A chemical element is a collective term that describes a collection of atoms of a simple substance, that is, one that cannot be divided into any simpler (according to the structure of their molecules) components. Imagine being given a piece of pure iron and being asked to separate it into its hypothetical constituents using any device or method ever invented by chemists. However, you can't do anything; the iron will never be divided into something simpler. A simple substance - iron - corresponds to the chemical element Fe.

Theoretical definition

The experimental fact noted above can be explained using the following definition: a chemical element is an abstract collection of atoms (not molecules!) of the corresponding simple substance, i.e. atoms of the same type. If there was a way to look at each of the individual atoms in the piece of pure iron mentioned above, then they would all be iron atoms. In contrast, a chemical compound such as iron oxide always contains at least two different kinds of atoms: iron atoms and oxygen atoms.

Terms you should know

Atomic mass: The mass of protons, neutrons, and electrons that make up an atom of a chemical element.

Atomic number: The number of protons in the nucleus of an element's atom.

Chemical symbol: a letter or pair of Latin letters representing the designation of a given element.

Chemical compound: a substance that consists of two or more chemical elements combined with each other in a certain proportion.

Metal: An element that loses electrons in chemical reactions with other elements.

Metalloid: An element that reacts sometimes as a metal and sometimes as a non-metal.

Non-metal: An element that seeks to gain electrons in chemical reactions with other elements.

Periodic Table of Chemical Elements: A system of classifying chemical elements according to their atomic numbers.

Synthetic element: One that is produced artificially in a laboratory and is generally not found in nature.

Natural and synthetic elements

Ninety-two chemical elements occur naturally on Earth. The rest were obtained artificially in laboratories. A synthetic chemical element is typically the product of nuclear reactions in particle accelerators (devices used to increase the speed of subatomic particles such as electrons and protons) or nuclear reactors (devices used to control the energy released by nuclear reactions). The first synthetic element with atomic number 43 was technetium, discovered in 1937 by Italian physicists C. Perrier and E. Segre. Apart from technetium and promethium, all synthetic elements have nuclei larger than uranium. The last synthetic chemical element to receive its name is livermorium (116), and before it was flerovium (114).

Two dozen common and important elements

Name	Symbol	Percentage of all atoms *				Properties of chemical elements (under normal room conditions)
		In the universe	In the earth's crust	In sea water	In the human body
Aluminum	Al	-	6,3	-	-	Lightweight, silver metal
Calcium	Ca	-	2,1	-	0,02	Found in natural minerals, shells, bones
Carbon	WITH	-	-	-	10,7	The basis of all living organisms
Chlorine	Cl	-	-	0,3	-	Poisonous gas
Copper	Cu	-	-	-	-	Red metal only
Gold	Au	-	-	-	-	Yellow metal only
Helium	He	7,1	-	-	-	Very light gas
Hydrogen	N	92,8	2,9	66,2	60,6	The lightest of all elements; gas
Iodine	I	-	-	-	-	Non-metal; used as an antiseptic
Iron	Fe	-	2,1	-	-	Magnetic metal; used to produce iron and steel
Lead	Pb	-	-	-	-	Soft, heavy metal
Magnesium	Mg	-	2,0	-	-	Very light metal
Mercury	Hg	-	-	-	-	Liquid metal; one of two liquid elements
Nickel	Ni	-	-	-	-	Corrosion-resistant metal; used in coins
Nitrogen	N	-	-	-	2,4	Gas, the main component of air
Oxygen	ABOUT	-	60,1	33,1	25,7	Gas, the second important one air component
Phosphorus	R	-	-	-	0,1	Non-metal; important for plants
Potassium	TO	-	1.1	-	-	Metal; important for plants; usually called "potash"

* If the value is not specified, then the element is less than 0.1 percent.

The Big Bang as the root cause of matter formation

What chemical element was the very first in the Universe? Scientists believe the answer to this question lies in stars and the processes by which stars are formed. The universe is believed to have come into being at some point in time between 12 and 15 billion years ago. Until this moment, nothing existing except energy is thought of. But something happened that turned this energy into a huge explosion (the so-called Big Bang). In the next seconds after the Big Bang, matter began to form.

The first simplest forms of matter to appear were protons and electrons. Some of them combine to form hydrogen atoms. The latter consists of one proton and one electron; it is the simplest atom that can exist.

Slowly, over long periods of time, hydrogen atoms began to cluster together in certain areas of space, forming dense clouds. The hydrogen in these clouds was pulled into compact formations by gravitational forces. Eventually these clouds of hydrogen became dense enough to form stars.

Stars as chemical reactors of new elements

A star is simply a mass of matter that generates energy from nuclear reactions. The most common of these reactions involves the combination of four hydrogen atoms forming one helium atom. Once stars began to form, helium became the second element to appear in the Universe.

As stars get older, they switch from hydrogen-helium nuclear reactions to other types. In them, helium atoms form carbon atoms. Later, carbon atoms form oxygen, neon, sodium and magnesium. Later still, neon and oxygen combine with each other to form magnesium. As these reactions continue, more and more chemical elements are formed.

The first systems of chemical elements

More than 200 years ago, chemists began to look for ways to classify them. In the mid-nineteenth century, about 50 chemical elements were known. One of the questions that chemists sought to resolve. boiled down to the following: is a chemical element a substance completely different from any other element? Or some elements related to others in some way? Is there a general law that unites them?

Chemists proposed various systems of chemical elements. For example, the English chemist William Prout in 1815 suggested that the atomic masses of all elements are multiples of the mass of the hydrogen atom, if we take it equal to unity, i.e. they must be integers. At that time, the atomic masses of many elements had already been calculated by J. Dalton in relation to the mass of hydrogen. However, if this is approximately the case for carbon, nitrogen, and oxygen, then chlorine with a mass of 35.5 did not fit into this scheme.

The German chemist Johann Wolfgang Dobereiner (1780 – 1849) showed in 1829 that three elements from the so-called halogen group (chlorine, bromine and iodine) could be classified according to their relative atomic masses. The atomic weight of bromine (79.9) turned out to be almost exactly the average of the atomic weights of chlorine (35.5) and iodine (127), namely 35.5 + 127 ÷ 2 = 81.25 (close to 79.9). This was the first approach to constructing one of the groups of chemical elements. Dobereiner discovered two more such triads of elements, but he was unable to formulate a general periodic law.

How did the periodic table of chemical elements appear?

Most of the early classification schemes were not very successful. Then, around 1869, almost the same discovery was made by two chemists at almost the same time. Russian chemist Dmitri Mendeleev (1834-1907) and German chemist Julius Lothar Meyer (1830-1895) proposed organizing elements that have similar physical and chemical properties into an ordered system of groups, series, and periods. At the same time, Mendeleev and Meyer pointed out that the properties of chemical elements periodically repeat depending on their atomic weights.

Today, Mendeleev is generally considered the discoverer of the periodic law because he took one step that Meyer did not. When all the elements were arranged in the periodic table, some gaps appeared. Mendeleev predicted that these were sites for elements that had not yet been discovered.

However, he went even further. Mendeleev predicted the properties of these not yet discovered elements. He knew where they were located on the periodic table, so he could predict their properties. Remarkably, every chemical element Mendeleev predicted, gallium, scandium, and germanium, was discovered less than ten years after he published his periodic law.

Short form of the periodic table

There have been attempts to count how many options for the graphic representation of the periodic table were proposed by different scientists. It turned out that there were more than 500. Moreover, 80% of the total number of options are tables, and the rest are geometric figures, mathematical curves, etc. As a result, four types of tables found practical application: short, semi-long, long and ladder (pyramidal). The latter was proposed by the great physicist N. Bohr.

The picture below shows the short form.

In it, chemical elements are arranged in ascending order of their atomic numbers from left to right and from top to bottom. Thus, the first chemical element of the periodic table, hydrogen, has atomic number 1 because the nuclei of hydrogen atoms contain one and only one proton. Likewise, oxygen has atomic number 8 since the nuclei of all oxygen atoms contain 8 protons (see figure below).

The main structural fragments of the periodic system are periods and groups of elements. In six periods, all cells are filled, the seventh is not yet completed (elements 113, 115, 117 and 118, although synthesized in laboratories, have not yet been officially registered and do not have names).

The groups are divided into main (A) and secondary (B) subgroups. Elements of the first three periods, each containing one row, are included exclusively in the A-subgroups. The remaining four periods include two rows.

Chemical elements in the same group tend to have similar chemical properties. Thus, the first group consists of alkali metals, the second - alkaline earth metals. Elements in the same period have properties that slowly change from an alkali metal to a noble gas. The figure below shows how one of the properties, atomic radius, changes for individual elements in the table.

Long period form of the periodic table

It is shown in the figure below and is divided in two directions, by rows and by columns. There are seven period rows, as in the short form, and 18 columns, called groups or families. In essence, the increase in the number of groups from 8 in the short form to 18 in the long form is obtained by placing all the elements in periods, starting from the 4th, not in two, but in one line.

Two different numbering systems are used for groups, as shown at the top of the table. The Roman numeral system (IA, IIA, IIB, IVB, etc.) has traditionally been popular in the United States. Another system (1, 2, 3, 4, etc.) is traditionally used in Europe and was recommended for use in the USA several years ago.

The appearance of the periodic tables in the figures above is a little misleading, as with any such published table. The reason for this is that the two groups of elements shown at the bottom of the tables should actually be located within them. The lanthanides, for example, belong to period 6 between barium (56) and hafnium (72). Additionally, actinides belong to period 7 between radium (88) and rutherfordium (104). If they were inserted into a table, it would become too wide to fit on a piece of paper or wall chart. Therefore, it is customary to place these elements at the bottom of the table.

MENDELEEV'S PERIODIC TABLE

The construction of Mendeleev's periodic table of chemical elements corresponds to the characteristic periods of number theory and orthogonal bases. The addition of Hadamard matrices with matrices of even and odd orders creates a structural basis of nested matrix elements: matrices of the first (Odin), second (Euler), third (Mersenne), fourth (Hadamard) and fifth (Fermat) orders.

It is easy to see that there are 4 orders k Hadamard matrices correspond to inert elements with an atomic mass that is a multiple of four: helium 4, neon 20, argon 40 (39.948), etc., but also the basics of life and digital technology: carbon 12, oxygen 16, silicon 28, germanium 72.

It seems that with Mersenne matrices of orders 4 k–1, on the contrary, everything active, poisonous, destructive and corrosive is connected. But these are also radioactive elements - energy sources, and lead 207 (the final product, poisonous salts). Fluorine, of course, is 19. The orders of the Mersenne matrices correspond to the sequence of radioactive elements called the actinium series: uranium 235, plutonium 239 (an isotope that is a more powerful source of atomic energy than uranium), etc. These are also alkali metals lithium 7, sodium 23 and potassium 39.

Gallium – atomic weight 68

Orders 4 k–2 Euler matrices (double Mersenne) correspond to nitrogen 14 (the basis of the atmosphere). Table salt is formed by two “mersenne-like” atoms of sodium 23 and chlorine 35; together this combination is characteristic of Euler matrices. The more massive chlorine with a weight of 35.4 falls just short of the Hadamard dimension of 36. Table salt crystals: a cube (! i.e. a docile character, Hadamards) and an octahedron (more defiant, this is undoubtedly Euler).

In atomic physics, the transition iron 56 - nickel 59 is the boundary between elements that provide energy during the synthesis of a larger nucleus (hydrogen bomb) and decay (uranium bomb). Order 58 is famous for the fact that not only does it not have analogues of Hadamard matrices in the form of Belevich matrices with zeros on the diagonal, it also does not have many weighted matrices - the nearest orthogonal W(58,53) has 5 zeros in each column and row (deep gap ).

In the series corresponding to the Fermat matrices and their substitutions of order 4 k+1, by the will of fate it costs Fermium 257. You can’t say anything, an exact hit. Here there is gold 197. Copper 64 (63.547) and silver 108 (107.868), symbols of electronics, do not, as can be seen, reach gold and correspond to more modest Hadamard matrices. Copper, with its atomic weight not far from 63, is chemically active - its green oxides are well known.

Boron crystals under high magnification

WITH golden ratio boron is bound - the atomic weight among all other elements is closest to 10 (more precisely 10.8, the proximity of the atomic weight to odd numbers also has an effect). Boron is a rather complex element. Boron plays an intricate role in the history of life itself. The structure of the framework in its structures is much more complex than in diamond. The unique type of chemical bond that allows boron to absorb any impurity is very poorly understood, although a large number of scientists have already received Nobel Prizes for research related to it. The boron crystal shape is an icosahedron, with five triangles forming the apex.

The mystery of Platinum. The fifth element is, without a doubt, noble metals such as gold. Superstructure over Hadamard dimension 4 k, 1 large.

Stable isotope uranium 238

Let us remember, however, that Fermat numbers are rare (the closest is 257). Crystals of native gold have a shape close to a cube, but the pentagram also sparkles. Its nearest neighbor, platinum, a noble metal, is less than 4 atomic weight away from gold 197. Platinum has an atomic weight not of 193, but slightly higher, 194 (the order of the Euler matrices). It's a small thing, but it brings her into the camp of somewhat more aggressive elements. It is worth remembering, in connection, that due to its inertness (it dissolves, perhaps, in aqua regia), platinum is used as an active catalyst for chemical processes.

Spongy platinum ignites hydrogen at room temperature. Platinum’s character is not at all peaceful; iridium 192 (a mixture of isotopes 191 and 193) behaves more peacefully. It's more like copper, but with the weight and character of gold.

Between neon 20 and sodium 23 there is no element with atomic weight 22. Of course, atomic weights are an integral characteristic. But among the isotopes, in turn, there is also an interesting correlation of properties with the properties of numbers and the corresponding matrices of orthogonal bases. The most widely used nuclear fuel is the uranium 235 isotope (Mersenne matrix order), in which a self-sustaining nuclear chain reaction is possible. In nature, this element occurs in the stable form uranium 238 (Eulerian matrix order). There is no element with atomic weight 13. As for chaos, the limited number of stable elements of the periodic table and the difficulty of finding high-order level matrices due to the barrier observed in thirteenth-order matrices are correlated.

Isotopes of chemical elements, island of stability

How to use the periodic table? For an uninitiated person, reading the periodic table is the same as for a gnome looking at the ancient runes of the elves. And the periodic table, by the way, if used correctly, can tell a lot about the world. In addition to serving you well in the exam, it is also simply irreplaceable in solving a huge number of chemical and physical problems. But how to read it? Fortunately, today everyone can learn this art. In this article we will tell you how to understand the periodic table.

The periodic table of chemical elements (Mendeleev's table) is a classification of chemical elements that establishes the dependence of various properties of elements on the charge of the atomic nucleus.

History of the creation of the Table

Dmitry Ivanovich Mendeleev was not a simple chemist, if anyone thinks so. He was a chemist, physicist, geologist, metrologist, ecologist, economist, oil worker, aeronaut, instrument maker and teacher. During his life, the scientist managed to conduct a lot of fundamental research in various fields of knowledge. For example, it is widely believed that it was Mendeleev who calculated the ideal strength of vodka - 40 degrees. We don’t know how Mendeleev felt about vodka, but we know for sure that his dissertation on the topic “Discourse on the combination of alcohol with water” had nothing to do with vodka and considered alcohol concentrations from 70 degrees. With all the merits of the scientist, the discovery of the periodic law of chemical elements - one of the fundamental laws of nature, brought him the widest fame.

There is a legend according to which a scientist dreamed of the periodic table, after which all he had to do was refine the idea that had appeared. But, if everything were so simple.. This version of the creation of the periodic table, apparently, is nothing more than a legend. When asked how the table was opened, Dmitry Ivanovich himself answered: “ I’ve been thinking about it for maybe twenty years, but you think: I was sitting there and suddenly... it’s done.”

In the mid-nineteenth century, attempts to arrange the known chemical elements (63 elements were known) were undertaken in parallel by several scientists. For example, in 1862, Alexandre Emile Chancourtois placed elements along a helix and noted the cyclic repetition of chemical properties. Chemist and musician John Alexander Newlands proposed his version of the periodic table in 1866. An interesting fact is that the scientist tried to discover some kind of mystical musical harmony in the arrangement of the elements. Among other attempts, there was also Mendeleev’s attempt, which was crowned with success.

In 1869, the first table diagram was published, and March 1, 1869 is considered the day the periodic law was opened. The essence of Mendeleev's discovery was that the properties of elements with increasing atomic mass do not change monotonically, but periodically. The first version of the table contained only 63 elements, but Mendeleev made a number of very unconventional decisions. So, he guessed to leave space in the table for still undiscovered elements, and also changed the atomic masses of some elements. The fundamental correctness of the law derived by Mendeleev was confirmed very soon, after the discovery of gallium, scandium and germanium, the existence of which was predicted by the scientist.

Modern view of the periodic table

Below is the table itself

Today, instead of atomic weight (atomic mass), the concept of atomic number (the number of protons in the nucleus) is used to order elements. The table contains 120 elements, which are arranged from left to right in order of increasing atomic number (number of protons)

The table columns represent so-called groups, and the rows represent periods. The table has 18 groups and 8 periods.

• The metallic properties of elements decrease when moving along a period from left to right, and increase in the opposite direction.
• The sizes of atoms decrease when moving from left to right along periods.
• As you move from top to bottom through the group, the reducing metal properties increase.
• Oxidizing and non-metallic properties increase when moving along a period from left to right I.

What do we learn about an element from the table? For example, let's take the third element in the table - lithium, and consider it in detail.

First of all, we see the element symbol itself and its name below it. In the upper left corner is the atomic number of the element, in which order the element is arranged in the table. The atomic number, as already mentioned, is equal to the number of protons in the nucleus. The number of positive protons is usually equal to the number of negative electrons in an atom (with the exception of isotopes).

The atomic mass is indicated under the atomic number (in this version of the table). If we round the atomic mass to the nearest integer, we get what is called the mass number. The difference between the mass number and the atomic number gives the number of neutrons in the nucleus. Thus, the number of neutrons in a helium nucleus is two, and in lithium it is four.

Our course “Periodical Table for Dummies” has ended. In conclusion, we invite you to watch the thematic video, and we hope that the question of how to use the periodic table of Mendeleev has become more clear to you. We remind you that it is always more effective to study a new subject not alone, but with the help of an experienced mentor. That is why you should never forget about them, who will gladly share their knowledge and experience with you.

Knowing the formulation of the periodic law and using D.I. Mendeleev’s periodic system of elements, one can characterize any chemical element and its compounds. It is convenient to put together such a characteristic of a chemical element according to plan.

I. Symbol of a chemical element and its name.

II. The position of a chemical element in the periodic table of elements D.I. Mendeleev:

1. serial number;
2. period number;
3. group number;
4. subgroup (main or secondary).

III. Structure of an atom of a chemical element:

1. charge of the nucleus of an atom;
2. relative atomic mass of a chemical element;
3. number of protons;
4. number of electrons;
5. number of neutrons;
6. number of electronic levels in an atom.

IV. Electronic and electron-graphic formulas of an atom, its valence electrons.

V. Type of chemical element (metal or non-metal, s-, p-, d- or f-element).

VI. Formulas of the highest oxide and hydroxide of a chemical element, characteristics of their properties (basic, acidic or amphoteric).

VII. Comparison of metallic or non-metallic properties of a chemical element with the properties of neighboring elements by period and subgroup.

VIII. The maximum and minimum oxidation state of an atom.

For example, we will provide a description of a chemical element with serial number 15 and its compounds according to their position in D.I. Mendeleev’s periodic table of elements and the structure of the atom.

I. We find in D.I. Mendeleev’s table a cell with the number of a chemical element, write down its symbol and name.

Chemical element number 15 is Phosphorus. Its symbol is R.

II. Let us characterize the position of the element in D.I. Mendeleev’s table (period number, group, type of subgroup).

Phosphorus is in the main subgroup of group V, in the 3rd period.

III. We will provide a general description of the composition of an atom of a chemical element (nuclear charge, atomic mass, number of protons, neutrons, electrons and electronic levels).

The nuclear charge of the phosphorus atom is +15. The relative atomic mass of phosphorus is 31. The nucleus of an atom contains 15 protons and 16 neutrons (31 - 15 = 16). The phosphorus atom has three energy levels containing 15 electrons.

IV. We compose the electronic and electron-graphic formulas of the atom, marking its valence electrons.

The electronic formula of the phosphorus atom is: 15 P 1s 2 2s 2 2p 6 3s 2 3p 3.

Electron-graphic formula for the external level of a phosphorus atom: on the third energy level, on the 3s sublevel, there are two electrons (two arrows in the opposite direction are written in one cell), on three p-sublevels there are three electrons (one is written in each of the three cells arrows having the same direction).

Valence electrons are electrons of the outer level, i.e. 3s2 3p3 electrons.

V. Determine the type of chemical element (metal or non-metal, s-, p-, d-or f-element).

Phosphorus is a non-metal. Since the latter sublevel in the phosphorus atom, which is filled with electrons, is the p-sublevel, Phosphorus belongs to the family of p-elements.

VI. We compose formulas of higher oxide and hydroxide of phosphorus and characterize their properties (basic, acidic or amphoteric).

Higher phosphorus oxide P 2 O 5 exhibits the properties of an acidic oxide. The hydroxide corresponding to the higher oxide, H 3 PO 4, exhibits the properties of an acid. Let us confirm these properties with equations of the types of chemical reactions:

P 2 O 5 + 3 Na 2 O = 2Na 3 PO 4

H 3 PO 4 + 3NaOH = Na 3 PO 4 + 3H 2 O

VII. Let's compare the non-metallic properties of phosphorus with the properties of neighboring elements by period and subgroup.

Phosphorus' subgroup neighbor is nitrogen. Phosphorus' period neighbors are silicon and sulfur. The nonmetallic properties of atoms of chemical elements of the main subgroups with increasing atomic number increase in periods and decrease in groups. Therefore, the non-metallic properties of phosphorus are more pronounced than those of silicon and less pronounced than those of nitrogen and sulfur.

VIII. We determine the maximum and minimum oxidation state of the phosphorus atom.

The maximum positive oxidation state for chemical elements of the main subgroups is equal to the group number. Phosphorus is in the main subgroup of the fifth group, so the maximum oxidation state of phosphorus is +5.

The minimum oxidation state for nonmetals in most cases is the difference between the group number and the number eight. Thus, the minimum oxidation state of phosphorus is -3.

Ether in the periodic table

The world ether is the substance of EVERY chemical element and, therefore, EVERY substance; it is the Absolute true matter as the Universal element-forming Essence.The world ether is the source and crown of the entire genuine Periodic Table, its beginning and end - the alpha and omega of the Periodic Table of Elements of Dmitry Ivanovich Mendeleev.

In ancient philosophy, ether (aithér-Greek), along with earth, water, air and fire, is one of the five elements of being (according to Aristotle) ​​- the fifth essence (quinta essentia - Latin), understood as the finest all-pervading matter. At the end of the 19th century, the hypothesis of a world ether (ME) filling all of the world’s space became widely circulated in scientific circles. It was understood as a weightless and elastic liquid that permeates all bodies. They tried to explain many physical phenomena and properties by the existence of the ether.

Preface.
Mendeleev had two fundamental scientific discoveries:
1 - Discovery of the Periodic Law in the substance of chemistry,
2 - Discovery of the relationship between the substance of chemistry and the substance of Ether, namely: particles of Ether form molecules, nuclei, electrons, etc., but do not participate in chemical reactions.
Ether is particles of matter ~ 10-100 meters in size (in fact, they are the “first bricks” of matter).

Facts. Ether was in the original periodic table. The cell for Ether was located in the zero group with inert gases and in the zero row as the main system-forming factor for building the System of chemical elements. After Mendeleev's death, the table was distorted by removing Ether from it and eliminating the zero group, thereby hiding the fundamental discovery of conceptual significance.
In modern Ether tables: 1 - not visible, 2 - not guessable (due to the absence of a zero group).

Such purposeful forgery hinders the development of the progress of civilization.
Man-made disasters (eg Chernobyl and Fukushima) would have been avoided if adequate resources had been invested in a timely manner in the development of a genuine periodic table. Concealment of conceptual knowledge occurs at the global level to “lower” civilization.

Result. In schools and universities they teach a cropped periodic table.
Assessment of the situation. The periodic table without Ether is the same as humanity without children - you can live, but there will be no development and no future.
Resume. If the enemies of humanity hide knowledge, then our task is to reveal this knowledge.
Conclusion. The old periodic table has fewer elements and more foresight than the modern one.
Conclusion. A new level is possible only if the information state of society changes.

Bottom line. Returning to the true periodic table is no longer a scientific question, but a political question.

What was the main political meaning of Einstein's teaching? It consisted of cutting off humanity’s access to inexhaustible natural sources of energy by any means, which were opened up by the study of the properties of the world ether. If successful on this path, the global financial oligarchy would lose power in this world, especially in the light of the retrospective of those years: the Rockefellers made an unimaginable fortune, exceeding the budget of the United States, on oil speculation, and the loss of the role of oil that “black gold” occupied in in this world - the role of the lifeblood of the global economy - did not inspire them.

This did not inspire other oligarchs - the coal and steel kings. Thus, financial tycoon Morgan immediately stopped funding Nikola Tesla’s experiments when he came close to wireless energy transfer and extracting energy “out of nowhere” - from the world’s ether. After that, no one provided financial assistance to the owner of a huge number of technical solutions put into practice - the solidarity of financial tycoons is like that of thieves in law and a phenomenal nose for where the danger comes from. That's why against humanity and a sabotage was carried out under the name “Special Theory of Relativity”.

One of the first blows fell on Dmitry Mendeleev’s table, in which ether was the first number; it was thoughts about ether that gave birth to Mendeleev’s brilliant insight - his periodic table of elements.

Chapter from the article: V.G. Rodionov. The place and role of the world ether in the true table of D.I. Mendeleev

6. Argumentum ad rem

What is now presented in schools and universities under the title “Periodic Table of Chemical Elements D.I. Mendeleev,” is an outright falsity.

The last time the real Periodic Table was published in an undistorted form was in 1906 in St. Petersburg (textbook “Fundamentals of Chemistry”, VIII edition). And only after 96 years of oblivion, the original Periodic Table rises for the first time from the ashes thanks to the publication of a dissertation in the journal ZhRFM of the Russian Physical Society.

After the sudden death of D.I. Mendeleev and the passing away of his faithful scientific colleagues in the Russian Physico-Chemical Society, the son of D.I. Mendeleev’s friend and colleague in the Society, Boris Nikolaevich Menshutkin, first raised his hand to Mendeleev’s immortal creation. Of course, Menshutkin did not act alone - he only carried out the order. After all, the new paradigm of relativism required the abandonment of the idea of ​​the world ether; and therefore this requirement was elevated to the rank of dogma, and the work of D.I. Mendeleev was falsified.

The main distortion of the Table is the transfer of the “zero group” of the Table to its end, to the right, and the introduction of the so-called. "periods". We emphasize that such (only at first glance, harmless) manipulation is logically explainable only as a conscious elimination of the main methodological link in Mendeleev’s discovery: the periodic system of elements at its beginning, source, i.e. in the upper left corner of the Table, must have a zero group and a zero row, where the element “X” is located (according to Mendeleev - “Newtonium”), - i.e. world broadcast.
Moreover, being the only system-forming element of the entire Table of Derived Elements, this element “X” is the argument of the entire Periodic Table. Transferring the zero group of the Table to its end destroys the very idea of ​​this fundamental principle of the entire system of elements according to Mendeleev.

To confirm the above, we will give the floor to D.I. Mendeleev himself.

“... If the argon analogues do not give compounds at all, then it is obvious that it is impossible to include any of the groups of previously known elements, and for them a special group zero should be opened... This position of argon analogues in the zero group is a strictly logical consequence of understanding the periodic law, and therefore (the placement in group VIII is clearly incorrect) was accepted not only by me, but also by Braizner, Piccini and others... Now, when it has become beyond the slightest doubt that before that group I, in which hydrogen should be placed, there exists a zero group, whose representatives have atomic weights less than those of the elements of group I, it seems to me impossible to deny the existence of elements lighter than hydrogen.

Of these, let us first pay attention to the element of the first row of the 1st group. We denote it by “y”. It will obviously have the fundamental properties of argon gases... “Coronium”, with a density of about 0.2 relative to hydrogen; and it cannot in any way be the world ether.

This element “y”, however, is necessary in order to mentally get close to that most important, and therefore most rapidly moving element “x”, which, in my understanding, can be considered ether. I would like to tentatively call it “Newtonium” - in honor of the immortal Newton... The problem of gravitation and the problem of all energy (!!! - V. Rodionov) cannot be imagined to be really solved without a real understanding of the ether as a world medium that transmits energy over distances. A real understanding of the ether cannot be achieved by ignoring its chemistry and not considering it an elementary substance; elementary substances are now unthinkable without their subordination to periodic law” (“An Attempt at a Chemical Understanding of the World Ether.” 1905, p. 27).

“These elements, according to the magnitude of their atomic weights, took a precise place between the halides and the alkali metals, as Ramsay showed in 1900. From these elements it is necessary to form a special zero group, which was first recognized by Errere in Belgium in 1900. I consider it useful to add here that, directly judging by the inability to combine elements of group zero, analogues of argon should be placed before elements of group 1 and, in the spirit of the periodic system, expect a lower atomic weight for them than for alkali metals.

This is exactly what it turned out to be. And if so, then this circumstance, on the one hand, serves as confirmation of the correctness of the periodic principles, and on the other hand, clearly shows the relationship of argon analogues to other previously known elements. As a result, it is possible to apply the analyzed principles even more widely than before, and expect elements of the zero series with atomic weights much lower than those of hydrogen.

Thus, it can be shown that in the first row, first before hydrogen, there is an element of the zero group with an atomic weight of 0.4 (perhaps this is Yong’s coronium), and in the zero row, in the zero group, there is a limiting element with an negligibly small atomic weight, not capable of chemical interactions and, as a result, possessing extremely fast partial (gas) movement of its own.

These properties, perhaps, should be attributed to the atoms of the all-pervading (!!! - V. Rodionov) world ether. I indicated this idea in the preface to this publication and in a Russian journal article of 1902...” (“Fundamentals of Chemistry.” VIII ed., 1906, p. 613 et seq.)
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From the comments:

For chemistry, the modern periodic table of elements is sufficient.

The role of ether may be useful in nuclear reactions, but this is not very significant.
Taking into account the influence of ether is closest to the phenomena of isotope decay. However, this accounting is extremely complex and the presence of patterns is not accepted by all scientists.

The simplest proof of the presence of ether: The phenomenon of annihilation of a positron-electron pair and the emergence of this pair from a vacuum, as well as the impossibility of catching an electron at rest. Also the electromagnetic field and a complete analogy between photons in a vacuum and sound waves - phonons in crystals.

Ether is differentiated matter, so to speak, atoms in a disassembled state, or more correctly, elementary particles from which future atoms are formed. Therefore, it has no place in the periodic table, since the logic of constructing this system does not imply the inclusion of non-integral structures, which are the atoms themselves. Otherwise, it is possible to find a place for quarks, somewhere in the minus first period.
The ether itself has a more complex multi-level structure of manifestation in world existence than modern science knows about. As soon as she reveals the first secrets of this elusive ether, then new engines for all kinds of machines will be invented on completely new principles.
Indeed, Tesla was perhaps the only one who was close to solving the mystery of the so-called ether, but he was deliberately prevented from realizing his plans. So, to this day, the genius who will continue the work of the great inventor and tell us all what the mysterious ether actually is and on what pedestal it can be placed has not yet been born.