Planetophysical State of the Earth and Life
By DR. ALEXEY N. DMITRIEV
Professor of Geology and Mineralogy
Chief Scientific Member, United Institute of Geology, Geophysics, and Mineralogy,
Siberian Department of Russian Academy of Sciences.
Expert on Global Ecology, and Fast -Processing Earth Events.
Published in Russian, IICA Transactions, Volume 4, 1997
English Presentation Sponsored By: THE MILLENNIUM GROUP, January 8, 1998 http://www.tmgnow.com/
Russian to English Translation and Editing:
by A. N. Dmitriev, Andrew Tetenov, and Earl L. Crockett
By DR. ALEXEY N. DMITRIEV
Professor of Geology and Mineralogy
Chief Scientific Member, United Institute of Geology, Geophysics, and Mineralogy,
Siberian Department of Russian Academy of Sciences.
Expert on Global Ecology, and Fast -Processing Earth Events.
Published in Russian, IICA Transactions, Volume 4, 1997
English Presentation Sponsored By: THE MILLENNIUM GROUP, January 8, 1998 http://www.tmgnow.com/
Russian to English Translation and Editing:
by A. N. Dmitriev, Andrew Tetenov, and Earl L. Crockett
|
SUMMARY
|
There is
growing probability that we are moving into a rapid temperature
instability period similar to the one that took place 10,000 years
ago. The adaptive responses of the biosphere, and humanity, to these
new conditions may lead to a total global revision of the range of
species and life on Earth.
It is only through a deep understanding of the fundamental changes taking place in the natural environment surrounding us that politicians and citizens alike will be able to achieve balance with the renewing flow of PlanetoPhysical states and processes. |
INTRODUCTION
|
This high-energy atmospheric phenomenon, which was rare in the past, is now becoming more frequent, intense, and changed in its nature. The material composition of the gas-plasma envelope is also being transformed.
It is quite natural for the whole biota of the Earth to be subjected to these changing conditions of the electromagnetic field, and to the significant deep alterations of Earth's climatic machinery. These fundamental processes of change create a demand within all of Earth's life organisms for new forms of adaptation. The natural development of these new forms may lead to a total global revision of the range of species, and life, on Earth . New deeper qualities of life itself may come forth, bringing the new physical state of the Earth to an equilibrium with the new organismic possibilities of development, reproduction and perfection. In this sense it is evident that we are faced with a problem of the adaptation of humanity to this new state of the Earth; new conditions on Earth whose biospheric qualities are varying, and non-uniformly distributed. Therefore the current period of transformation is transient, and the transition of life's representatives to the future may take place only after a deep evaluation of what it will take to comply with these new Earthly biospheric conditions. Each living representative on Earth will be getting a thorough "examination," or "quality control inspection," to determine its ability to comply with these new conditions. These evolutionary challenges always require effort, or endurance, be it individual organisms, species, or communities. Therefore, it is not only the climate that is becoming new, but we as human beings are experiencing a global change in the vital processes of living organisms, or life itself; which is yet another link in the total process. We cannot treat such things separately, or individually. |
1.0 TRANSFORMATION OF THE SOLAR SYSTEM
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This breakthrough constitutes a kind of matter and energy donation made by interplanetary space to our Solar System.
In response to this "donation of energy/matter," we have observed a number of large scale events:
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1.1 A Series of Large PlanetoPhysical Transformations
|
Update Note From A.N.D Nov. 1997:
A stream of ionized hydrogen, oxygen, nitrogen, etc. is being directed to Jupiter from the volcanic areas of Io through a one million amperes flux tube. It is affecting the character of Jupiter's magnetic process and intensifying its plasma genesis.{Z.I.Vselennaya "Earth and Universe" N3, 1997 plo-9 by NASA data} 1.1.6 A series of Martian atmosphere transformations increasing its biosphere quality. In particularly, a cloudy growth in the equator area and an unusual growth of ozone concentration[16]. Update Note: In September 1997 the Mars Surveyor Satellite encountered an atmospheric density double that projected by NASA upon entering a Mars orbit. This greater density bent one of the solar array arms beyond the full and open stop. This combination of events has delayed the beginning of the scheduled photo mission for one year. 1.1.7 A first stage atmosphere generation on the Moon, where a growing natrium atmosphere is detected that reaches 9,000 km in height. [17]. 1.1.8 Significant physical, chemical and optical changes observed on Venus; an inversion of dark and light spots detected for the first time, and a sharp decrease of sulfur-containing gases in its atmosphere [16]. |
1. 2 A Change in the Quality of Interplanetary Space Towards an Increase
in its Interplanetary and Solar-Planetary Transmitting Properties
in its Interplanetary and Solar-Planetary Transmitting Properties
|
A report already exists of two new populations of cosmic particles that were not expected to be found in the Van Allen radiation belts [25]; particularly an injection of a greater than 50 MeV dense electron sheaf into the inner magnetosphere during times of abrupt magnetic storms [CMEs], and the emergence of a new belt consisting of ionic elements traditionally found in the composition of stars.
This newly changed quality of interplanetary space not only performs the function of a planetary interaction transmission mechanism, but it (this is most important) exerts stimulating and programming action upon the Solar activity both in its maximal and minimal phases. The seismic effectiveness of the solar wind is also being observed [26,27]. |
1.3 The Appearance of New States and Activity Regimes of the Sun
|
The 23rd cycle was initiated by a short series of sunspots in August 1995 [32], which allows us to predict the solar activity maximum in 1999. What is also remarkable is that a series of class C flares has already happened in July 1996 . The specificity and energy of this cycle was discussed at the end of the 1980s. [23]. The increased frequency of X-Ray flux flares which occurred in the very beginning of this cycle provided evidence of the large-scale events to come, especially in relation to an increase in the frequency of super-flashes.
The situation has become extremely serious due to the growth in the transmitting qualities of the interplanetary environment [2 3, 24] and the growth of Jupiter's system's heliospheric function; with Jupiter having the possibility of being shrouded by a plasmosphere extending over Io's orbit [13]. As a whole, all of the reporting and observation facilities give evidence of a growth in the velocity, quality, quantity, and energetic power of our Solar System's Heliospheric processes. Update Note, 1 August 1998: The unexpected high level of Sun activity in the later half of 1997, that is continuing into present time, provides strong substantiation of the above statement. There were three "X" level GOES 9 X-Ray Flux events in 1997 where one was forecasted; a 300% increase. The most dramatic of these, a X-9.1 coronal mass ejection on November 6, 1997, produced a proton event here on Earth of approximately 72 hours in duration. The character, scale, and magnitude of current Sun activity has increased to the point that one official government Sun satellite reporting station recently began their daily report by saying, "Everything pretty much blew apart on the Sun today, Jan. 3,1998." |
2.0 THE EARTH RE-ORGANIZATION PROCESSES
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In the case of our own planet these new events have placed an intense pressure on the geophysical environment; causing new qualities to be observed in the natural processes here on Earth; causes and effects which have already produced hybrid processes throughout the planets of our Solar System; where the combining of effects on natural matter and energy characteristics have been observed and reported.
We shall now discuss global, regional, and local processes. |
2.1 The Geomagnetic Field Inversion
|
We also have to take into account the factual growth of the polar cusp's angle (i.e. The polar slots in the magnetosphere; North and South), which in the middle 1990's reached 45 degrees (by IZMIRAN data). [Note: The cusp angle was about 6 degrees most of the time. It fluctuates depending upon the situation. During the last five years, however, it has varied between 25 and 46 degrees.]
The increasing and immense amounts of matter and energy radiating from the Sun's Solar Wind and Interplanetary Space by means previously discussed, has began to rush into these widened slots in the polar regions causing the Earth's crust, the oceans, and the polar ice caps to warm[27]. Our study of geomagnetic field paleoinversions, and their after effects, has lead us to the unambiguous, and straightforth, conclusion that these present processes being observed are following precisely the same scenarios as those of their distant ancestors. And additional signs of the inversion of the magnetic field are becoming more intense in frequency and scale. For example: during the previous 25 million years, the frequency of magnetic inversions was twice in half a million years while the frequency of inversions for the last 1 million years is 8 to 14 inversions [43], or one inversion each 71 to 125 thousand years. What is essential here is that during prior periods of maximum frequency of inversions there has also been a corresponding decrease in the level of oceans world-wide (10 to 150 meters) from contraction caused by the wide development of crustal folding processes. Periods of lesser frequency of geomagnetic field inversions reveals sharp increases of the world ocean level due to the priority of expansion and stretching processes in the crust. [43-44]. Therefore, the level of the world's oceans depends on the global characteristic of the contraction and expansion processes in force at the time. The current geomagnetic inversion frequency growth phase may not lead to an increase in oceanic volume from polar warming, but rather to a decrease in ocean levels. Frequent inversions mean stretching and expansion, rare inversions mean contraction. Planetary processes, as a rule, occur in complex and dynamic ways which require the combining and joining of all forces and fields in order to adequately understand the entire system. In addition to the consideration of hydrospheric redistribution, there are developing events which also indicate a sudden and sharp breakdown of the Earth's meteorological machinery. |
2.2 Climate Transformations
|
2.2.4.That annual temperatures increased by 7 degrees centigrade.
2.2.5.That precipitation grew in the range of 3 to 4 times. 2.2.6.That the mass of dust material increased by a factor of 100. Such high-speed transformations of the global climatic mechanism parameters and its effects on Earth's physical and biospheric qualities has not yet been rigorously studied by the reigning scientific community. But researchers are now insisting more and more that the Earth's temperature increases are dependent upon, and directly linked to, space-terrestrial interactions [52,53]; be it Earth-Sun, Earth-Solar System, and/or Earth-Interstellar. At the present time there is no lack of new evidence regarding temperature inversion variations in the hydrosphere [oceans]. In the Eastern Mediterranean there have been recordings of a temperature inversion in depths greater than two kilometers from a ratio of 13.3 to 13.5 degrees centigrade to a new ratio of 13.8 to 13.5; along with a growth in salinity of 0.02% since 1987. The growth of salinity in the Aegean Sea has stopped, and the salt water outflow from the Mediterranean Basin to the Atlantic has diminished. Neither of these processes, or their causes, has been satisfactorily explained. It has already been established that evaporation increases in the equatorial regions causes a water density increase which results in an immediate sinking to a greater depth. Ultimately this would force the Gulfstream to reverse its flow. A probability of this event happening is confirmed by other signs as well as multiparameter numeric models [53]. Therefore the most highly probable scenario for the European Continent is a sharp and sudden cooling. Elsewhere, the Siberian region has been experiencing a stable temperature increase [58] along with reports from the Novosibirsk Klyuchi Observatory of a constant growth of up to 30 nanoteslas per year of the vertical component of the magnetic field. This growth rate increases significantly as the Eastern Siberian magnetic anomaly is approached. Update Note 1/8/98: The National Oceanic and Atmospheric Administration reported today, 1/8/98, that 1997 was the warmest year on record since records began in 1880, and that nine of the warmest years since that time have occurred in the last eleven years. |
2.3 Vertical and Horizontal Ozone Content Redistribution
|
The most serious concern of aeronomists comes from the detection of H02 that is being produced at an altitude of 11 miles by a completely unknown source or mechanism. This source of HO2 was discovered as a result of the investigation of OH/HO2 ratios in the interval between 4.35 and 21.70 miles in the upper troposphere and stratosphere. This significant growth of HO2, over the course of time, will create a dependence on this substance for the ozone transfer and redistribution process in the lower stratosphere[56].
The submission of the ozone's dynamic regime and space distribution to the above unknown source of HO2, signifies a transition of Earth's atmosphere to a new physico-chemical process. This is very important because non-uniformities in the Earth's ozone concentrations can, and will, cause an abrupt growth in temperature gradients, which in turn do lead to the increase of air mass movement velocities, and to irregularities of moisture circulation patterns[46,59]. Temperature gradient changes and alterations over the entire planet would create new thermodynamic conditions for entire regions; especially when the hydrospheres [oceans] begin to participate in the new thermal non-equilibrium. The study [53] supports this conclusion, and the consideration of a highly possible abrupt cooling of the European and North American Continents. The probability of such a scenario increases when you take into account the ten year idleness of the North Atlantic hydrothermal pump. With this in mind, the creation of a global, ecology-oriented, climate map which might reveal these global catastrophes becomes critically important. |
3.0 THE ARRIVAL OF NEW CONDITIONS AND CONSEQUENCES
Considering the totality and sequential relationship of
transient background and newly formed processes, brought about by
the above stated cosmogenic and anthropogenic PlanetoPhysical
transformations and alterations of our weather and climatic systems,
we find it reasonable to divide matters into their manifest
(explicit) and non-manifest (implicit) influences upon Earth's
environment.
3.1 The Manifest or Explicit Consequences
|
The dynamic growth of significant catastrophes shows a major increase in the rate of production since 1973. And in general, the number of catastrophes has grown by 410% between 1963 and 1993. Special attention must be focused on the growing number and variety of catastrophes, and to their consequences.
One must keep in mind that the growing complexity of climatic and weather patterns signals a transformation tending towards a new state, or as Academician Kondratyev says, data indicates that we are moving in the direction of climatic chaos. In reality this transition state of our climatic machinery is placing new requirements upon Earth's entire biosphere; which does include the human species. In particular, there are reports from Antarctica that show a dramatic reaction by vegetation to the recent changes in climate; there were 700 species found growing in 1964 and 17,500 in 1990 [61]. This increase in Earth's vegetative cover provides evidence of the biosphere's reaction to the ongoing process of climatic re-arrangement. The overall pattern of the generation and movement of cyclones has also changed. For example, the number of cyclones moving to Russia from the West has grown 2.5 times during the last 10 years. Increased ocean levels caused by the shedding of ice from the polar regions will lead to sharp changes in coast lines, a redistribution of land and sea relationships, and to the activation of significant geodynamic processes. This is the main characteristic of those processes leading to a new climatic and biospheric order. |
3.2 The Non-Manifest or Implicit Consequences
|
These features include:
3.2.1. Intense electromagnetic emissions ranging from the micrometer wave band through the visible diapason, to television and radio wavelengths. 3.2.2. Electric and magnetic field changes such as electric breakdowns, and the magnetization of rocks and technical objects. 3.2.3. Destructive electrical discharges. 3.2.4. Gravitation effects such as levitation. 3.2.5. Others. All of the qualities of this class of phenomena are requiring the development of new branches of modern physics; particularly the creation of a "non-homogeneous physical vacuum model". An advancement of the sciences in this direction would allow us to reveal the true nature of these objects, which are acting apparently, and latently, upon our geological-geophysical and biospheric environment, and on human life [68]. Therefore, we must first take into account all of the newly developed processes and states of our geological-geophysical environment. These processes, for the most part, manifest themselves in the hard-to-register, and observe, qualities of the Earth's electromagnetic skeleton. This data also concerns the geophysical and climatic meanings of Solar-terrestrial and planetary-terrestrial interactions. This is especially true of Jupiter which is magnetically conjugate to our planet. The totality of these planet-transforming processes develops precipitately, ubiquitously, and diversely. It is critical that politicians be informed and trained to understand these global relationships between the totality of natural and anthropogeneous activities, and their fundamental causes and effects [69]. A compelling need exists to commence a scientific study which would delineate the problems associated with Earth's current transformational processes, and the effects they will have on global demographic dynamics.[70]. The sharp rise of our technogeneous system's destructive force on a planetary as well as a cosmic scale, has now placed the future survival of our technocratic civilization in question[33,7]. Additionally, the principle of Nature's supremacy [72] over that of humanity's current integral technogeneous and psychogenic activities and results, becomes more and more apparent. |
CONCLUSIONS
|
The general list of these zones includes the polar regions, the eastern continental extremities of the equatorial regions [Caribbean, Madagascar, Philippines, Yellow Sea, etc.], and the inner continental zones tending to folding and uplifting [Himalayas, Pamir-Hindukush, Altay-Sayan systems, etc.].
The most significant of these areas are the helio-sensitive zones which have intense responses to geoeffective solar activities [Note #1]; responses that include the very dramatic and unusual manifestation of non-homogeneous vacuum, or classical non-mechanical, ether domain structures. These structures or objects then interact with the heliosensitive zones, producing deep and powerful effects upon the environment such as the alteration of seismic activities and chemical compositions. Because these non-homogeneous vacuum domain objects display not-of-this-physical-world characteristics such as "liquid light" and "non-Newtonian movement" it is difficult not to describe their manifestations as being "interworld processes". It is important to note that those heliosensitive zones that exhibit middle and large scale processes are also those that are closely associated with these "interworld processes" produced by physical vacuum homogeneity disturbances. Such disturbances cause and create energy and matter transfer processes between the ether media and our three-dimensional world. The multitude of such phenomena, which is rich in its quality and variety, is already growing quickly. Hundreds of thousands of these natural self-luminous formations are exerting an increasing influence upon Earth's geophysic fields and biosphere. We suggest that the presence of these formations is the mainstream precedent to the transformation of Earth; an Earth which becomes more and more subject to the transitional physical processes which exist within the borderland between the physical vacuum and our material world. All of this places humanity, and each one of us, squarely in front of a very difficult and topical problem; the creation of a revolutionary advancement in knowledge which will require a transformation of our thinking and being equal to this never-before-seen phenomenon now presencing itself in our world. There is no other path to the future than a profound internal experiential perception and knowledge of the events now underway in the natural environment that surrounds us. It is only through this understanding that humanity will achieve balance with the renewing flow of the PlanetoPhysical States and Processes. |
NOTES
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3. Since different zones of Earth have different functions in
the Earth organism, their response to Solar activity is also
different. For example, the polar regions are first to react to Solar
disturbances, which we know well in the form of magnetic storms,
auroras, and nowadays in ocean warming at the 75 degree North
latitudes. We also know other places which demonstrate intense
reactions to different kinds of solar activity; that's what we call
heliosensitive zones. Such reactions include local
electromagnetic disturbances, low-latitude auroras, and specific
changes in the pattern of magnetic field variations on the short term
scale. There are also long-term reactions in the state of the
biosphere. One of our colleagues, Ildar Mingazov, found, in studying
the distribution and frequency of different types of diseases in
various regions, that the intensity of disease frequency in
correlation with solar activity varies between regions, and is
maximal for heliosensitive zones (for example, cardiovascular
diseases).
(Notes by: Andrew Tetenov) |
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