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Science news. Research on the kitchen table
Lim Word
Everything new is being sought not in huge institutions, but in our home laboratory. Almost from scratch. You will learn how to concentrate the energy scattered in nature, restore the past, and see the invisible.
Science news
Research on the kitchen table
Lim Word
© Lim Word, 2018
ISBNВ 978-5-4485-6692-9
Created with Ridero smart publishing system
…How to collect scattered in space, as if already asleep energy? Obviously, there are natural natural processes that increase its quality to its original value.
These are not some complicated devices. Everything happens byВ itself. You just need toВ be able toВ see.
The hot kettle on the table gives energy to the space – the table, the streams of air, etc. With the passage of time it cools down. The motion of molecules is evenly distributed in the environment. The energy of high order disappeared, replaced by a uniform thermal background. Is it possible to reverse the process? Will the impulses from the environment of the teapot be transferred in a particular case, will it boil right on your kitchen table?
This is how it should be if inВ nature, from the beginning ofВ time, there is aВ cycle ofВ energy.
One of the author’s first publications on this topic is an article in “TM”, No. 4, 2000:
“What is the difference between an object of the macrocosm – a monolith – from a cloud of dust obtained as a result of its long grinding and subsequent shaking? Well-known: the area of contact with the environment of another phase, for example, with gas. That is why the chemical reactions that occur in powders are completely unaffected by monoliths, iron filings burn in the air, whereas an iron nail, except in pure oxygen…
Dusty laser?
But the question is: what happens when the monolith is grinded or, conversely, how does the dust coalesce again into a monolith with a radiation-absorption spectrum? Let’s help the laws of quantum physics.
InВ monolith, the spectrum runs through all the energy levels, theoretically, as many as the atoms inВ the body. InВ aВ gas, individual atoms radiate independently, on aВ few levels. But when the neighboring atoms appear, the levels shift so as not toВ repeat each other, the prohibition principle introduced at the beginning ofВ the 20th century works. Wolfgang Pauli: there can not be interconnected atoms, the energy parameters ofВ which are completely the same.
But the powder is an intermediate state between the gas and the solid. Apparently, aВ sharp boundary, on which the properties change spasmodically, can not be carried out. And accordingly, the spectrum ofВ the dust cloud, as the particles are fragmented, will approach the gas spectrum.
But what happens if you thicken it toВ the volume ofВ the original monolith?
When merging, say, aВ hundred particles, each energy level will take at once one hundred atoms. ToВ restore the order adopted inВ the microcosm, each ofВ these supersaturated levels will tend toВ split into aВ hundred isolated spectral lines. The most natural way toВ restore the energy hierarchy for atoms ofВ aВ newly formed monolith is toВ radiate aВ certain number ofВ electromagnetic quanta. Consequently, the condensed cloud ofВ dust will become generally colder than the surrounding environment.
Are we humans the same hubs? Than our cells are not isolated “motes” separated by membranes? But the permeability of membranes is constantly changing. And are there many unrelated properties of living organisms that are not associated with such a unification of many millions of “dust particles”?”
Continuation – in the article “Energy concentrators”, “TM” No. 6, 2002, already based on practical, not mental experiments.
1.В cabinet with thermal insulation
2. Dewar vessels
3. continuous medium (water)
4. porous medium
5. electronic thermometers (error not more than 0,02РЎ)
6. temperature sensors
Two vessels – one with a porous medium, the other – with a solid, are located in a thermally insulated cabinet. They have thermal sensors; the temperature inside is measured every 20 minutes.
It was found out that the temperature inВ aВ container with aВ granulated medium (wet sand, etc.) varies abruptly, with considerable amplitude. The solid medium gives aВ very flat temperature graph, without bursts and any periodicity.
Porous, granular, otherwise – ordered matter has the property of ordering – to collect in space and time, energy. Probably, this property manifests itself on different scales. Local heating can also occur in a handful of sand, earth, porous clay, only one or two degrees, and in large areas, in square kilometers. The temperature can increase by tens, hundreds of degrees, possibly accompanied by radioactive emissions. So the energy of a high level comes back to the world.
In a certain way ordering matter, it is possible to achieve a predictable ejection of heat (or cold), in certain areas of the created system. Covered by feedback, the system creates a “cold-heat” pulsation; from this one can obtain a steady stream of energy. The ordering can be performed on macroscopic (fractions of a millimeter) and micro-levels (the distance between the atoms of the crystal). In the latter case, it is possible to achieve not intermittent flicker, “eternal radiance”.
In the first approximation, the concentration system looks like the organization of flows of a homogeneous, initially disconnected substance to some common point, a kind of “heart” with subsequent separation.
Some successes in this, perhaps even intuitively realizing the essence of the process, were achieved by American researchers Fleischman and Pons. They are known to conduct electrolysis of heavy water on palladium electrodes. Their idea – the molecules of the hydrogen isotope accumulate in the crystal lattice of the metal, as closely as possible – and interact. As a result of the “cold nuclear fusion” (NNS), an anomalous heat release occurred (four times higher than the calculated one), but, in addition, there was no neutron radiation associated with it.
In the end, experiments – although they were reproduced in other laboratories, were abandoned, they were almost forgotten. But, with a satisfactory theory: “A structured substance structures energy, creates an order around itself,” they can be revived, put on an appropriate, correct pattern. Hydrogen atoms were collected in one small volume, and therefore they were forced to radiate (relatively soft) photons from their upper energy levels. Isotopes, the synthesis of light nuclei, radiation – this can be forgotten. New reactors of Eternal Motors are loaded with any, not radioactive, but – structured substance.
Note: A structured body (massif) is a cluster of clusters (dust grains) of a substance of equal shape, composition that is some distance from each other in a semitransparent medium or a vacuum. An additional structure in time, give periodic rendezvous and separation of particles – which is like breathing or pulse.
The author reproduced the experiments ofВ Fleischmann and Pons at home, replacing heavy water with ordinary tap water, and palladium electrodes with sand.
It turned out this article:
Electrons get tired?
“Some of the fundamental laws of physics are so simple and obvious that no one doubts their justice, and no one is involved in their verification. In particular, this applies to Ohm’s law, according to which the direct current in the circuit (in any case at its low density) is equal to the voltage divided by the resistance: I = U / R. This is followed by other rules of electrical engineering. For example, according to the Joule-Lentz law, the heat W allocated to the resistance R is directly proportional to the voltage drop across it U, the current I and the duration of its passage t, that is, W = R-U-1-t. Therefore, if two identical resistances are sequentially included in a closed circuit, then the same amount of heat should be allocated to them in a unit of time. It seems quite obvious that, bypassing the first resistance, the electrons are not able to either acquire additional energy or lose it.
But does Ohm’s law really hold for resistances of all kinds at low current densities? Interested in this issue, I performed a series of simple experiments. Two, if possible, the same resistance, I included in the DC circuit, and next to them attached sensors sensitive thermometers. Each resistance, together with its “own” sensor, was placed in a separate thermostat.
InВ the first experiments, as resistance, IВ used incandescent lamps (calculated for aВ voltage ofВ 2.5 V and aВ current ofВ 0.15 A). Turning on the current (its source was aВ reducing stabilizing transformer and aВ rectifier included inВ aВ household circuit with aВ voltage ofВ 220 V), IВ measured the temperature inВ thermostats for an hour; then changed the lamps inВ places and repeated the measurements. Five series ofВ similar experiments showed that the metallic resistances gave off the amount ofВ heat inВ full accordance with the classical laws ofВ electrical engineering, and no matter where these resistances were located.
IВ did not make measurements using resistances ofВ other types, but IВ performed the experiment using electrolytic cells as aВ resistance inВ which ordinary tap water was decomposed on stainless steel electrodes; the result again did not reveal any anomalies.
But if electrolysis ofВ water was carried out inВ aВ porous, heterogeneous medium, the picture turned out toВ be different.
IВ filled the electrolytic cells with aВ mixture ofВ quartz sand and tap water, acidified for better electrical conductivity byВ several drops ofВ hydrochloric acid (which, generally speaking, is not necessary). And the first experiments gave amazing results, not corresponding toВ the classical laws ofВ electrical engineering.
Namely, the temperature inВ the thermostat located inВ the course ofВ the motion ofВ the electrons turned out toВ be much higher than the temperature inВ the next thermostat! At aВ voltage ofВ aВ current source ofВ 220 V and its strength ofВ 0.5 A, the difference was 90В°C, which significantly exceeded the error value ofВ previous experiments. InВ total IВ performed 10 similar experiments and noticed that the difference inВ temperature between cells clearly depends on the current strength inВ the circuit and can reach even aВ few tens ofВ degrees.
IВ also noticed that on the first cell the voltage drop was higher than the second one (150 and 70 V, respectively), which explains the increased heat release. But the main question remained without an answer: why is there such aВ noticeable asymmetry, if before and after the experiments the resistance ofВ the cells were the same? After all, this effect should notВ be!
It can be assumed that inВ the first cell the electrons for some reason lose some ofВ their internal energy and therefore inВ the second cell they are no longer able toВ interact with ions as intensively. But inВ fact the second cell too (though not style strongly) heats up. True, inВ the sand-water electrolytic cells there are many local and rather sharp differences inВ the resistance ofВ the medium, as aВ result ofВ which the electrons inВ it are sharply accelerated, then they are sharply slowed down. Is not this the reason for the effect that IВ observed?
Of course, my assumption that after passing a certain device, the electrons can seem to get tired, giving the environment some special energy, contradicts the laws of nuclear physics, according to which the electron does not have an internal structure and has only a reserve of external kinetic energy. But if I’m wrong, then let me point out the error, preferably by repeating my experiments.
1—4. electrodes made of stainless steel
5. thermometer sensors
6. The first sand-waterВ cell
7. The second sand-waterВ cell
8. Thermostats
9. DC power supply
…The original idea of the experiment is an anomalous heat release in a granular medium. It turned out not quite what was supposed to be found, but still, the result is interesting. It looks as if the charge carrier, ions and electrons, interacting tightly with each other in the first cell along the current, lose some of their internal energy. And, of course, all this happens in an internally divided, more or less ordered environment.
Unfortunately, the lack ofВ calorimeters, tools for accurate determination ofВ the amount ofВ heat released do not allow toВ receive data at aВ quantitative level. But the qualitative result is also aВ good result.
InВ the first approximation, the generator ofВ electromagnetic energy can look like aВ slurry ofВ magnetic microscopic balls inВ an external medium. According toВ all the above, the ordered array should periodically change its properties (and hence the magnetic flux) inВ time. It remains toВ add toВ it aВ coil with aВ wire toВ get aВ more or less perpetual generator.
In the case of a teapot, things are as follows. Let the table on which it is left to cool – a highly ordered structure of many identical elements, in a closed volume (it can be large). The energy of boiling water is first distributed throughout the volume. Then, macroscopic temperature fluctuations will arise in the system. The period of their appearance in this or that place can be calculated or even organized. We put the cooled vessel at the right time in the right place – and it boils.
This structure can work inВ an open space, attracting the energy scattered inВ the medium, raising it toВ the previous high level.
To such systems, undoubtedly, one can class living beings, beginning with the simplest unicellular ones. The body consists of billions, trillions of pores, membranes opening and closing according to a certain rhythm. For its life, it attracts more energy than it consumes when digesting food, which is proved by some scientific studies. Obviously, living, ordered matter is a kind of perpetual motion machine – however, not quite perfect yet. At the very least, food is needed for metabolism, cell replacement, and the like.
High orderliness is possessed byВ forest massifs, crops ofВ crops, ice cover, possibly, deserts and dried salt lakes. Here, first ofВ all, it is necessary toВ look for anomalous heat releases, and even radiation.
The energy (thermal, electromagnetic) that passes through the massif ofВ matter evenly brings order into it. AВ standard example is the Benard cells, hexagonal honeycombs emerging inВ the oil layer on the heated surface. Thus, systems reanimating energy can be created, including aВ melt, from aВ solidification, under conditions ofВ thermal energy inhomogeneity.
Interaction ofВ similar forms
It is intuitively clear that two identical objects are linked inВ some way; Further on this inner conviction layered the well-known physical formulas and principles.
Any physical body has aВ strictly set ofВ levels ofВ absorption-radiation ofВ electromagnetic waves. The location ofВ the energy bars is affected byВ the structure, shape, chemical composition, temperature, etc. InВ other words, the spectrum, inВ its entirety, is the name ofВ the thing, the set ofВ drawings, the code.
What will happen if, inВ aВ closed volume, two identical things are located next toВ each other? They will start exchanging radiation. The system will tend toВ come toВ aВ stable equilibrium. This is possible when the lines ofВ the spectra ofВ both bodies coincide.
In other words, the spectrum of the body A will tend to impose itself on the body B, and vice versa. Electromagnetic radiation is not purely informational, it has a certain power component. If the bodies A and B (at least one of them) are sufficiently plastic, they will tend to change – in the direction of maximum mutual similarity.
Here, presumably, at a macroscopic level, Pauli’s principle (prohibition) can come into force – two objects can not be (nearby, in the same system) at a single energy level. Thus, around the body A there are concentric zones in which its action on B will be destructive, or creative. The likeness of A and B depends on exactly how far apart they are separated. It is possible to determine this distance only empirically (ie, experimentally).
We will refer to the act of additional assimilation by exchanging our own radiations – Synchronization. As a result, we get two physical bodies, each of which has microparticles having their reflection, a synchronized pair, in another object. And, these particles interact by exchanging electromagnetic quanta (and, perhaps, somehow in some other way).
Here, the Heisenberg uncertainty relation (principle) comes into play. Roughly speaking, two microparticles inВ aВ relatively small region, having the same parameters, become paradoxically connected inВ some way. Some changes inВ the particle AВ are transmitted toВ the partner B, instantly, and, as the founders ofВ quantum mechanics claim, inВ aВ non-physical way (ie, without the participation ofВ any waves or particles). AВ and B are considered as aВ single system, even if the parts are inВ different parts ofВ the universe.
It turns out, after the primary synchronization, the macroscopic bodies A and B, made up of myriads of microscopic a and b, feel each other’s changes. There are various schools of quantum mechanics, some of them try to observe the principles of the Theory of Relativity (the finiteness of the speed of light). But it seems that we have a communication system in which the signals are transmitted many times higher than the “constant” C (300 000 km s).
In the first experiments, I used two identical containers A and B. In the first I put a simple small addition – a figure of a triangle, a square, a pentagon … In both tanks I poured a hot solution of hyposulfite, placed them side by side in a thermally insulated box, and waited for the crystals to show. The solidifying solution is the desired plastic body, sensitive to internal and external influences.
In many cases, the crystals actually appeared on the surface of the solution, formed a kind of label. But, with each time such experiments were reproduced worse and worse, coming to naught usually, to the fourth repetition. This is not quite what modern science requires – experience must be reproduced every time, with accurate reproduction of all conditions, in any laboratory in the world. And of course, the article on such tests is quite serious publications will not take. In the end, the material – just to have something in print – was published in the journal “Young Technician”, 2013, No. 5, under the heading “Mad Ideas”.
Strange experiments
“We are used to the fact that only living organisms have the ability to learn. But can such a property boast chemical compounds? Our long-time author … believes that it is possible and such. That they seem to confirm the experiments they have set.
Take two identical containers – for example, plates or photocells, if any. Mix the alabaster on the solution of hyposulfite (photophyxis). The resultant slowly set the mixture in the same portions on plates. Then put on the surface of one of the plates a mark – carved from plastic or wood triangle. Place the tanks at a distance of one meter from each other, and to protect against external influences, you can cover them with something, for example, with the same plates.
As the mixture solidifies, fine white crystallites ofВ hyposulfite appear on its surface. InВ this case, the hyposulfite crystals inВ the second plate formed, as the author claims, the contours ofВ the triangle, copying the triangular spots that appeared inВ the first form around the real triangle.
“Three experiments in a row showed approximately one result,” the author emphasizes.
Then he conducted the following experiment. Instead ofВ aВ triangle, aВ rectangle was placed inВ the transmitter form (A). The mixtures, as before, crystallized. But on their surface formed white spots, which have nothing toВ do with either the triangle or the rectangle! All subsequent attempts toВ get the previous result failed. Neither the triangle nor the rectangle inВ any way wanted toВ broadcast information about itself inВ the form-receiverВ (B).
The author postponed the experiments and returned to them only a week later. And the incredible happened! The previous results were almost completely restored! Three experiences – three good luck. Three times in the receiver, a ghost of a rectangle’s mark appeared more or less clearly … Then again the formless whitish spots began to appear.
Such an effect is explained byВ the author byВ aВ special M-field, which introduces the course ofВ natural processes inВ similar objects toВ one another inВ aВ certain direction.
About this “morphogenetic field” the author read in the book of the British scientist Rupert Sheldrake “The New Science of Life.” In it, the English professor claims that the biological forms that existed before, nevertheless, affect similar forms (that is, living beings) and at the present time.
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