleep. Journal of Sleep Research(8), 77-81.
Alabdulgader, A., McCraty, R., Atkinson, Y., Vainoras, A., Ragulskis, M., & Stolc, V. (2018). LongTerm Study of Heart Rate Variability Responses to Changes in the Solar and Geomagnetic Environment. Scientific Reports, 8(2663).
Altunel, E. (1998). Evidence for damaging earthquakes at Priene: western Turkey. Turkish Journal of Earth Sciences(7), 25-35.
Altunel, E. (1999). Geological and geomorphological observations in relation to the 20 September 1899 Menderes earthquake, western Turkey. Journal of the Geological Society(156), 241-246.
Anagnostopoulos, C.G. (2012). Characteristics of flux-time profiles, temporal evolution, and spatial distribution of radiation-belt electron precipitation bursts in the upper ionosphere before great and giant earthquakes. Annals of Geophysics.
Anagnostopoulos, C.G. (2013). A study of correlation between seismicity and mental health: Crete, 2008–2010. Geomatics, Natural Hazards and Risk.
Andreev, Y., Beliy, M., & Sit’ko, S. (1984). Occurrence of the human body’s own characteristic frequencies. Documents of AN USSR, 60-63.
Andronova, T. D. (1982). Heliometeotropic reactions of healthy and sick people. Leningrad, USSR: Medicina.
Annunziatellis, A., Ciotoli, G., Lombardi, S., & Nolasco, F. (2003). Short- and long- term gas hazard: the release of toxic gases in the Alban Hills volcanic area (central Italy). Journal of Geochemical Exploration(77), 93-108.
Apostol, A. (1995). North American Indian Effigy Mounds: An Enigma at the Frontier of Archaeology and Geology. Journal of Scientific Exploration, 9(4), 549-563.
Aptikaeva, O.I. (2010). Dynamics of Morbidity Rate in a Population Before and After Severe Earthquakes and Its Relationship with Other Natural Factors. Izvetiya, Atmospheric and Oceanic Physics.
Aschoff, D. (2014). Electromagnetic property of blood measurable different on geological fault zones-detection of fault zones by measurement of a drop of blood. In Elektromagnetische Eigenschaft des Blutes durch Reizzonen messbar verändert-Feststellung von Reizzonen Einwirkung durch einen Tropfen Blut. chapter in Der Elektromagnetische Bluttest, Yashi Kunz, Lightball Media.
Aschoff, D. D. (1994). Location as a risk factor: Mutation and measurement of biologically effective radiation and fields and their influence on humans. In Standort als Risikofaktor: Mutung und Messung biologisch wirksamer Strahlen und Felder und ihr Einfluss auf den Mensche, Reich Verlag.
Aschoff, D., Dräger, M., Heinz Müller, H., Aschoff, J., Gruner, S., Rothdach, P.,. Worsch, E. (1994). Location as a risk factor: Mutation and measurement of biologically effective radiation and fields and their influence. In Standort als Risikofaktor: Mutung und Messung biologisch wirksamer Strahlen und Felder und ihr Einfluss auf den Mensche, Reich Verlag.
Athanasiou, A., Karkambounas, S. B., Lykoudis, E., Katsaraki, A., Kartsiouni, T., Papalois, A., & Evangelou, A. (2007). The Effect of Pulsed Electromagnetic Fields on Secondary SkinWound Healing: An Experimental Study. Biolectromagnetics.
Athanasiou, Μ. A., Machairidis, G. G., David, C. N., & Anagnostopoulos, G. C. (2013). Enhanced ULF electromagnetic activity detected by DEMETER above seismogenic regions.
Augner C., Hacker G.W., Jekel I. (2010). Geopathic Stress Zones: Short-Term Effects on Work Performance and Well-Being?. Journal of Alternative and Complemenntary Medicine, Jun;16(6):657-61
Avakyan, S. (1999). Anomalous aerospace phenomena: geophysical aspect. Geomagnetism and Aeronomy(39), 1-7.
Avdikos A, Karkabounas S, Metsios A, Kostoula O, Havelas K, Binolis J, Verginadis I, Hatziaivazis G, Simos I, Evangelou A. (2007). Anticancer effects on leiomyosarcoma–bearing Wistar rats after electromagnetic radiation of resonant radiofrequencies. Hellenic Journal of Nuclear Medicine, May-Aug;10(2):95-101.
Avtsyn, A. (1972). Introduction to geographical pathology. Moscow, USSR.: Medicina.
Babayev, E. A. (2007). Effects of geomagnetic activity variations on the physiological and psychological state of functionally healthy humans: some results of Azerbaijani studies. Advances in Space Research(40), 1941-1951.
Babayev, E., & Allahverdiyeva, A. (2007). Effects of geomagnetic activity variations on the physiological and psychological state of functionally healthy humans: some results of Azerbaijani studies. Advances in Space Research(40), 1941-1951.
Babayev, E., Crosby, N., Obridko, V., & Rycroft, M. (2012). In Advances in Solar and Solar Terrsetrial Physics. In G. M. Demetrescu. Research Signpost.
Babcock, E., & Collins, J. (1929). Does natural ionizing radiation control rate of mutation? Proceedings of the National Academy of Sciences(15), 623-628.
Bachler, K. (1989). Earth radiation. Manchester, UK: Wordmasters.
Badyaev, A. (2005). Stress-induced variation in evolution: from behavioural plasticity to genetic assimilation. Proceedings of the Royal Society B: Biological Sciences(272), 877-886.
Baevsky, R. P. (1998). Regulation of autonomic nervous system in space and magnetic storms. Advances in Space Research(22), 227-234.
Bardasano, J., Cos, S., & Picazo, M. (1989). Veränderungen der Anzahl synaptischer Bänder in der Pinealdrüse der Ratte an Geomagnetischen Ruhetagen und Gewittertagen. Journal für Hirnforschung(30), 639-643.
Bates, M. G. (1998). Cancer incidence, morbidity and geothermal air pollution in Rotorua, New Zealand. International Journal of Epidemiology(27), 10-14.
Bates, M., Garret, N., Graham, B., & Read, D. (1998). Cancer incidence, morbidity and geothermal air pollution in Rotorua, New Zealand. International Journal of Epidemiology(27), 10-14.
Baxter, P., Baubron, J.-C., & Coutinho, R. (1999). Health hazards and disaster potential of ground gas emissions at Furnas volcano, São Miguel, Azores. Journal of Volcanology and Geothermal Research(92), 95-106.
Becker, R., & Marino, A. (2010). Electromagnetism and Life. New York: Cassandra Publishing.
Becker, R., & Seldon, G. (1985). The body electric,. William Morrow.
Belisheva, N., Popov, A., Petukhova, N., Pavlova, L., Osipov, K., Tkachenko, S., & Baranova, T. (1995). Qualitative and quantitative evaluation of the effect of geomagnetic field variations on the functional state of the human brain. Biophysics(40), 1007-1014.
Belyaev, D., & Borodin, P. (1982). The influence of stress on variation and its role in evolution. Biologisches Zentralblatt(100), 705-714.
Bergsmann, O. (1990). Risikofaktor Standort. Vienna: Facultas University Press,.
Bergsmann, O. (1994). Risk factor location. Dowser zone and human Scientific research on the problem of location influences on the people. Wien: Facultas, Universitatsverlag Ges. m.b.H. Wien.
Bgatov, V. A. (1992). Studies of azonal ecological and geological systems exemplified by platform terrains in Siberia. Novosibirsk, Russia: Siberian Research Institute of Geology, Geophysics, and Mineral Resources.
Binhi, V. (2002). Magnetobiology: Underlying physical problems. San Diego, CA.: Academic Press.
Blank, M., & Goodman, R. (2011). DNA is a fractal antenna in electromagnetic fields. International Journal of Radiation Biology., 87(4):409-15.
Bølviken, B., Celius, E., Nilsen, R., & Strand, T. (2003). Radon: a possible risk factor in multiple sclerosis. Neuroepidemiology(22), 87-94.
Booth, J., Koren, S., & Persinger, M. (2005). Increased feelings of the sensed presence and increased geomagnetic activity at the time of the experience during exposures to transcerebral weak complex magnetic fields. International Journal of Neuroscience(115), 1053-1079.
Boyarskikh, I.S. (2012). Change in Biochemical and Morphological Characteristics of Lonicera Caerulea in Tectonically Active Zone of the Dzhazator River Valley (Altai Mountains). Izvestiya, Atmospheric and Oceanic Physics.
Boyarskikh, I. S. (2010). Intraspecific variability of plants: the impact of active local faults. In F. I., Man and the geosphere. New York: Nova Science Publishers.
Boyarskikh, I., & Shitov, A. (2010). Intraspecific variability of plants: the impact of active local faults. In F. I., Chapter 5, Man and the geosphere. New York: Nova Science Publishers.
Bradna, L. (2002). The Influence of Hydro pathogenic zones on Drivers. Narendra Prakashan, 38-43.
Brady, B. T., & Rowell, G. A. (1986). Laboratory Investigation of the Electrodynamics of rock fracture. Nature, 321, 490.
Breus, T., Pimenov, K., Cornélissen, G., Halberg, F., Syutkina, E., Baevsky, R., Chibisov, S. (2002). The biological effects of solar activity. Biomedicine and Pharmacotherapy(56), 273-283.
Brooker, C. (1983). Magnetism and the Standing Stones. In New Scientist.
Brown, S.R. & Haupt, R.W (1997). Study of Electrokinetic Effects to Quantify Groundwater Flow., Sandia Report SAND 94-2607, UC-122, Sandia National Laboratories, April
Buchachenko, A. (2009). Magnetic isotope effects in chemistry and biochemistry. New York: Wiley.
Buchachenko, A., Kouznetsov, D., & Berdinsky, V. (2006). New mechanisms of biological effects of electromagnetic fields. Biophysics(51), 489-496.
Burch, J., Reif, J., & Yost, M. (1999). Geomagnetic disturbances are associated with reduced nocturnal excretion of a melatonin metabolite in humans. Neuroscience Letters(266), 209-212.
Bureau, Y., & Persinger, M. (1992). Geomagnetic activity and enhanced mortality in rats with acute (epileptic) limbic lability. International Journal of Biometeorology(36), 226-232.
Burke, J., & Halberg, K. (2005). Seed of Knowledge, Stone of Plenty: Understanding the Lost Technology of the Ancient Megalith-Builders. Council Oak Books.
Calabrese, E. (1994). Biological effects of low level exposures: Dose-response relationships. Boca Raton, FL: CRC Press.
Calabrese, E. (2008). What is hormesis? In E. L. Rattan, Mild stress and healthy aging: Applying hormesis in aging research and interventions (pp. 5-19). Amsterdam, Netherlands: Springer.
Calabrese, E. J. (2009). HORMESIS IS CENTRAL TO TOXICOLOGY, PHARMACOLOGY AND RISK ASSESSMENT. MA 01003, USA.
Calabrese, E., & Baldwin, L. (2001). The frequency of U-shaped dose responses in the toxicological literature. Toxicol Sci, 62(2):330–338.
Calabrese, E., & Baldwin, L. (2003). Hormesis: the dose-response revolution. Annu Rev Pharmacol Toxicol, 43:175-97.
Calahhan, P. (1995). Paramagnetism, rediscovering Natures Secret Force ofGrowth. Texas, U.S.A.: Acres.
Carapezza, M., Badalamenti, B., Cavarra, L., & Scalzo, A. (2003). Gas hazard assessment in a densely inhabited area of Colli Albani Volcano (Cava dei Selci, Roma). Journal of Volcanology and Geothermal Research(123), 81-94.
Carpenter, D., Sage, C., & David, O. (2012). BioInitiative Report: A Rationale for Biologically-based Public Exposure Standards for Electromagnetic Radiation at.
Chavez, R., Tejero, A., Cifuentes, G., Argote, D., & Hernandez, J. (2015). A Special ERT-3D Array Carried Out to Investigate the Subsoil of the Pyramid El Castillo, Chichen Itza, Mexico, Near Surface Geoscience-21st European Meeting of Environmental and Engineering Geophysics.
Chernouss, S., Vinogradov, A., & Vlassova, E. (2001). Geophysical Hazard for Human Health in the Circumpolar Auroral Belt: Evidence of a Relationship between Heart Rate Variation and Electromagnetic Disturbances. Natural Hazards March, Volume 23, Issue 2–3, pp 121–135
Cherry, N. (2002). Schumann Resonances, a plausible biophysical mechanism for the human health effects of Solar/Geomagnetic Activity. Natural Hazard, 26:279-331.
Chibisov, S., Breus, T., Levitin, A., & Drogova, G. (1995). Biological effects of a planetary magnetic storm. Biophysics(40), 957-966.
Chizevskii, A. (1968). The Earth in the Universe (ed. V.V. Fedynskii), published for NASA by the Israel Program for Scientific Translation. Jerusalem.
Cleal, E., Walker, K., & Montague, R. (1995). Stonehenge and its landscape. London: English Heritage.
Close, J. (2012). Are stress responses to geomagnetic storms mediated by the cryptochrome compass system?. Proceedings of Biological Sciences. Jun 7;279(1736):2081-90
Cohen, B. (1995). Test of the linear-no threshold theory of radiation carcinogenesis for inhaled radon decay products. Health Physics(68), 157-174.
Cohen, S., & Popp, F. (2003). Biophoton emission of human body. Indian Journal of Experimental Biology, 41, 440-445.
Committee, G. S. (1986). Active tectonics. Washington, DC-: National Academy Press.
Conesa, J. (1995). Relationship between isolated sleep paralysis and geomagnetic influences: a case study. Perceptual and Motor Skills(80), 1263-1273.
Connell-Rodwell. (2001). Exploring the Potential Use of Seismic Waves as a Communication Channel by Elephants and Other Large Mammals. Amer. Zool.
Constable C. (2005). Non-Dipole field. Encyclopedia of Geomagnetism and Paleomagnetism.
Conter, A., Dupouy, D., & Planel, H. (1983). Demonstration of a biological effect of natural ionizing radiations. International Journal of Radiation Biology(43), 421-432.
Cook Ian, Pajot S. K., Leuchter A.F. (2008). Ancient Architectural Acoustic Resonance Patterns and Regional Brain Activity. Time and Mind: The Journal of Archeology Consciousness and Culture, 1, 95-104.
Cook, A., Hainsworth, L., Sorey, M., Evans, W., & Southon, J. (2001). Radiocarbon studies of plant leaves and tree rings from Mammoth Mountain, CA: a longterm record of magmatic CO2 release. Chemical Geology(177), 117-131.
Cook, C. (2004). Psychiatry and mysticism. Psychiatry and mysticism. Mental Health, Religion and Cultue(7), 149-163.
Cook, I., Pajot, S., & Leuchter, A. (2008). Ancient Architectural Acoustic Resonance Patterns and Regional Brain Activity Time and Mind. The Journal of Archaeology Consciousness and Culture, 1(1):95–104.
Cook, L., & Persinger, M. (2000). Suppression of experimental allergic encephalomyelitis is specific to the frequency and intensity of nocturnally applied, intermittent magnetic fields in rats. Neuroscience Letters(292), 171-174.
Cornelissen, G., Halberg, F., Breus, T., Syutkina, E., Baevsky, R., & Weydahl, A. (2002). Non-photic solar associations of heart rate variability and myocardial infarction. J Atmos Sol-Terr Phys, 64:707–720.
Cothern, C., & Smith, J. (1987). Environmental radon. New York: Plenum Press.
Crain, I. (1971). Possible direct causal relation between geomagnetic reversals and biological extinctions. Bulletin of the Geological Society of America(82), 2603-2606.
Croute, F., Soleilhavoup, J., Vidal, S., Dupouy, D., & Planel, H. (1982). Paramecium tetraurelia growth stimulation under low-level chronic irradiation: investigations on a possible mechanism. Radiation Research(92), 560-567.
Cull, J. P. (1986). Telluric Currents and magnetic anomalies. Geophysical Research Letters, 13(9), 941-944.
Culver, R., Rotton, J., & Kelly, I. (1988). Geophysical variables and behavior: XLIX. Moon mechanisms and myths: a critical appraisal of explanations of purported lunar effects on human behavior. Psychological Reports(62), 683-710.
Curry, M. (1978). Curry-Netz: Das Reaktionsliniensystem als krankheitsauslösender Faktor. München, Germany: Herold.
David, A., & Payne, A. (1997). Geophysical Surveys within the Stonehenge Landscape: A review of Past Endeavour and Future potential. Proceedings of the British Academy(92), 73-113.
De Boer, J., Hale, J., & Chanton, J. (2001). New evidence for the geological origins of the Ancient Delphic oracle (Greece). Geology(29), 707-711.
De Matteis, G., Vellante, M., Marrelli, A., Villante, U., Santalucia, P., Tuzi, P., & Prencipe, M. (1994). Geomagnetic activity, humidity, temperature and headache: is, there any correlation? Headache(34), 41-43.
Debertolis, P. T. (2014, Februaty). Systems of acoustic resonance in ancient sites and related brain activity. Proceedings of Conference Archaeoacoustics. The Archaeology of Sound. Malta.
Del Seppia, C. M. (2006). Simulation of the geomagnetic field experienced by the International Space Station in its revolution around the Earth: effects on psychophysiological responses to affective picture viewing. Neuroscience Letters(400), 197-202.
Derek, J. (1994). The Effect of Geopathic Stress on Building Occupants. Renew Energy, 993-996.
Devereux, P. (1999). Places of Power: Measuring the Secret Energy of Ancient Sites. Blandford Pr; 2 edition
Devereux, P., Steel, J., & Kubrin, D. (1989). Earth mind, a modern adventure in ancient wisdom. NY: Harper and Row.
Dharmadhikari N.P., Rao A. P., Pimplikar S.S., Kharat A. Aghav S. D., Meshram D. C. Kulkarni S., Jain B. B. (2010). Effect of geopathisc stress on human heart rate and blood pressure. Indian jorunal of science and technology, January, 1, 54-57.
Dharmadhikari, N., Meshram, D., Kulkarni, S., Kharat, A., & Pimplikar, S. (2011). Effect of geopathic stress zone on human body voltage and skin resistance. Journal of Engineering and Technology Research, 3(8):255-263.
Dimitrova, S. (2006). Relationship between human physiological parameters and geomagnetic variations of solar origin. Advances in Space Research(37), 1251-1257.
Divi, R., & Fyson, W. (1973). Folds and strain in Grenville metamorphic rocks, Bancroft, Ontario, Canada. Bulletin of the Geological Society of America(84), 1607-1618.
Dmitriev, A. N. (1998). Natural self-luminous objects. Novosibirsk, Russia: Institute of Mathematics, Russian Academy of Sciences.
Dmitriev, А. D. (2005). Unusual phenomena in nature and non-uniform physical vacuum. Biysk, Russia: Biysk Pedagogical University.
Doronin, V., Parfent’ev, V., Tleulin, S., Namvar, R., Somsikov, V., Drobzhev, V., & Chemeris, A. (1998). Influence of variations in geomagnetic field and solar activity on human physiological parameters. Biophysics(43), 610-616.
Drachev, S., & Shitov, A. (2007). Geophysical characteristics of some archaeological complexes of the Mountain Altai. In N. B. Maidurova, German researchers in Altai: Proceedings of the conference (pp. 175-178). Gorno-Altaysk, Russia: Gorno-Altaysk University Press.
Dubrov, A. (1978). The geomagnetic field and life. Geomagnetobiology. New York: Plenum Press.
Dubrov, A. (1996). Human biorhythms and the Moon. New York: Nova Science Publishers.
Dubrov, A. (2008). Geopathic Zones and Oncological Diseases. The sixteenth seminar of BDA. June. Druskininkai, Lithuania.
Dubrov, A. (2008). Geophatich zones and oncological diseases. Federal Scientific &-Clinical Experimental Center of Tradition Methods of Diagnostics and Medical Treatment of Roszdav RF. Lithuania.
Durand, M. (2006). Spatial analysis of respiratory disease on an urbanized geothermal field. Environmental Research(101), 238-245.
Durand, M., & Wilson, J. (2006). Spatial analysis of respiratory disease on an urbanized geothermal field. Environmental Research(101), 238-245.
Erickson, B. (2007). The therapeutic use of radon: a biomedical treatment in Europe; an “alternative” remedy in the United States. Dose-Response(5), 48-62.
Farmaki, S. (2013). Map of Geomythology of Peloponese. PhD Dissertation. Faculty of Geology, Univeristy of Patras.
Farrar, C., Sorey, M., Evens, W., Howle, J., Kerr, B., Kennedy, B., Southon, J. (2002). Forest-killing diffuse CO2 emissions at Mammoth Mountain as a sign of magmatic unrest. Nature(376), 675-678.
Fedorov, A. (2004). World history and global geological structures. In A. Fedorov, The system of the planet Earth (Non-conventional problems of geology): Papers of the 12th Scientific seminar (pp. 385-420). Moscow, Russia: ROO "The Structural Harmony of the Earth Planets".
Fedorov, A. (2007). Historical and geological commentary to the paper by O.V. Kirichenko. In A. Fedorov, The system of the planet Earth (Non-conventional problems of geology): Papers of the 14th and 15th Scientific seminars (pp. 371-374). Moscow, Russia: LKI Press.
Feinendegen L.E. (2005) Evidence for beneficial low level radiation effects and radiation hormesis. The British Journal of Radiology. Jan;78(925):3-7.
Felgin, V., Nikitin, Y., & Vinogradova, T. (1997). Solar and geomagnetic activities: are there associations with stroke occurrence? A population-based study in Siberia, Russia (1982– 1992). Cerebrovascular Diseases(7), 345-348.
Fesenko, E., & Gluvstein, A. (1995). Changes in the state of water, induced by radiofrequency electromagnetic fields. FEBS Letters(367), 53-55.
Fleming, J. P. (1994). Magnetic pulses elevate nociceptive thresholds: comparison with opiate receptor compounds in normal and seizure-induced brain-damaged rates. Electro- and Magnetobiology(13), 67-75.
Florinsky, I. (2000). Relationships between topographically expressed zones of flow accumulation and sites of fault intersection: analysis by means of digital terrain modelling. Environmental Modelling and Software(15), 87-100.
Florinsky, I. (2008). Influence of geological and geophysical factors on spatial distribution of monasteries (in the context of neurophysiological data). In A. Fedorov, The system of the planet Earth (Non-conventional problems of geology): Paper of the 16th Scientific seminar (pp. 515-541). Moscow, Russia: Librokom Press.
Florinsky, I. (2010). Sacred places and geophysical activity. In Man and the Geosphere. New York: Nova Science Publishers
Florinsky, I. (2004). Topographic control of soil microbial activity: a case study of denitrifiers. Geoderma(119), 33-53.
Freund, F. S. (2007). Electric currents along earthquake faults and the magnetization of pseudotachylite veins. Tectonophysics(431), 131-141.
Freund, F. T. (2003). Rocks That Crackle and Sparkle and Glow: Strange Pre-Earthquake Phenomena. Journal of Scientic Exploration, 37–71.
Freund, F. T. (2006). Electric currents streaming out of stressed igneous rocks – a step towards understanding pre-earthquake low frequency EM emissions. Physics and Chemistry of the Earth, A/B/C(31), 389-396.
Friedman, H., Becker, R., & Bachman, C. (1963). Geomagnetic parameters and psychiatric hospital admissions. Nature(200), 626-628.
Fritsch, V. (1955). Das Problem geopathogener Erscheinungen vom Standpunkt der Geophysik. München, Germany: Lehmann.
Gak, E., & Gridin, V. (2008). About nature Influence Geophysics Earth’s Fields anomalies on the Living Systems. Earth's Fields Conference June Drunskininkai, Lithuania.
Gelfand, I. G.-B. (1972). Criteria of high seismicity, determined by pattern recognition. Tectonophysics(13), 415-422.
Ghione, S., Mezzasalma, L., Del Seppia, C., & Papi, F. (1998). Do geomagnetic disturbances of solar origin affect arterial blood pressure? Journal of Human Hypertension(12), 749-854.
Giannnoulopoulou,L. (2019). The effects of geophysical anomalies on the biosphere. PHD Thesis. University of Ioannina School of Health Sciences Faculty of Medicine Sector of Clinical and Basic Functional Sciences Department of Physiology.
Gilman, E., & Knox, E. (1998). Geographical distribution of birth places of children with cancer in the UK. British Journal of Cancer(77), 842-849.
Gmitrov, J., & Gmitrova, A. (2004). Geomagnetic field effect on cardiovascular regulation. Bioelectromagnetics(25), 91-101.
Gokhberg, М. M. (1995). Earthquake prediction: Seismo-electromagnetic phenomena. London, UK: Gordon and Breach.
Gomez-Pinilla, F. (2008). The influences of diet and exercise on mental health through hormesis. Ageing Res Rev. Jan, 7(1):49-62.
Goodman, R., Bassett, C., & Henderson, A. (1983). Pulsing Electromagnetic Fields Induce Cellular Transcription. Science.
Gunn, P. J., & Dentith, M. C. (1997). Magnetic responses associated with mineral deposits. AGSO Journal of Australian Geology and Geophysics(17), 145-158.
Gurfinkel, Y., Lyubimov, V., Orayevskii, V., Parfenova, L., & Yur’ev, A. (1995). Effect of geomagnetic disturbances on capillary blood flow in patients suffering from ischaemic disease of the heart. Biophysics(40), 777-783.
Habash, R. (2008). Bioeffects and therapeutic applications of electromagnetic energy. Boca Raton: CRC Press.
Hacker G. W, A. C. (2012). Daytime related rhythmicity of GDV parameter glow image area: time course and comparison to biochemical parameters measures in saliva, Book chapter in Energy Fields Electrophotonic Analysis in Humans and Nature.
Hacker, G. P. (2005). Biomedical evidence of influence of geopathic zones on the human body: scientifically traceable effects and ways of harmonization. Forsch Komplementarmed Klass Naturheilkd(12), 315-327.
Hacker, G., Eder, A., Augner, C., & Pauser, G. (2008). Geopathic Stress Zones and Their Influence on the Human Organism. Proceedings of the Druskininskai congress on "Earth's Fields and their Influence on Human Beings", 21 pages.
Hacker, G., Pauser, G., & Augner, A. (2011). Geophysical Background, target structures and effects of geopathic stress zones, as detected with GDV methodology. In K. Konstantin, Spiral Traverse (pp. 315-348). Journey into the Unknown.
Hacker, W. G., Augner, C., & Pauser, G. (2012). Daytime related rhythmicity of GDV parameter glow image area: time course and comparison to biochemical parameters measures in saliva. In Energy Fields Electrophotonic Analysis in Humans and Nature.
Hainsworth, L. (1983). The Effect Of Geophysical Phenomena onHuman Health. Speculations in Science and Technology, 6(5):439-444.
Harisson, R., Heckscher, J., & Lewis, E. (1971). Helicopter observations of very low frequency radio waves over certain mountains and shore lies. Journal of atmospheric and terrestrial Physics, 33:106-116.
Hartmann, E. (1982). Krankheit als Standortproblem. Heidelberg, Germany: Haug.
Harvalik, Z. (1978). Anatomical localization of human detection of weak electromagnetic radiation: experiments with dowsers. Physiological Chemistry and Physics(10), 525-534.
Haynes, R. (1988). The distribution of domestic radon concentrations and lung cancer mortality in England and Wales. Radiation Protection Dosimetry(25), 93-96.
Hays, J. (1971). Faunal extinctions and reversals of the Earth’s magnetic field. Bulletin of the Geological Society of America(82), 2433-2447.
Heads, M. (1998). Biogeographic disjunction along the Alpine fault, New Zealand. Botanical Journal of the Linnean Society(63), 161-176.
Heads, M. (2008). Biological disjunction along the West Caledonian fault, New Caledonia: a synthesis of molecular phylogenetics and panbiogeography. Botanical Journal of the Linnean Society(158), 470-488.
Heiskanen, W., & Moritz, H. (1967). Physical Geodesy. San Francisco: W. H. Freeman and Company.
Henshaw, D. R. (1996). Enhanced deposition of radon daughter nuclei in the vicinity of power frequency electromagnetic fields. International Journal of Radiation Biology(69), 25-38.
Henshaw, D., Eatough, J., & Richardson, R. (1990). Radon as a causative factor in induction of myeloid leukaemia and other cancers. Lancet(335), 1008-1012.
Herbert L. Konigm, A. P. (1981). Biologic Effects of Environmental Electromagnetism. New York: Springer-Verlag New York Inc.
Heri, S. (2008). Handprint of Atlas. Corvos Books.
Hessler, P. V., & Wescott, M. E. (1959). Correlation between Earth-Current and Geomagnetic Disturbance. Nature(184), 627.
Hippocrates. (1992). Concerning nutrition (Περί Διαίτης). Odisseas Chatzopoulos.
Hodge, K., & Persinger, M. (1991). Quantitative increases in temporal lobe symptoms in human males are proportional to postnatal geomagnetic activity: verification by canonical correlation. Neuroscience Letters(125), 205-208.
Hough, R. (2007). Soil and human health: an epidemiological review. European Journal of Soil Science(58), 1200-1212.
Ji, L., Dickman, J., Kang, C., & Koenig, R. (2010). Exercise-Induced Hormesis May Help Healthy Aging. Dose Response, 8(1):73–79.
Joffe, R., Damasevicius, R., Landauskas, M., McCraty, R., & Vainoras, A. (2017). Local Earths magnetic field fluctuations interconnections with human physical wellbeing. Earths fields and their influence on organisms (pp. 72-75). Lithuani: Lithuanina Nature Society.
Johnston, M. (1997). Review of electric and magnetic fields accompanying seismic and volcanic activity. Surveys in Geophysics(18), 441-476.
Kalde, E. (2004). Productivity of potatoes and pathongens of potatoes in relation to natural environmental factors. Earths fields and their influence on organisms, 3-6.
Kalmijn, A. (1978). Experimental evidence of geomagnetic orientation in elasmobranch fishes. In K. Schmidt-Koenig, & W. Keeton, Animal Migration, Navigation, and Homing (pp. 347353). Berlin: Springer-Verlag.
Kamoi, K., Tanaka, M., Ikarashi, T., & Miyakoshi, M. (2006). Effect of the 2004 Mid Niigata Prefecture earthquake on glycemic control in type 1 diabetic patients. Diabetes Research and Clinical Practice(74), 141-147.
Kamoi, K., Tanaka, M., Ikarashi, T., & Miyakoshi, M. (2006b). Effect of the 2004 Mid Niigata Prefecture earthquake on patients with endocrine disorders. Endocrine Journal(53), 511-521.
Karakhanian, A., Trifonov, V., Ivanova, T., Avagyan, A., Rukieh, M., Minini, H.,. Bachmanov, D. (2008). Seismic deformation in the St. Simeon Monasteries (Qalat Siman), Northwestern Syria. Tectonophysics, 453:122–147.
Karampatzakis, P., & Zafranas, V. (2009). Did Hades accept visitors? The acoustic properties of the crypt at Acheron Necromanteion, Efira, Preveza, Greece" publication date publication description EAA Annual meeting. Riva del Grada, Italy.
Kario, K., McEwen, B., & Pickering, T. (2003). Disasters and the heart: a review of the effects of earthquake-induced stress on cardiovascular disease. Hypertension Research(26), 355-367.
Kasimov, N. K. (1978). Geochemistry of the soils of fault zones (exemplified by Kazakhstan). Soviet Soil Science(10), 397-406.
Kasimov, N., Kovin, M., Proskuryakov, Y., & Shmelkova, N. (1978). Geochemistry of the soils of fault zones (exemplified by Kazakhstan). Soviet Soil Science(10), 397-406.
Kerr, R. (1995). Quake Prediction Tool Gains Ground. Science, 270(5238), 911-912.
Kharat, A. (2000). Theoretical and Empirical Investigations on Built Environment. India: PhD thesis, Pune University.
King, C. Y., Zhang, W., & Zhang, Z. (2006). Earthquake-induced groundwater and gas changes. Pure and Applied Geophysics(163), 633-645.
King, C.-Y. Z. (2006). Earthquake-induced groundwater and gas changes. Pure and Applied Geophysics(163), 633-645.
King, C.-Y., King, B.-S., Evans, W. C., & Zhang, W. (1996). Spatial radon anomalies on active faults in California. Applied Geochemistry(11), 496-510.
Kirschvink, J. (2000). Earthquake prediction by animals: evolution and sensory perception. Bulletin of the Seismological Society of America(90), 312-323.
Kirschvink, J., & Gould, J. (1981). Biogenic magnetite as a basis for magnetic field detection in animals. Biosystems, 13(3):181-201.
Kirschvink, J., Jones, D., & MacFadden, B. (1985). Magnetite biomineralization and magnetoreception in organisms: A new biomagnetism. New York: Plenum Press.
Kirshivink, J. L., Kobayashi-Kirshivink, A., & Woodford, B. J. (1992). Magnetite Biomineralization in the Human Brain. Proceedings of the National Academy of Science(89), 7683-7687.
Koenig, C. (2005). Specialized hydro-, balneo- and medicinal bath therapy. Lincoln, NE.: iUniverse.
Komatina, M. (2004). Medical geology: Effects of geological environments on human health. Amsterdam, Netherlands: Elsevier.
Kopper, J., & Papamarinopoulos, S. (1978). Human evolution and geomagnetism. Journal of Field Archaeology(5), 443-452.
Kopytenko, Y. M. (1993). Detection of ultralow frequency emissions connected with the Spitak earthquake and its aftershock activity, based on geomagnetic pulsation data at Susheti and Vardzia observatories. Physics of the Earth and Planetary Interiors(77), 85-95.
Korhonen, J. F. (2007). Magnetic anomaly map of the world, scale 1 : 50,000,000. Paris, France: Commission for the Geological Map of the World.
Kositsky, N., Nizhelska, A., & Ponezha, G. (2001). Influence of high-frequency electromagnetic radiation at non-thermal intensities on the human body. No Place To Hide Newsletter of the Cellular Phone Taskforce Inc., 3(1), 1-33.
Kostov, R. I. (2008). Geoarchaeology and Archaeomineralogy. Geological And Mineralogical Background Of The Megalithic And Rock-Cut Sites In Bulgaria And Some Other European Countries (pp. 163-168). Sofia: Publishing House “St. Ivan Rilski”,.
Kostryukova, N., & Kostryukov, O. (2002). Local faults of the Earth’s crust – Factor of natural risk. Moscow, Russia: Mining Science Press.
Kravchenko, A. (2002). Spatial variability of soybean quality data as a function of field topography: I. Spatial data analysis. Crop Science, 42, 804–815.(42), 804-815.
Kruckeberg, A. (2004). Geology and plant life: The effects of landforms and rock types on plants. Seattle, WA: University of Washington Press.
Krueger, A. (1972). Are air ions biologically significant? A review of a controversial subject. Are air ions biologically significant? A review of a controversial subject. International Journal of Biometeorology, 16(4), 313-322.
Krueger, A., & Yamagucchi, F. (1983). Electrocultrure of tomato plants in a commercial hydroponic greenhouse. Journal of biological Physics, 11:5-10.
Kuritzky, A., Zoldan, Y., Hering, R., & Stoupel, E. (1987). Geomagnetic activity and the severity of the migraine attack. Headache(27), 87-89.
Kutinov, Y., & Chistova, Z. (2004). Hierarchical range of manifestation of alkaline and ultra-alkaline magmatism of the Arkhangelsk diamond province. Their manifestation in geological and geophysical data. Arkhangelsk, Russia: Pravda.
Kuznetsov, V., & Kuznetsova, N. (2004). Impact of the cosmic radiation and long-term variations of the geomagnetic field on the climate and life’s evolution on the Earth. In B. Shevtsov, Solar-terrestrial bonds and electromagnetic precursors of earthquakes: Proceedings of the 3rd International conference, Paratunka, Russia, Aug. 16–21, 2004, Vol. 2 (pp. 82–104). Petropavlovsk-Kamchatsky, Russia: Institute of Cosmophysical Research and Rad.
Låg, J. (1990). Geomedicine. Boca Raton, FL.: CRC Press.
Lai, S.-W., Liu, C.-S., Li, C.-I., Tan, C.-K., Ng, K.-C., Lai, M.-M., & Lin, C.-C. (2000). Post-earthquake illness and disease after the Chi-Chi earthquake. European Journal of Internal Medicine(11), 353-354.
Lakhovsky, G. (1935). The secret of life, electricity, radiation and your body. California U.S.A: The Noontide Press.
Langer, D. (2008,). A first consistent physical model of radiestesy? The sixteenth seminar of BDA. June
Langer, H. (1997). Das geophysikalische Standortproblem der Solitärbäume, Teil 1:Ergebnisse systematischer Naturbeobachtungen (The geophysical location problem of solitary trees, Part 1: Results of systematic observations of nature). Veröffentlichungen des Museums fur Naturkunde Chemnits.
Larter, R., & Ortoleva, P. (1981). A theoretical basis for self-electrophoresis. Journal of Theoretical Biology, 88(4):599-630.
Leask, M. (1978). A physicochemical mechanism for magnetic field detection by migratory birds and homing pigeons. Nature, 267:144-145.
Leitgeb, N. A. (2008). Should hospitals protect from geopathogenic zones? Wiener Medizinische Wochenschrift(158), 42-48.
Lenz, W. (1979). Radon: A factor in human evolution. M.A. Thesis. Stony Brook, NY: State University of New York at Stony Brook.
Leucht, T. (1987). Magnetic effects on tail-fin melanophores of Xenopus laevis tadpoles in vitro. Naturwissenschaften, 74:441-44.
Levengood, G. (1988). Redox responsive electrodes applied during plant morphogenesis. Bioelectrochemistry and Bioenergetic, 19;461-476.
Leventhall, G. P. (2003). A review of published research on low frequency noise and its effects. London UK: Department for Environment, Food and Rural Affairs.
Lewis-Williams, D., & Clottes, J. (2007). The mind in the cave – the cave in the mind: altered consciousness in the Upper Palaeolithic. Anthropology of Consciousness, 9(1):13–21.
Loay E.G., Bushra M.I. (2012). The Distribution of Non-Dipole Part of Earth's Magnetic Field. Asian Transactions on Basic and Applied Sciences. Volume 01 Issue 06
Lohmann K. J., Willows A. O., Pinter R. B. (1991). An identifiable molluscan neuron responds to change in earth strengh magnetic fields. Journal of Experimental Biology 1991 161: 1-24;
Lonetree, B., & Miller, I. (2013). The Sedona Effect: Correlations between Geomagnetic Anomalies, EEG Brainwaves & Schumann Resonance. Journal of Consciousness Exploration & Research, 4(6).
Long, M. (1991). Secrets of Animal navigation. National Geographic Magazine, 70-99.
Luckey, T. (1991). Radiation hormesis. Boca Raton, FL: CRC Press.
Lukina, N., Lyal’ko, V., Makarov, V., Skobolev, S., Spiridonov, K., Chekhtova, Y., & Chervenyashka, M. (1992). Preliminary results of a spectrometric study of the Faisabad test area (TianShan – Intercosmos 88 International Aerospace Experiment). Soviet Journal of Remote Sensing(9), 1022-1037.
Lumbers, S. (1967). Geology and mineral deposits of the Bancroft–Madoc area. In S. Jenness, Geology of parts of eastern Ontario and western Quebec (pp. 13-19). Kingston, ON: Geological Association of Canada.
Mackey, B. a. (2001). Towards a hierarchical framework for modelling the spatial distribution of animals. Journal of Biogeography(28), 1147-1166.
Macklis, R., & Beresford, B. (1999). Radiation hormesis. J Nucl Med., 32(2):350-9.
Malmivuo, J., & Plonsey, R. (1995). Bioelectromagnetism. principles and applications of bioelectric and biomagnetic fields. New York Oxford University Press.
Mamaev, S. (1973). Forms of intraspecific variability in ligneous plants. Moscow, USSR: Nauka.
Mamirova G. N. (2010). Bioindication of Geological Anomalies in Ecosystems. Republic of Kazakhstan City of Almaty: Dissertation of Biological Science.
Marinaga, M. (1992). Giving Personal Magnetism a whole new meaning. Science, 256, 967.
Marino, A. a. (1977). Biological effects of extremely low frequency electric and magnetic fields: a review. Physiological Chemistry and Physics(9), 131-147.
Mariolakos, I., Nikolopoulos, V., Bantekas, I., & Palyvos, N. (2010). Oracles on faults: a probable location of a ‘lost’ oracle of Apollo near Oroviai (northern Euboea island, Greece) viewed in its geological and geomorphological context. Bulletin of the Geological Society of Greece XLIII, 829-844.
Markov, M. (2007). Pulsed electromagnetic field therapy history, state of the art and future. Environmentalist(27), 465-475.
Markson, R., & Nelson, R. (1970). Mountain-Peak Potential-Gradient Measurements And The Andes Glow. Weather, 25, 350-360.
Martin III, J. R., Haupt, R. W., & J., G. R. (1982). The effect of fluid flow on the magnetic field in low porosity crystalline rock. Geophysical Research Letters, 9(12), 1301-1304.
Martínez, C. J. (2012). The Central Iberian arc, an orocline centered in the Iberian Massif and some implications for the Variscan belt. International Journal of Earth Sciences, 101(5):1299-1314.
Martynuk, V. (1995). Temporal organization of living organisms and the problem of the reproducibility of the results in magnetobiological research. Biophysics(40), 925-927.
Masironi, R. (1987). Geochemistry, soils and cardiovascular diseases. Experientia(43), 68-74.
Mathur, M. a. (1997). Desert Lung Syndrome, in rural dwellers of the Thar Desert, India. Journal of Arid Environments(35), 559-562.
Matsuoka, T., Yoshioka, T., Oda, J., Tanaka, H., Kuwagata, Y., Sugimoto, H., & Sugimoto, T. (2000). The impact of a catastrophic earthquake on morbidity rates for various illnesses. Public Health(114), 249-253.
Mattson, M., & Calabrese, E. (2010). Hormesis: Once Marginalized, Evidence Now. Department of Environmental Health Sciences, School of Public Health and Health Sciences,. MA, USA: Springer Science+Business Media2010.
Mattson, M., & Wan, R. (2005). Beneficial effects of intermittent fasting and caloric restriction on the cardiovascular and cerebrovascular systems. J Nutr Biochem, 16(3):129-37.
McCraty. (2014). The Global Coherence Initiative: Investigating the Dynamic Relationship Between People and Earth’s Energetic Systems.
McCraty, R. (2003). The Energetic Heart: Biolectromagnetic Interactions within and between people. Heartmath research center, (6):022-043.
McKay, B., & Persinger, M. (2005). Complex magnetic fields enable static magnetic field cue use for rats in radial maze tasks. International Journal of Neuroscience(115), 625-648.
Melnikov, E. (2003). Influence of geological heterogeneities on the health of population of Saint Petersburg and Leningrad Region. In A. L. Shurygin, Geologists for the 300th year anniversary of Saint Petersburg (pp. 164-177). Sain Petersburg, Russia: Pangea.
Melnikov, E., & Rudnik, V. (1998). Geoactive zones and their influence on human health. Razvedka i Okhrana Nedr(7/8), 54-57.
Melnikov, E., & Rudnik, V. (2010). Pathogenic effect of fault zones in the urban environment. In I. Florisnky, Man and the Geosphere.
Melnikov, E., Musiychuk, Y., Potiforov, A., Rudnik, V., & Rymarev, V. (1993). Geopathogenic zones – Myth or reality? Saint Petersburg, Russia: All-Russian Scientific Research Institute “Oceangeologia” (in Russian, with English abstract).
Melnikov, E., Rudnik, V., Musiychuk, Y., & Rymarev, V. (1994). Pathogenic influence of active fault zones in Saint Petersburg area. Geoecologia(4), 50-69.
Mereaux, P. (1992). Des pierres pour les vivantes. Nature et Bretagne.
Merrill, R. M. (1998). The magnetic field of the Earth: Paleomagnetism, the core, and the deep mantle (2nd ed.). London UK: Academic Press.
Meyl, J. (2012). Task of the introns, cell communication explained by field physics. Cell Commun. Signal.
Meyl, K. (2003). Scalar waves. Indel, Verlag-Abt.
Michon, A., & Persinger, M. (1997). Experimental simulation of the effects of increased geomagnetic activity upon nocturnal seizures in epileptic rats. Neuroscience Letters(224), 53-56.
Mifune, M., Sobue, T., Arimoto, H., Komoto, Y., Kondo, S., & Tanooka, H. (1992). Cancermortality survey in a spa area (Misasa, Japan) with a high radon background. Cancer Science, 83:1–5.
Mikulecký, M. (2007). Solar activity, revolutions and cultural prime in the history of mankind. Neuroendocrinology Letters(28), 749-756.
Mikulecky, M., Moravcikova, G., & Czanner, S. (1996). Lunisolar tidal waves, geomagnetic activity and epilepsy in the light of multivariate coherence. Brazilian Journal of Medical and Biological Research(29), 1069-1072.
Miller. (2013). The Sedona Effect: Correlations between Geomagnetic Anomalies, EEG Brainwaves & Schumann Resonance. Journal of Consciousness Exploration adn Research.
Miroschnik. (2013). Research of Interaction of Background Geo-Magnetic Radiation with Architectural Forms. World Applied Sciences Journal. 27 (2): 216-223
Miroshnichenko, V. (1958). Disjunctive expressions of recent tectonic motions in the southwest Turkmenistan and their investigations by air methods. Trudy Laboratorii Aerometodov(6), 3-21.
Mitchel, J. (2001). View Over Atlantis. Thames & Hudson.
Mizutani, H., Ishido, T., Yokokura, T., & Ohnishi, S. (1976). Electrokinetic Phenomena Associated with Earthquakes. Geophysical Research Letters, 3(7):365-369.
Mo, W., Liu, Y., Cooper, H. M., & He, R. (2011). Development of Xenopus Embryos in a Hypogeomagnetic Field. Bioelectromagnetics. Apr;33(3):238-46
Molchanov, O. (2011). Underlying mechanism of precursory activity from analysis of upward earthquake migration. Natural Hazards Earth Sys, 11:135-143.
Mulligan, B. P., Cloes, L. S., Mach, Q. H., & Persinger, M. (2011). Geopsychology : Geophysical Matrix And Human Behavior. In I. Florisnky, Man and the Geosphere.
Mulligan, S., & Persinger, M. (1998). Perinatal exposures to rotating magnetic fields ‘demasculinize’ neuronal density in the medial preoptic nucleus of male rats. Neuroscience Letters(253), 29-32.
Myalo, E. A. (1972). Peculiarities in manifestation of groundwater discharge connected with faults. zvestiya Akademii Nauk, Series Geographical(5), 81-86.
Nambi, K., & Soman, S. (1987). Environmental radiation and cancer in India. Health Physics(52), 653-657.
Nash, G., Moore, J., & Sperry, T. (2003). Vegetal-spectral anomaly detection at the Cove FortSulphurdale thermal anomaly, Utah, USA: implications for use in geothermal exploration. Geothermics(32), 109-130.
Negri, S., & Leucci, G. (2006). Geophysical investigation of the Temple of Apollo (Hierapolis, Turkey). Journal of Archaeological Science(33), 1505-1513.
Neruchev, S. (1976). Effects of radioactive epochs on the evolution of the biosphere. Soviet Geology and Geophysics(17), 1-9.
Neruchev, S. (2007). Uranium and life in the history of the Earth (2nd ed.). Saint Petersburg, Russia: All-Russian Oil Research Prospecting Institute.
Novitskii, Y. I. (1966). Effects of a magnetic field on the dry seeds of some cereals. Proceedings of conference on the efrfect of magnetic fuields on biological objets (p. 52). Moscow: Verlag Moos and Partner Munchen.
O’Connor, R., & Persinger, M. (1997). Geophysical variables and behavior: LXXXII. A strong association between sudden infant death syndrome and increments of global geomagnetic activity– possible support for the melatonin hypothesis. Perceptual and Motor Skillis, 84:395-402.
Olcese, J., Reuss, S., & Vollrath, L. (1985). Evidence for the involvement of the visual system in mediating magnetic field effects on pineal melatonin synthesis in the rat. Brain Research, 2(333):382-384.
Olson, A., & Lewis, G. (1928). Natural radioactivity and the origin of species. Nature(121), 673-674.
Orbera L., Ramirez R. (2003) Caracteristicas geobiologica de algunos centros medicos y locales de Cuba. Memorias Geomin. I taller internacional sobre geobiología y radiestesia. 2003, La Habana, 24-28 March
Oschman, J. (2000). Energy Medicine, the scientific basis. Churchill Livingstone.
Osika, D. (1981). The fluid regime of the seismically active regions. Moscow, USSR: Nauka.
Osipov, V. (1994). Geological hazard zones in Moscow. Vestnik Rossiiskoi Academii Nauk(64), 32-45.
Ossenkopp, K.-P., & Nobrega, J. (1979). Significant relationship between perinatal geomagnetic field activity and anxiety levels in females. Archives für Meteorologie, Geophysik und Bioklimatologie, Series B(27), 75-90.
Ottani, V., De Pasquale, V., Govoni, P., Franchi, M., Zaniol, P., & Ruggeri, A. (1988). Effects of pulsed extremely-low frequency magnetic fields on skin wounds in the rat. Bioelectromagnetics, 9:53– 62.
Palmer, S. R., Rycroft M. J., Cermack M. (2016). Solar and geomagnetic activity, extremely low frequency magnetic and electric fields and human health at the Earth’s surface. Surveys in Geophysics(27), 557-595.
Parati, G., Antonicelli, R., Guazzarotti, F., Paciaroni, E., & Mancia, G. (2001). Cardiovascular effects of an earthquake: direct evidence by ambulatory blood pressure monitoring. Hypertension(38), 1093-1095.
Parish, L., & Lotti, T. (1996). Balneology and the spa: the use of water in dermatology. Clinics in Dermatology(14), 547-692.
Parkhomenko, E. a. (1975). Phenomena of electrification and luminescence of minerals during their deformation and destruction. In M. Sadovskiy, Physics of earthquake focus (pp. 151159). Moscow, USSR: Nauka.
Peeters, E.-G. (1987). The possible influence of the components of the soil and the lithosphere on the development and growth of neoplasms. Experientia(43), 74-81.
Pennock, D. W. (2001). Topographically controlled yield response of canola to nitrogen fertilizer. Soil Science Society of America Journal(65), 1838-1845.
Persinger, M. (2014). Infrasound, human health, and adaptation: an integrative overview of recondite hazards in a complex environment. Nat Hazards.
Persinger, A., & Psych, C. (1995). Sudden unexpected death in epileptics following sudden, intense, increases in geomagnetic activity: prevalence of effect and potential mechanisms. International Journal of Biometerology, 180.
Persinger, M. (1971). Prenatal exposure to an ELF rotating magnetic field, ambulatory behavior, and lunar distance at birth: a correlation. Psychological Reports(28), 435-438.
Persinger, M. (1976). Transient geophysical bases for ostensible UFO-related phenomena and associated verbal behavior. Perceptual and Motor Skills(43), 215-221.
Persinger, M. (1980). Earthquake activity and antecedent UFO report numbers. Perceptual and Motor Skills(50), 791-797.
Persinger, M. (1983). Geophysical variables and behavior: IX. Expected clinical consequences of close proximity to UFO-related luminosities. Perceptual and Motor Skills(56), 259-265.
Persinger, M. (1983b). Religious and mystical experiences as artifacts of temporal lobe function: a general hypothesis. Perceptual and Motor Skills(57), 1255-1262.
Persinger, M. (1984). Geophysical variables and behavior: XVIII. Expected perceptual characteristics and local distributions of close UFO reports. Perceptual and Motor Skills(58), 951-959.
Persinger, M. (1987). Geopsychology and geopsychopathology: mental processes and disorders associated with geochemical and geophysical factors. Experientia(43), 92-104.
Persinger, M. (1988). Geophysical variables and behavior: LIII. Epidemiological considerations for incidence of cancer and depression in areas of frequent UFO reports. Perceptual and Motor Skills(67), 799-803.
Persinger, M. (1995). Sudden unexpected death in epileptics following sudden, intense increases in geomagnetic activity: prevalence of effect and potential mechanisms. International Journal of Biometeorology(38), 180-187.
Persinger, M. (2001). The neuropsychiatry of paranormal experiences. Journal of Neuropsychiatry and Clinical Neuroscience(13), 515-524.
Persinger, M. (2008). On the possible representation of the electromagnetic equivalents of all adult memory within the Earth’s magnetic field: implications for theoretical biology. Theoretical Biology Insights(1), 3-11.
Persinger, M. (1985). Geophysical variables and behavior: XXXII. Evaluation of UFO reports in an area of infrequent seismicity: the Carman, Manitoba episode. Perceptual and Motor Skills(61), 807-813.
Persinger, M. (1990). Geophysical variables and behavior: LXII. Temporal coupling of UFO reports and seismic energy release within the Rio Grande Rift System: discriminative validity of the tectonic strain theory. Perceptual and Motor Skills(71), 567-572.
Persinger, M., & Janes, J. (1975). Significant correlations between human anxiety scores and perinatal geomagnetic activity. International Journal of Biometeorology(19), 126.
Persinger, M., & Richards, P. (1995). Vestibular experiences of humans during brief periods of partial sensory deprivation are enhanced when daily geomagnetic activity exceeds 15–20 nT. Neuroscience Letters(194), 69-72.
Persinger, M., Lafreniere, F., & Dotta, T. B. (2012). Marked Increases in Background Photon Emissions in Sudbury Ontario More than One Week before the Magnitude > 8.0 Earthquakes in Japan and Chile. International Journal of Geosciences, 627-629.
Persinger, M., Ludwig, H., & Ossenkopp, K.-P. (1973). Psychophysiological effects of extremely low frequency electromagnetic fields: a review. Perceptual and Motor Skills(36), 1131-1159.
Piccardi, L. (2000). Active faulting at Delphi, Greece: seismotectonic remarks and a hypothesis for the geologic environment of a myth. Geology(28), 651-654.
Piccardi, L. (2007). The AD 60 Denizli Basin earthquake and, G. the apparition of Archangel Michael at Colossae (Aegean Turkey). In L. Piccardi, & B. Masse, Myth and Geology (pp. 273:95-105). Special Publication of the Geological Society.
Planel, H., Soleilhavoup, J., Tixador, R., Richoilley, G., Conter, A., Croute, F., Gaubin, Y. (1987). Influence on cell proliferation of background radiation or exposure to very low, chronic gamma radiation. Health Physics(52), 571-578.
Planel, H., Soleilhavoup, J.-P., Cottin, F., Tixador, R., & Richoilley, G. (1969). Recherches sur l’action biologique de l’irradiation naturelle: étude de la croissance de Paramecium aurelia et Paramecium caudatum en laboratoire souterrain. Comptes Rendus Hebdomadaires des Seances de lAcadémie des Sciences, Série D(269), 1697-1700.
Plumlee, G., Morman, S., & Ziegler, T. (2006). The toxicological geochemistry of earth materials: an overview of processes and the interdisciplinary methods used to understand them. Reviews in Mineralogy and Geochemistry(64), 5-57.
Polimenakos, L. (1996). Thoughts on the perception of the earthquake in Greek antiquity. In S. J. Stiros, Archaeoseismology. (pp. 253-257). British School of Athens Occasional Paper.
Powell, J. R., & Finkelstein, D. (1970). Ball Lightning: Less well known than stroke lightning, ball lightning is about as frequent and can be simulated in the laboratory. American Scientist, 58, 272.
Prato, F., Robertson, J., Desjardins, D., Hensel, J., & Thomas, A. (2005). Daily repeated magnetic field shielding induces analgesia in CD-1 mice. Bioelectromagnetics(26), 109-117.
Presman, A. (1970). Electromagnetic Fields and Life. New York, London: Plenum Press.
Ptitsyna, N., Villoresi, G., Tyasto, M., Iucci, N., & Dorman, L. (1995). Possible effect of geomagnetic disturbances on the incidence of traffic accidents (St. Petersburg 1987–1989). Physica Medica(11), 91-101.
Pulinets, S. D. (2004). Ionospheric precursors of earthquakes and Global Electric Circuit. Advances in Space Research. doi:http://dx.doi.org/10.1016/j.asr.2013.12.035
Quindós, P., Fernández, P., Gómez, A. J., Sainz, C., Fernández, J., Suarez, M. E.,. Cascón, M. (2004). Natural Gamma radiation map (MARNA) and indoor radon levels in Spain. Environmental International, 29(8):1091-1096.
Radak, Z., Chung, H., & Goto, S. (2005). Exercise and hormesis: oxidative stress-related adaptation for successful aging. Biogerontology, 6(1):71-5.
Radak, Z., Chung, H., Koltai, E., Taylor, A., & Goto, S. (2008). Exercise, oxidative stress and hormesis. Ageing Res Rev. Jan., 7(1):34-42.
Radin, D. (1991). Studied mental influences of background radiation. Frontier Perspectives.
Raevskaya, O. (1988). Geomagnetic field and the human organism. Uspekhi Fiziologicheskikh Nauk(4), 91-108.
Raevskaya, O. (1988). Geomagnetic field and the human organism. Uspekhi Fiziologicheskikh Nauk(4), 91-108.
Rahnama, M., Tuszynski, J., & Bόkkon, I. (2011). Emmiusion of mitrochondrial biophotons and their effect on electrical activity of membrane via, microtubules. Journal of Integrative Medicine, Neurosci., 10(1), 65-68.
Raibshtein, V., Kudryashev, V., Tarasov, S., & Chepasov, V. (1995). Role of tidal variations of the force of gravity in the regulation of the systems response of blood circulation and respiration to orthostasis. Biophysics(40), 791-798.
Rajaram, M., & Mitra, S. (1981). Correlation between convulsive seizure and geomagnetic activity. Neuroscience Letters(24), 187-191.
Raukas, K. J. (2012). Radon emissions and their influence to the organisms. Lituania conference.
Reiter, R. (2003). Melatonin: clinical relevance. Best Practice and Research Clinical Endocrinology and Metabolism June, 17(2):273-85.
Research, G. (2014). A quantum model about coherence to understand the mechanisms generating biological effects caused by man-made non-ionizing radiation.
Richards, P., Persinger, M., & Koren, S. (1996). Modification Of Semantic Memory In Normal Subjects By Application Across The Temporal Lobes Of A Weak (1 Microt) Magnetic Field Structure That Promotes Long-Term Potentiation In Hippocampal Slices. Electr and Magnetobiologu, 15(2):141-148.
Rikitake, T., & Honkura, Y. (1986). Solid Earth Geomagnetism. Tokyo: Scientific Publishing.
Ringrose, S., Vanderpost, C., & Matheson, W. (1998). Evaluation of vegetative criteria for nearsurface groundwater detection using multispectral mapping and GIS techniques in semiarid Botswana. Applied Geography(18), 331-354.
Robins, D. (1985). Circles of Silence. Souvenir Press Ltd.
Rocard, Y. (1964). Actions of a very weak magnetic gradient: the reflex of the dowser. In I. M. Barnothy, Biological effects of magnetic fields, Vol. 1 (pp. 279-286). New York: Plenum Press.
Romanova, E. M. (1983). Microclimatology and its importance for agriculture. Leningrad, USSR: Hydrometeoizdat.
Roney-Dougal, S. M., & Vogl, G. (1993). Some Speculations on the effect of Geomagnetism on the Pineal Gland. Journal of the Society for Psychical Research, 59(830), 1-15.
Rosenblum, B., Jungerman, R., & Longfellow, L. (1985). Limits to induction-based magnetoreception. In J. Kirschvink, D. Jones, & B. MacFadden, Magnetite Biomineralizalion and Magnetoreception in Organisms: A New Biomagnetism (pp. 223232). New York: Plenum Press.
Rudakov, Y., Mansurov, S., Mansurova, L., Portnov, A., Polishchuk, Y., & Mazursky, M. (1984). Role of sector structure of the interplanetary magnetic field in synchronization of psychophysiological regulation of the human organism. In N. Krasnogorskaya, Electromagnetic fields in the biosphere, Vol. 1 (pp. 150-159). Moscow, USSR: Nauka.
Rudnik, V. (2002). Mineral substance as a key factor of geological influence on human and environment. In V. Kuzmin, Role of mineralogical research in studies of ecological problems (theory, practice, and outlook): Proceedings of the Annual meeting of the Russian mineralogical society (pp. 170-173). Moscow, Russia: Federovsky All-Russian Research Institute of Mineral Resources Press.
Rudnik, V., & Melnikov, E. (2010). Pathogenic effect of fault zones in the urban environment. In I. Florinsky, Man and the Geosphere. (pp. 169-183). New York: Nova Science Publishers.
Ruttan, L. A., Persinger, M. A., & Koren, S. (1990). Enhancement of Temporal Lobe-Related Experiences During Brief Exposures to Milligaus Intensity Extremely Low Intensity Magnetic Fields. Journal of Bioelectricity, 9(1), 33-54.
Ryan A. (2008). New Insights into the Links between ESP and Geomagnetic Activity. Journal of Scientific Exploration.
Sadovskiy, M. S. (1979). Variations of the natural radiowave emission of the Earth during a severe earthquake in the Carpathians. Doklady, Earth Sciences Sections(244), 4-6.
Safwat, A. (2008). Clinical applications of low-dose whole body irradiation hormesis. In E. L. Rattan, Mild stress and healthy aging: Applying hormesis in aging research and interventions (pp. 157-170). Amsterdam, Netherlands: Springer.
Scherrer, P. (2000). Ephesus—The New Guide. Ege Yayinlari.
Schulten, K., & Windemuth, A. (1986). Model for a physiological magnetic compass. In G. Maret, N. Boccara, & J. Kiepenheuer, Biophysical Effects of Steady Magnetic Fields (pp. 99-106). Berlin: Springer-Verlag.
Selinus, O., Alloway, B., Centeno, J., Finkelman, R., Fuge, R., Lindh, U., & Smedley, P. (2005). Essentials of medical geology: Impacts of the natural environment on public health. Amsterdam, Netherlands: Elsevier.
Shitov, A. (2012). Changes in the Effect of Geological Factors on the Health of the Population during Geodynamical Activation. Izvestya, Atmospheric and Oceanic Physics.
Shitov, A. (2006). Ecological consequences of activization of geodynamic processes in the Mountain Altai. Vestnik Tomskogo Universiteta, Bulletin Operativnoi Nauchnoi Informatsii(72), 118-135.
Shitov, A. (2010). Health of people living in a seismically active region. In I. Florinsky, Chapter 7, Man and the geosphere. New York: Nova Science Publishers.
Shitov, A. (2010b). Intraspecific variability of plants: the impact of active local faults. In I. Florisnky, Man and the Geosphere.
Si, B. C, Farrell, R.E. (2004). Scale-dependent relationship between wheat yield and topographic indices: a wavelet approach. Soil Science Society of America Journal(68), 577-587.
Similox-Tohon, D., Sintubin, M., Muchez, P., Verhaert, G., Vanneste, K., Fernandez-Alonso, M., Waelkens, M. (2006). The identification of an active fault by a multidisciplinary study at the archaeological site of Sagalassos (SW Turkey). Tectonophysics, 420:371-387.
Simonenko, T. (1968). Manifestation of fault zones of the Earth’s crust in the magnetic field. Geophysical Communications(26), 5-12.
Simpson, J. (1966). Evolutionary pulsations and geomagnetic polarity. Bulletin of the Geological Society of America(77), 197-204.
Sintubin, M., Muchez, P., Similox-Tohon, D., Verhaert, G., Paulissen, E., & Waelkens, M. (2003). Seismic catastrophes at the ancient city of Sagalassos (SW Turkey) and their implications for the seismotectonics in the Burdur-Isparta area. Geological Journal, 38:359-374.
Skinner, H. (2007). The Earth, source of health and hazards: an introduction to medical geology. Annual Review of Earth and Planetary Sciences(35), 177-213.
Skvortsov, A. (1991). Brief analysis of the association between cities and tectonics on the Russian Platform. In S. P. Melnikova, Modeling of processes of ecological development (pp. 30-35). Moscow, USSR: All-Union Scientific Research Institute of System Investigations.
Sliaupa, S. (2017). Does the background magnetic and gravity fields have an impact on the human health. Earths fields and their influence on organisms (pp. 77-79). Birstonas, Lithuania: Lithuaninan Nature Society.
Sliaupa, S., Zukauskas, G., Korabliova, L., Denas, Z., Zakarevicius, A., & Davidoniene, O. (2004). Impact of some geological factors on human health. Earths Fields and their influence on organisms. Tamosava, Lithuania: Lithuanina Nature Sociedty.
Sobolev, G. B. (1975). Study of mechanoelectrical phenomena in a seismoactive region. In M. Sadovskiy, Physics of earthquake focus (pp. 184-223). Moscow, USSR: Nauka.
Sobotovich, E. V., Florinsky, V. I., & Lysenko, O. B. (2010). Role of isotopes in the biosphere. In I. Florisnky, Man and the Geosphere.
Soter, S. (1993). Macroscopic seismic anomalies and submarine pockmarks in the Corinth–Patras rift, Greece. Tectonophysics, 308(1):275–290.
Stacey, F. (1964). The seismomagnetic effect. Pure and Applied Geophysics(58), 5-22.
Stavitsky, R. (1999). Blood as indicator of the state of organism and its systems. Moscow, Russia: MNPI.
Stewart, I. (1996). Holocene uplift and palaeoseismicity on the Eliki Fault western Gulf of Corinth, Greece. Annali di Geofisica, 39:575–588.
Stewart, I., & Piccardi, L. (2017). Seismic faults and sacred sanctuaries in Aegean antiquity. Proceedings of the Geologists’ Association, 128:711–721.
Stewart, I., & Vita-Finzi, C. (1996). Coastal uplift on active normal faults: the Eliki Fault, Greece. Geophysical Research Letters, 23:1853–1856.
St-Laurent, F., Derr, J., & Freund, F. (2006). Earthquake lights and the stress-activation of positive hole charge carriers in rocks. Physics and Chemistry of the Earth, A/B/C(31), 305-312.
Stoupel, E. (1999). Effect of geomagnetic activity on cardiovascular parameters. Journal of Clinical and Basic Cardiology 1999; 2 (1), 34-40, 34-40.
Stoupel, E. (2002). The effect of geomagnetic activity on cardiovascular parameters. Biomedicine and Pharmacotherapy(27), 247-256.
Stoupel, E., Abramson, E., Gabbay, U., & Pick, A. (1995). Relationship between immunoglobulin levels and extremes of solar activity. International Journal of Biometeorology(38), 89-91.
Stoupel, E., Frimer, H., Appelman, Z., Ben-Neriah, Z., Dar, H., Fejgin, M., Shohat, M. (2005). Chromosome aberration and envi-ronment physical activity: Down syndrome and solar and cosmic ray activity, Israel. International Journal Biometeorology, 50:1-25.
Stoupel, E., Kalediene, R., Petrauskiene, J., Domarkiene, S., Radishauskas, R., Abramson, E., Sulkes, J. (2004). Three Kinds of Cosmophysical Activity: Links to Temporal Distribution of Deaths and Occurrence of Acute Myocardial Infarction. Med. Sci. Monit., 10:80-84.
Stoupel, E., Martfel, J., & Rotenberg, Z. (1991). Admissions of patients with epileptic seizures (E) and dizziness (D) related to geomagnetic and solar activity levels: differences in female and male patients. Medical Hypotheses(36), 384-388.
Subrahmanyan, S., Narayan, P., & Srinivasan, T. (1985). Effect of magnetic micropulsations on the Biological Systems- a Bioenvironmental study. International Journal of Biometerology, 29(3), 293-305.
Suess, L., & Persinger, M. (2001). Geophysical variables and behavior. XCVI: “Experiences” attributed to Christ and Mary at Marmora, Ontario, Canada may have been consequences of environmental electromagnetic stimulation: implications for religious movements. Perceptual and Motor Skills(93), 435-450.
Sytinskii, А. (1997). Planetary atmospheric disturbances during strong earthquakes. Geomagnetism and Aeronomy(37), 256-259.
Takakura, R., Himeno, S., Kanayama, Y., Sonoda, T., Kiriyama, K., Furubayashi, T.,. Iwao, N. (1997). Follow-up after the Hanshin-Awaji earthquake: diverse influences on pneumonia, bronchial asthma, peptic ulcer and diabetes mellitus. Internal Medicine(36), 87-91.
Tchijevsky, A. (1929). L’aéroionothérapie des maladies pulmonaires. Recherches expérimentales de l’effet de l’air ionisé sur la tuberculose des poumons, la pneumonie et la bronchite. La Presse Thermale et Climatique(70), 653-665.
Tchijevsky, A. (1938). Les épidemies et les perturbations électromagnetiques du milieu exterieur. Paris, Frabce: Hippocrate. Tennant, J. (2013). Healing is voltage. Polland: Amazon. Thompson, W. (1872). Reprints of papers on Electrostatics and Magnetism. Macmillan, London. Tofani, S., Barone, D., Cintorino, M., De Santi, M., Ferrara, A., R., O., Ronchetto, F. (2001). Static and ELF magnetic fields induce tumor growth inhibition and apoptosis. Bioelectromagnetics, 22:419–428. Tofani, S., Cintorino, M., Barone, D., Berardelli, M., De Santi, M., Ferrara, A., Tosi, P. (2002). Increased mouse survival, tumor grouth inhibition and decreased immunoreactive P53 after exposure to magnetic fields. Bioelectromagnetics, 23:230-238. Travkin, M., & Kolesnikov, A. (1972). About the influence of the anomalous magnetic field on morbidity rate in the Kursk Magnetic Anomaly area. In Sanitary assessment of magnetic fields: Proceedings of the symposium. Moscow, USSR: Soviet Academic Press. Trifonov, V. a. (2004). Active faulting and human environment. Tectonophysics(380), 287-294. Trifonov, V. a. (2004b). Geodynamics and the history of civilization. Moscow, Russia: Nauka. Trifonov, V., & Karakhanian, A. (2004). Geodynamics and the history of civilization. Moscow, Russia: Nauka. Trivieri L., Anderson J. (2002). Alternative Medicine: The Definitive Guide. Celestial Arts Trofimov, V. (2000). Ecological functions of the lithosphere. Moscow, Russia: Moscow University Press. Tsarfis, P. (1985). Nature and health: Treatment and rehabilitation by natural factors. Moscow, USSR: Mir Publishers. Turturro, A., Hass, B., & Hart, R. (1998). Hormesis-Implications for risk assessment caloric intake (body weight) as an exemplar. Human & Experimental Toxicology, 17(8):454–459. Tyasto, M., Ptitsyna, N., Kopytenko, Y., Voronov, P., Kopytenko, Y., Villoresi, G., & Iucci, N. (1995). Influence of man-made and natural electromagnetic fields on the incidence of different pathologies in St Petersburg. Biophysics(40), 829-837. Uffen, R. (1963). Influence of the Earth’s core on the origin and evolution of life. Nature(198), 143-144. UNSCEAR (1993). Sources And Effects Of Ionizing Radiation United Nations Scientific Committee on the Effects of Atomic Radiation UNSCEAR 1993 Report to the General Assembly. UNSCEAR (2000). Combined effects of radiation and other agents. In United Nations Scientific Committee on the Effects of Atomic Radiation, Sources and effects of ionizing radiation: UNSCEAR 2000 report to the General Assembly, with scientific annexes, Vol. 2: Effects. New York: United Nations.
UNSCEAR (2001). Hereditary effects of radiation: UNSCEAR 2001 report to the General Assembly, with scientific annex. New York, NY: United Nations.
UNSCEAR (2008). Effects of ionizing radiation: UNSCEAR 2006 report to the General Assembly, with scientific annexes. New York, NY: United Nations.
Vaitl, D., Propson, N., Stark, R., Walter, B., & Schienle, A. (2001). Headache and sferics. Headache(41), 845-853.
Valdmanis, D. (2012). Manifestations of biophysicals anomalies in forest. Earths fields and theri influence on organisms, Lithuania
Valkovic, V. (1977). A possible mechanism for the influence of geomagnetic field on the evolution of life. Origins of Life(8), 7-11.
Vavilov, N. (1926). Studies on the origin of cultivated plants. Bulletin of Applied Botany and Plant Breeding, 16(2), 1-248.
Vavilov, N. (1992). Origin and geography of cultivated plants. Cambridge, UK: Cambridge University Press.
Verginadis. (2012). Analgesic effect of the electromagnetic resonant frequencies derived from the NMR spectrum of morphine. Electromagnetic Biology and Medicine.
Verginadis I., Simos Y.V, Velalopoulou A.P, Vadalouca A.N, Kalfakakou V.P, Karkabounas S.Ch, Evangelou A.M. (2012). Analgesic effect of the electromagnetic resonant frequencies derived from the NMR spectrum of morphine. Electromagnetic biology and medicine, 1-10.
Vinogradov, A. (1983). Biogeochemical provinces and endemies. Comptes Rendus de l’Académie des Sciences de l’URSS(18), 283-286.
Vinogradov, B. (1955). Examples of relationships between vegetation, soils, and neotectonics. Journal Botanique de l'URSS(40), 837-844.
Vladimirskii, B., & Kislovskii, L. (1995). Cosmophysical periods in European history. Biophysics(40), 849-852.
Vogt, J., Sinnhuber, M., & Kallenrode, M.-B. (2009). Effects of geomagnetic variations on System Earth. In H. S. K.-H. Glaβmeier, Geomagnetic field variations (pp. 159-208). Berlin, Germany: Springer.
Volchek, O. (1995). Influence of the cyclicity of the environment on the manifestations of functional asymmetry of the human brain. Biophysics(40), 1015-1022.
Volfson, I., Wolfgang, P., & Pechenkin, I. (2010). Geochemical Anomalies: Sickness And Health. In I. Florisnky, Man and the Geosphere.
Von Pohl, F. G. (1983). Earth Currents as Pathogenic Agents for Illness and the Development of Cancer,. Freich Verlag, Feucht (out of print).
Vorobiev, А. (1974). Physical conditions for setting of the deep substance and seismic events. Tomsk, USSR: Tomsk University Press.
Vorobiev, А. S. (1979). Abnormal change of intensity of a natural impulse electromagnetic field in the Tashkent region before earthquake. Uzbeksky Geologichesky Journal(5), 11-15.
Voronkov, E., Shitov, A., Velilyaeva, E., & Voronkova, E. (2006). Study of vegetative and emotional parameters of the human organism during visits to tectonic faults and the Scythian ritual mound in the Mountain Altai. Vestnik Tomskogo universiteta, Bulletin Operativnoi Nauchnoi Informatsii(117), 20-32.
Vorontsov, N., & Lyapunova, E. (1984). Explosive chromosomal speciation in seismic active region. Chromosomes Today(8), 289-294.
Walach, H., Betz, H.-D., & Schweickhardt, A. (2001). Sferics and headache: a prospective study. Cephalalgia(21), 685-690.
Wang J.H., Cain S.D., Lohmann K.J. (2004). Identifiable neurons inhibited by Earth-strength magnetic stimuli in the mollusc Tritonia diomedea. The Journal of Experimental Biology. Feb;207(Pt 6):1043-9.
Warman, V., Dijk, D.-J., W. G., Arendt, J., & Skene, D. (2003). Phase advancing human circadian rhythms with short wavelength light. Neuroscience Letters, 342;37–40.
Watanabe, Y., Cornélissen, G., Halberg, F., Otsuka, K., & Ohkawa, S.-I. (2000). Associations by signatures and coherences between the human circulation and helio- and geomagnetic activity. Biomedicine & Pharmacotherapy Volume 55, Supplement 1, 11 November, Pages s76-s83, 55:Suplement11(11):76-83.
Watkins, N., & Goodell, H. (1967). Geomagnetic polarity change and faunal extinction in the Southern Ocean. Science(156), 1083-1087.
Watson, L. (1974). Supernature. Coronet Books.
Watson, N., Doherty, M., Dodrill, C., Farrell, D., & Miller, J. (2002). The experience of earthquakes by patients with epileptic and psychogenic nonepileptic seizures. Epilepsia(43), 317-320.
Weinberg, E. (1987). The influence of soil on infectious disease. Experientia(43), 92-104.
Weiss, S. M. (1988). Sun, slope, and butterflies: topographic determinants of habitat quality for Euphydryas editha. Ecology(69), 1486-1496.
Weydahl, A., Sothern, R., Cornélissen, G., & Wetterberg, L. (2001). Geomagnetic activity influences the melatonin secretion at latitude 70º N. Biomed. Pharmacother, 5:57-62.
Wheaton, F. (1968). Effects of various electrical fields on seed germination. Retrospective Theses and Dissertations. Paper 3521.
White, J. (1999). Sweet corn seed enhancement increases early plant fresh and dry weights and yield. Proc. Fla. State Hort. Soc., 112.
Williams, E. (1992). The Schumann Resonance: A Global Tropical Thermometer. Science, 256(5060):1184-1187.
Wool, F. (1976). “Moon rhythms” in the development of an epileptic process. Journal Neuropatologii i Psychiatrii Imeni S.S. Korsakova, 76:1875–1879.
Yakovleva, M. (1973). Physiological mechanisms of the action of electromagnetic fields. Leningrad, USSR: Medicina.
Yang J., F. Lu, Kostiuk L. W., Kwok D. Y. (2003). Electrokinetic microchannel battery by means of electrokinetic and microfluidic phenomena. Journal of micromechanics and micro engineering. October, Volume 13, Number 6
Yasui, Y. (1973). A summary of studies on luminous phenomena accompanied with earthquakes. Memoirs Kakioka Magnetic Observatory(15), 127-138.
Yeagley, H. (1947). A Preliminary Study of a Physical Basis of Bird Navigation. Journal of Applied Physics, 18(12).
Yen, H.-Y, Yeh Y.-H., Liu J.-Y., Lin C.-R., Tsai Y.-B. (1999). Geomagnetic fluctuations during the 1999 Chi-Chi earthquake in Taiwan. Earth, Planets, and Space(56), 39-45.
Yuan Gas, S. C. (2008). Shear-wave splitting and earthquake forecasting.
Zagainov, Y. (1974). Review of geological and geophysical materials on the Kholzun iron ore deposition zone to select an exploration strategy: Report 1273. Novokuznetsk, USSR: Western Siberian Geological Administration.
Zangger, E. (1993). The Geoarchaeology of the Argolid. Berlin: Gebr. Mann Verlag.
Zaprometov, M. (1996). Phenolic compounds and their role in a plant life. Moscow, USSR: Nauka.
Zhadin, M. (2001). Review of Russian literature on biological action of DC and lowfrequency AC magnetic fields. Bioelectromagnetics(22), 27-45.
Zhidkov, M., Likhacheva, E., & Trifonov, V. (1999). Towns, population and active faults on the Russian Plain. Izvestiya Akademii Nauk, Series Geographical(2), 51-57.
Zlotnicki, J.; Le Mouël J.-L.; Gvishiani, A.; Agayan, S.; Mikhailov, V.; Bogoutdinov, S.; Kanwar, R.; Yvetot, P. (2005). Automatic fuzzy-logic recognition of anomalous activity on long geophysical records: Application to electric signals associated with the volcanic activity of La Fournaise volcano (Re´union Island). Earth and Planetary Science Letters. Volume 234, Ticket 1-2, p.261-278
Zlotnicki J., & Le Mouel, J. (1990). Possible electrokinetic origin of large magnetic variations at La Fournaise volcano. Nature, 343(15):633-635.
Zulauf, G., Dörr, W. L., & Marko, J. (2018). The late Eo-Cimmerian evolution of the external Hellenides: constraints from microfabrics and U–Pb detrital zircon ages of Upper Triassic (meta)sediments (Crete, Greece). International Journal of Earth Sciences, 1-36.
Zwaardemaker, H. (1924). Bio-radioactivity and humoral environment. Quarterly Journal of Experimental Physiology(14), 339-350.
Τombarkiewicz, B. (1996). Geomagnetics studies in cow house. Acta Agr. Et 426 Silv. Seria Zoot.(34).