Presentation on the topic "Alcohols" in chemistry in powerpoint format. The presentation for schoolchildren contains 12 slides, which, from the point of view of chemistry, talk about alcohols, their physical properties, reactions with hydrogen halides.

Fragments from the presentation

From the history

Do you know that even in the 4th c. BC e. did people know how to make drinks containing ethyl alcohol? Wine was obtained by fermentation of fruit and berry juices. However, they learned how to extract the intoxicating component from it much later. In the XI century. alchemists caught vapors of a volatile substance that was released when wine was heated.

Physical properties

• Lower alcohols are liquids that are highly soluble in water, colorless, with an odor.
• Higher alcohols are solids, insoluble in water.

Feature of physical properties: state of aggregation

• Methyl alcohol (the first representative of the homologous series of alcohols) is a liquid. Maybe it has a high molecular weight? No. Much less than carbon dioxide. Then what is it?
• It turns out that it's all about the hydrogen bonds that form between alcohol molecules, and do not allow individual molecules to fly away.

Feature of physical properties: solubility in water

• Lower alcohols are soluble in water, higher alcohols are insoluble. Why?
• Hydrogen bonds are too weak to hold an alcohol molecule, which has a large insoluble portion, between water molecules.

Feature of physical properties: contraction

• Why, when solving computational problems, they never use volume, but only mass?
• Mix 500 ml of alcohol and 500 ml of water. We get 930 ml of solution. The hydrogen bonds between the molecules of alcohol and water are so great that the total volume of the solution decreases, its "compression" (from the Latin contraktio - compression).

Are alcohols acids?

• Alcohols react with alkali metals. In this case, the hydrogen atom of the hydroxyl group is replaced by a metal. It looks like acid.
• But the acid properties of alcohols are too weak, so weak that alcohols do not act on indicators.

Friendship with the traffic police.

• Alcohols are friends with the traffic police? But how!
• Have you ever been stopped by a traffic police inspector? Did you breathe into a tube?
• If you were unlucky, then the alcohol oxidation reaction took place, in which the color changed, and you had to pay a fine.

We give water 1

Withdrawal of water - dehydration can be intramolecular if the temperature is more than 140 degrees. In this case, a catalyst is needed - concentrated sulfuric acid.

We give water 2

If the temperature is reduced, and the catalyst is left the same, then intermolecular dehydration will take place.

Reaction with hydrogen halides.

This reaction is reversible and requires a catalyst - concentrated sulfuric acid.

To be friends or not to be friends with alcohol.

The question is interesting. Alcohol refers to xenobiotics - substances that are not contained in the human body, but affect its vital activity. Everything depends on the dose.

1. Alcohol is a nutrient that provides the body with energy. In the Middle Ages, the body received about 25% of energy through alcohol consumption.
2. Alcohol is a drug that has a disinfectant and antibacterial effect.
3. Alcohol is a poison that disrupts natural biological processes, destroys internal organs and the psyche, and, if consumed in excess, leads to death.

All substances can be in different states of aggregation - solid, liquid, gaseous and plasma. In ancient times, it was believed: the world consists of earth, water, air and fire. Aggregate states of substances correspond to this visual division. Experience shows that the boundaries between aggregate states are very arbitrary. Gases at low pressures and low temperatures are considered ideal, the molecules in them correspond to material points that can only collide according to the laws of elastic impact. The forces of interaction between molecules at the moment of impact are negligible, the collisions themselves occur without loss of mechanical energy. But as the distance between molecules increases, the interaction of molecules must also be taken into account. These interactions begin to affect the transition from a gaseous state to a liquid or solid. Various kinds of interactions can occur between molecules.

The forces of intermolecular interaction do not have saturation, differing from the forces of chemical interaction of atoms, leading to the formation of molecules. They can be electrostatic when interacting between charged particles. Experience has shown that the quantum mechanical interaction, which depends on the distance and mutual orientation of molecules, is negligible at distances between molecules of more than 10 -9 m. In rarefied gases, it can be neglected or it can be assumed that the potential energy of interaction is practically zero. At small distances, this energy is small, at , the forces of mutual attraction act

at - mutual repulsion and force

attraction and repulsion of molecules are balanced and F= 0. Here the forces are determined by their connection with the potential energy. But the particles move, having a certain reserve of kinetic energy

gee. Let one molecule be motionless, and another collide with it, having such a supply of energy. When the molecules approach each other, the forces of attraction do positive work and the potential energy of their interaction decreases to a distance. At the same time, the kinetic energy (and speed) increases. When the distance becomes less, the attractive forces will be replaced by repulsive forces. The work done by the molecule against these forces is negative.

The molecule will approach the immobile molecule until its kinetic energy is completely converted into potential. Minimum distance d, which molecules can approach each other is called effective molecular diameter. After stopping, the molecule will begin to move away under the action of repulsive forces with increasing speed. Having passed the distance again, the molecule will fall into the region of attractive forces, which will slow down its removal. The effective diameter depends on the initial stock of kinetic energy, i.e. this value is not constant. At distances equal to the potential energy of interaction has an infinitely large value or "barrier" that prevents the convergence of the centers of molecules at a shorter distance. The ratio of the average potential energy of interaction to the average kinetic energy determines the aggregate state of matter: for gases for liquids, for solids

Condensed media are liquids and solids. In them, atoms and molecules are located close, almost touching. The average distance between the centers of molecules in liquids and solids is about (2 -5) 10 -10 m. Their densities are approximately the same. Interatomic distances exceed the distances over which electron clouds penetrate each other so much that repulsive forces arise. For comparison, in gases under normal conditions, the average distance between molecules is about 33 10 -10 m.

AT liquids intermolecular interaction is more pronounced, the thermal motion of molecules manifests itself in weak oscillations around the equilibrium position and even jumps from one position to another. Therefore, they have only short-range order in the arrangement of particles, i.e., consistency in the arrangement of only the nearest particles, and characteristic fluidity.

Solids are characterized by rigidity of the structure, have a precisely defined volume and shape, which change much less under the influence of temperature and pressure. In solids, amorphous and crystalline states are possible. There are also intermediate substances - liquid crystals. But the atoms in solids are not at all motionless, as one might think. Each of them fluctuates all the time under the influence of elastic forces that arise between neighbors. Most elements and compounds have a crystal structure under a microscope.

So, salt grains look like ideal cubes. In crystals, atoms are fixed at the nodes of the crystal lattice and can only vibrate near the lattice nodes. Crystals constitute true solids, and solids such as plastic or asphalt occupy an intermediate position, as it were, between solids and liquids. An amorphous body, like a liquid, has a short-range order, but the probability of jumps is small. So, glass can be considered as a supercooled liquid, which has an increased viscosity. Liquid crystals have the fluidity of liquids, but retain the orderliness of the arrangement of atoms and have anisotropy of properties.

The chemical bonds of atoms (and on about in) in crystals are the same as in molecules. The structure and rigidity of solids is determined by the difference in electrostatic forces that bind together the atoms that make up the body. The mechanism that binds atoms into molecules can lead to the formation of solid periodic structures, which can be considered as macromolecules. Like ionic and covalent molecules, there are ionic and covalent crystals. Ionic lattices in crystals are held together by ionic bonds (see Fig. 7.1). The structure of table salt is such that each sodium ion has six neighbors - chloride ions. This distribution corresponds to a minimum of energy, i.e., when such a configuration is formed, the maximum energy is released. Therefore, as the temperature drops below the melting point, a tendency to form pure crystals is observed. With an increase in temperature, the thermal kinetic energy is sufficient to break the bond, the crystal will begin to melt, and the structure will collapse. Crystal polymorphism is the ability to form states with different crystal structures.

When the distribution of electric charge in neutral atoms changes, a weak interaction between neighbors can occur. This bond is called a molecular or van der Waals bond (as in a hydrogen molecule). But the forces of electrostatic attraction can also arise between neutral atoms, then no rearrangements in the electron shells of atoms occur. Mutual repulsion during the approach of electron shells shifts the center of gravity of negative charges relative to positive ones. Each of the atoms induces an electric dipole in the other, and this leads to their attraction. This is the action of intermolecular forces or van der Waals forces, which have a large radius of action.

Since the hydrogen atom is very small and its electron is easily displaced, it is often attracted to two atoms at once, forming a hydrogen bond. The hydrogen bond is also responsible for the interaction of water molecules with each other. It explains many of the unique properties of water and ice (Figure 7.4).

covalent bond(or atomic) is achieved due to the internal interaction of neutral atoms. An example of such a bond is the bond in the methane molecule. A highly bonded form of carbon is diamond (four hydrogen atoms are replaced by four carbon atoms).

So, carbon, built on a covalent bond, forms a crystal in the form of a diamond. Each atom is surrounded by four atoms forming a regular tetrahedron. But each of them is simultaneously the vertex of the neighboring tetrahedron. Under other conditions, the same carbon atoms crystallize into graphite. In graphite, they are also connected by atomic bonds, but they form planes of hexagonal honeycomb cells capable of shearing. The distance between the atoms located at the vertices of the hexagons is 0.142 nm. The layers are located at a distance of 0.335 nm, i.e. weakly bound, so graphite is plastic and soft (Fig. 7.5). In 1990, there was a boom in research work, caused by a message about the receipt of a new substance - fullerite, consisting of carbon molecules - fullerenes. This form of carbon is molecular; The smallest element is not an atom, but a molecule. It is named after the architect R. Fuller, who in 1954 received a patent for building structures from hexagons and pentagons that make up a hemisphere. Molecule from 60 carbon atoms with a diameter of 0.71 nm was discovered in 1985, then molecules were discovered, etc. All of them had stable surfaces,

but the molecules C 60 and With 70 . It is logical to assume that graphite is used as a feedstock for the synthesis of fullerenes. If so, then the radius of the hexagonal fragment should be 0.37 nm. But it turned out to be equal to 0.357 nm. This difference of 2% is due to the fact that carbon atoms are located on the spherical surface at the vertices of 20 regular hexagons inherited from graphite and 12 regular pentahedrons, i.e. the design resembles a soccer ball. It turns out that when "stitching" into a closed sphere, some of the flat hexagons turned into pentahedrons. At room temperature, C 60 molecules condense into a structure where each molecule has 12 neighbors spaced 0.3 nm apart. At T= 349 K, a first-order phase transition occurs - the lattice is rearranged into a cubic one. The crystal itself is a semiconductor, but when an alkali metal is added to the C 60 crystalline film, superconductivity occurs at a temperature of 19 K. If one or another atom is introduced into this hollow molecule, it can be used as the basis for creating a storage medium with ultrahigh information density: the recording density will reach 4-10 12 bits/cm2. For comparison, a film of ferromagnetic material gives a recording density of the order of 10 7 bits / cm 2, and optical discs, i.e. laser technology, - 10 8 bits/cm 2 . This carbon also has other unique properties that are especially important in medicine and pharmacology.

manifests itself in metal crystals metallic bond, when all the atoms in a metal donate their valence electrons "for collective use". They are weakly bound to atomic cores and can freely move along the crystal lattice. About 2/5 of the chemical elements are metals. In metals (except mercury), a bond is formed when the vacant orbitals of metal atoms overlap and electrons are detached due to the formation of a crystal lattice. It turns out that the cations of the lattice are shrouded in electron gas. A metallic bond occurs when atoms approach each other at a distance less than the size of the outer electron cloud. With this configuration (Pauli principle), the energy of external electrons increases, and the nuclei of the neighbors begin to attract these external electrons, blurring the electron clouds, evenly distributing them over the metal and turning them into an electron gas. This is how conduction electrons arise, which explain the high electrical conductivity of metals. In ionic and covalent crystals, the outer electrons are practically bound, and the conductivity of these solids is very low, they are called insulators.

The internal energy of liquids is determined by the sum of the internal energies of the macroscopic subsystems into which it can be mentally divided, and the interaction energies of these subsystems. The interaction is carried out through molecular forces with a range of about 10 -9 m. For macrosystems, the interaction energy is proportional to the contact area, so it is small, like the fraction of the surface layer, but this is not necessary. It is called surface energy and should be taken into account in problems related to surface tension. Typically, liquids occupy a larger volume with equal weight, i.e., have a lower density. But why do the volumes of ice and bismuth decrease upon melting and even after the melting point retain this trend for some time? It turns out that these substances in the liquid state are more dense.

In a liquid, each atom is acted upon by its neighbors and oscillates within the anisotropic potential well they create. Unlike a solid body, this well is not deep, since distant neighbors have almost no effect. The nearest environment of particles in a liquid changes, i.e., the liquid flows. When a certain temperature is reached, the liquid boils; during boiling, the temperature remains constant. The incoming energy is spent on breaking bonds, and when they are completely broken, the liquid turns into a gas.

The densities of liquids are much greater than the densities of gases at the same pressures and temperatures. Thus, the volume of water at boiling is only 1/1600 of the volume of the same mass of water vapor. The volume of a liquid depends little on pressure and temperature. Under normal conditions (20 °C and a pressure of 1.013 10 5 Pa), water occupies a volume of 1 liter. With a decrease in temperature to 10 ° C, the volume will decrease only by 0.0021, with an increase in pressure - by a factor of two.

Although there is as yet no simple ideal model of a liquid, its microstructure has been sufficiently studied and makes it possible to qualitatively explain most of its macroscopic properties. The fact that the cohesion of molecules in liquids is weaker than in a solid was noticed by Galileo; he was surprised that large drops of water accumulate on cabbage leaves and do not spread over the leaf. Spilled mercury or water drops on a greasy surface take the form of small balls due to adhesion. When the molecules of one substance are attracted to the molecules of another substance, it is called wetting, for example, glue and wood, oil and metal (despite the enormous pressure, the oil is retained in the bearings). But water rises in thin tubes, called capillaries, and rises the higher, the thinner the tube. There can be no other explanation than the effect of wetting water and glass. Wetting forces between glass and water are greater than between water molecules. With mercury, the effect is reversed: the wetting of mercury and glass is weaker than the cohesive forces between mercury atoms. Galileo noticed that a greased needle can float on water, although this contradicts the law of Archimedes. When the needle floats,

but notice a slight deflection of the surface of the water, tending to straighten out, as it were. The cohesive forces between the water molecules are sufficient to prevent the needle from falling into the water. The surface layer, like a film, protects water, this is surface tension, which tends to give the shape of water the smallest surface - spherical. But the needle will no longer float on the surface of alcohol, because when alcohol is added to water, the surface tension decreases, and the needle sinks. Soap also reduces surface tension, so hot soap suds, penetrating into cracks and crevices, is better at removing dirt, especially grease, while pure water would simply curl up into droplets.

Plasma is the fourth aggregate state of matter, which is a gas from a collection of charged particles interacting at large distances. In this case, the number of positive and negative charges is approximately equal, so that the plasma is electrically neutral. Of the four elements, plasma corresponds to fire. To transform a gas into a plasma state, it is necessary to ionize strip electrons from atoms. Ionization can be carried out by heating, by the action of an electric discharge or by hard radiation. Matter in the universe is mostly in an ionized state. In stars, ionization is caused thermally, in rarefied nebulae and interstellar gas, by ultraviolet radiation from stars. Our Sun also consists of plasma, its radiation ionizes the upper layers of the earth's atmosphere, called ionosphere, the possibility of long-range radio communication depends on its condition. Under terrestrial conditions, plasma is rare - in fluorescent lamps or in an electric arc. In laboratories and technology, plasma is most often produced by an electric discharge. In nature, this is done by lightning. During ionization by a discharge, electron avalanches arise, similar to the process of a chain reaction. To obtain thermonuclear energy, the injection method is used: gas ions accelerated to very high speeds are injected into magnetic traps, attract electrons from the environment, forming a plasma. Pressure ionization is also used - shock waves. This method of ionization is found in superdense stars and, possibly, in the Earth's core.

Any force acting on ions and electrons causes an electric current. If it is not connected with external fields and is not closed inside the plasma, it is polarized. Plasma obeys gas laws, but when a magnetic field is applied, which regulates the movement of charged particles, it exhibits properties that are completely unusual for a gas. In a strong magnetic field, particles begin to spin around the lines of force, and along the magnetic field they move freely. It is said that this helical motion shifts the structure of the field lines and the field is "frozen" into the plasma. A rarefied plasma is described by a system of particles, while a denser plasma is described by a fluid model.

The high electrical conductivity of plasma is its main difference from gas. The conductivity of cold plasma on the surface of the Sun (0.8 10 -19 J) reaches the conductivity of metals, and at thermonuclear temperature (1.6 10 -15 J) hydrogen plasma conducts current 20 times better than copper under normal conditions. Since plasma is capable of conducting current, the model of a conducting liquid is often applied to it. It is considered a continuous medium, although compressibility distinguishes it from an ordinary liquid, but this difference is manifested only in flows whose speed is greater than the speed of sound. The behavior of a conductive fluid is studied in a science called magnetic hydrodynamics. In space, any plasma is an ideal conductor, and the laws of the frozen field are widely used. The model of a conducting fluid makes it possible to understand the mechanism of plasma confinement by a magnetic field. Thus, plasma streams are ejected from the Sun, affecting the Earth's atmosphere. The flow itself does not have a magnetic field, but an extraneous field cannot penetrate into it according to the freezing law. Plasma solar streams push extraneous interplanetary magnetic fields out of the vicinity of the Sun. A magnetic cavity appears, where the field is weaker. When these corpuscular plasma flows approach the Earth, they collide with the Earth's magnetic field and are forced to flow around it according to the same law. It turns out a kind of cavern where the magnetic field is collected and where plasma flows do not penetrate. Charged particles accumulate on its surface, which were detected by rockets and satellites - this is the outer radiation belt of the Earth. These ideas were also used in solving problems of plasma confinement by a magnetic field in special devices - tokamaks (from the abbreviation of words: toroidal chamber, magnet). With fully ionized plasma held in these and other systems, hopes are pinned for obtaining a controlled thermonuclear reaction on Earth. This would provide a clean and cheap source of energy (sea water). Work is also underway to obtain and retain plasma using focused laser radiation.

The most widespread knowledge is about three states of aggregation: liquid, solid, gaseous, sometimes they think about plasma, less often liquid crystal. Recently, a list of 17 phases of matter, taken from the famous () Stephen Fry, has spread on the Internet. Therefore, we will talk about them in more detail, because. one should know a little more about matter, if only in order to better understand the processes taking place in the Universe.

The list of aggregate states of matter given below increases from the coldest states to the hottest, and so on. may be continued. At the same time, it should be understood that from the gaseous state (No. 11), the most “expanded”, on both sides of the list, the degree of compression of the substance and its pressure (with some reservations for such unexplored hypothetical states as quantum, ray, or weakly symmetric) increase. After the text a visual graph of the phase transitions of matter is given.

1. Quantum- the state of aggregation of matter, achieved when the temperature drops to absolute zero, as a result of which internal bonds disappear and matter crumbles into free quarks.

2. Bose-Einstein condensate- the aggregate state of matter, which is based on bosons cooled to temperatures close to absolute zero (less than a millionth of a degree above absolute zero). In such a strongly cooled state, a sufficiently large number of atoms find themselves in their minimum possible quantum states, and quantum effects begin to manifest themselves at the macroscopic level. Bose-Einstein condensate (often referred to as "Bose condensate", or simply "back") occurs when you cool a chemical element to extremely low temperatures (usually just above absolute zero, minus 273 degrees Celsius). , is the theoretical temperature at which everything stops moving).
This is where strange things start to happen. Processes normally only observable at the atomic level now occur on scales large enough to be observed with the naked eye. For example, if you put a "back" in a beaker and provide the desired temperature, the substance will begin to crawl up the wall and eventually get out on its own.
Apparently, here we are dealing with a futile attempt by matter to lower its own energy (which is already at the lowest of all possible levels).
Slowing down atoms using cooling equipment produces a singular quantum state known as a Bose condensate, or Bose-Einstein. This phenomenon was predicted in 1925 by A. Einstein, as a result of a generalization of the work of S. Bose, where statistical mechanics was built for particles, ranging from massless photons to atoms with mass (Einstein's manuscript, which was considered lost, was found in the library of Leiden University in 2005 ). The result of the efforts of Bose and Einstein was the Bose concept of a gas that obeys Bose-Einstein statistics, which describes the statistical distribution of identical particles with integer spin, called bosons. Bosons, which are, for example, both individual elementary particles - photons, and whole atoms, can be with each other in the same quantum states. Einstein suggested that cooling atoms - bosons to very low temperatures, would cause them to go (or, in other words, condense) into the lowest possible quantum state. The result of such condensation will be the emergence of a new form of matter.
This transition occurs below the critical temperature, which is for a homogeneous three-dimensional gas consisting of non-interacting particles without any internal degrees of freedom.

3. Fermionic condensate- the state of aggregation of a substance, similar to the backing, but differing in structure. When approaching absolute zero, atoms behave differently depending on the magnitude of their own angular momentum (spin). Bosons have integer spins, while fermions have spins that are multiples of 1/2 (1/2, 3/2, 5/2). Fermions obey the Pauli exclusion principle, which states that two fermions cannot have the same quantum state. For bosons, there is no such prohibition, and therefore they have the opportunity to exist in one quantum state and thereby form the so-called Bose-Einstein condensate. The process of formation of this condensate is responsible for the transition to the superconducting state.
Electrons have spin 1/2 and are therefore fermions. They combine into pairs (so-called Cooper pairs), which then form a Bose condensate.
American scientists attempted to obtain a kind of molecule from fermion atoms by deep cooling. The difference from real molecules was that there was no chemical bond between the atoms - they just moved together in a correlated manner. The bond between atoms turned out to be even stronger than between electrons in Cooper pairs. For the pairs of fermions formed, the total spin is no longer a multiple of 1/2, therefore, they already behave like bosons and can form a Bose condensate with a single quantum state. During the experiment, a gas of potassium-40 atoms was cooled to 300 nanokelvins, while the gas was enclosed in a so-called optical trap. Then an external magnetic field was applied, with the help of which it was possible to change the nature of interactions between atoms - instead of strong repulsion, strong attraction began to be observed. When analyzing the influence of the magnetic field, it was possible to find such a value at which the atoms began to behave like Cooper pairs of electrons. At the next stage of the experiment, scientists propose to obtain the effects of superconductivity for the fermionic condensate.

4. Superfluid matter- a state in which the substance has virtually no viscosity, and when flowing, it does not experience friction with a solid surface. The consequence of this is, for example, such an interesting effect as the complete spontaneous "creeping out" of superfluid helium from the vessel along its walls against gravity. Of course, there is no violation of the law of conservation of energy here. In the absence of friction forces, only gravity forces act on helium, forces of interatomic interaction between helium and the walls of the vessel and between helium atoms. So, the forces of interatomic interaction exceed all other forces combined. As a result, helium tends to spread as much as possible over all possible surfaces, and therefore "travels" along the walls of the vessel. In 1938, the Soviet scientist Pyotr Kapitsa proved that helium can exist in a superfluid state.
It is worth noting that many of the unusual properties of helium have been known for quite some time. However, in recent years, this chemical element has been “spoiling” us with interesting and unexpected effects. So, in 2004, Moses Chan and Eun-Syong Kim of the University of Pennsylvania intrigued the scientific world by claiming that they had succeeded in obtaining a completely new state of helium - a superfluid solid. In this state, some helium atoms in the crystal lattice can flow around others, and helium can thus flow through itself. The effect of "superhardness" was theoretically predicted back in 1969. And in 2004 - as if experimental confirmation. However, later and very curious experiments showed that everything is not so simple, and, perhaps, such an interpretation of the phenomenon, which was previously taken for the superfluidity of solid helium, is incorrect.
The experiment of scientists led by Humphrey Maris from Brown University in the USA was simple and elegant. The scientists placed a test tube turned upside down into a closed tank of liquid helium. Part of the helium in the test tube and in the tank was frozen in such a way that the boundary between liquid and solid inside the test tube was higher than in the tank. In other words, there was liquid helium in the upper part of the tube, solid helium in the lower part, it smoothly passed into the solid phase of the tank, over which a little liquid helium was poured - lower than the liquid level in the test tube. If liquid helium began to seep through solid, then the level difference would decrease, and then we can speak of solid superfluid helium. And in principle, in three out of 13 experiments, the level difference did decrease.

5. Superhard matter- a state of aggregation in which matter is transparent and can "flow" like a liquid, but in fact it is devoid of viscosity. Such liquids have been known for many years and are called superfluids. The fact is that if the superfluid is stirred, it will circulate almost forever, while the normal liquid will eventually calm down. The first two superfluids were created by researchers using helium-4 and helium-3. They were cooled almost to absolute zero - to minus 273 degrees Celsius. And from helium-4, American scientists managed to get a superhard body. They compressed the frozen helium by pressure more than 60 times, and then the glass filled with the substance was installed on a rotating disk. At a temperature of 0.175 degrees Celsius, the disk suddenly began to rotate more freely, which, according to scientists, indicates that helium has become a superbody.

6. Solid- the state of aggregation of matter, characterized by the stability of the form and the nature of the thermal motion of atoms, which make small vibrations around the equilibrium positions. The stable state of solids is crystalline. Distinguish solids with ionic, covalent, metallic, and other types of bonds between atoms, which determines the variety of their physical properties. The electrical and some other properties of solids are mainly determined by the nature of the motion of the outer electrons of its atoms. According to their electrical properties, solids are divided into dielectrics, semiconductors, and metals; according to their magnetic properties, they are divided into diamagnets, paramagnets, and bodies with an ordered magnetic structure. The investigations of the properties of solids have united into a large field—solid-state physics, the development of which is being stimulated by the needs of technology.

7. Amorphous solid- a condensed state of aggregation of a substance, characterized by the isotropy of physical properties due to the disordered arrangement of atoms and molecules. In amorphous solids, atoms vibrate around randomly located points. Unlike the crystalline state, the transition from a solid amorphous to liquid occurs gradually. Various substances are in the amorphous state: glasses, resins, plastics, etc.

8. Liquid crystal- this is a specific state of aggregation of a substance in which it simultaneously exhibits the properties of a crystal and a liquid. We must immediately make a reservation that not all substances can be in the liquid crystal state. However, some organic substances with complex molecules can form a specific state of aggregation - liquid crystal. This state is carried out during the melting of crystals of certain substances. When they melt, a liquid-crystalline phase is formed, which differs from ordinary liquids. This phase exists in the range from the melting temperature of the crystal to some higher temperature, when heated to which the liquid crystal transforms into an ordinary liquid.
How does a liquid crystal differ from a liquid and an ordinary crystal and how is it similar to them? Like an ordinary liquid, a liquid crystal has fluidity and takes the form of a vessel in which it is placed. In this it differs from the crystals known to all. However, despite this property, which unites it with a liquid, it has a property characteristic of crystals. This is the ordering in space of the molecules that form the crystal. True, this ordering is not as complete as in ordinary crystals, but, nevertheless, it significantly affects the properties of liquid crystals, which distinguishes them from ordinary liquids. The incomplete spatial ordering of the molecules that form a liquid crystal manifests itself in the fact that in liquid crystals there is no complete order in the spatial arrangement of the centers of gravity of the molecules, although there may be a partial order. This means that they do not have a rigid crystal lattice. Therefore, liquid crystals, like ordinary liquids, have the property of fluidity.
An obligatory property of liquid crystals, which brings them closer to ordinary crystals, is the presence of an order in the spatial orientation of molecules. Such an order in orientation can manifest itself, for example, in the fact that all long axes of molecules in a liquid crystal sample are oriented in the same way. These molecules should have an elongated shape. In addition to the simplest named ordering of the axes of molecules, a more complex orientational order of molecules can be realized in a liquid crystal.
Depending on the type of ordering of the molecular axes, liquid crystals are divided into three types: nematic, smectic and cholesteric.
Research on the physics of liquid crystals and their applications is currently being carried out on a wide front in all the most developed countries of the world. Domestic research is concentrated both in academic and industrial research institutions and has a long tradition. The works of V.K. Frederiks to V.N. Tsvetkov. In recent years, the rapid study of liquid crystals, Russian researchers also make a significant contribution to the development of the theory of liquid crystals in general and, in particular, the optics of liquid crystals. So, the works of I.G. Chistyakova, A.P. Kapustina, S.A. Brazovsky, S.A. Pikina, L.M. Blinov and many other Soviet researchers are widely known to the scientific community and serve as the foundation for a number of effective technical applications of liquid crystals.
The existence of liquid crystals was established a very long time ago, namely in 1888, that is, almost a century ago. Although scientists had encountered this state of matter before 1888, it was officially discovered later.
The first to discover liquid crystals was the Austrian botanist Reinitzer. Investigating the new substance cholesteryl benzoate synthesized by him, he found that at a temperature of 145 ° C, the crystals of this substance melt, forming a cloudy liquid that strongly scatters light. With continued heating, upon reaching a temperature of 179 ° C, the liquid becomes clear, that is, it begins to behave optically like an ordinary liquid, such as water. Cholesteryl benzoate showed unexpected properties in the turbid phase. Examining this phase under a polarizing microscope, Reinitzer found that it has birefringence. This means that the refractive index of light, that is, the speed of light in this phase, depends on the polarization.

9. Liquid- the state of aggregation of a substance, combining the features of a solid state (conservation of volume, a certain tensile strength) and a gaseous state (shape variability). A liquid is characterized by a short-range order in the arrangement of particles (molecules, atoms) and a small difference in the kinetic energy of the thermal motion of molecules and their potential energy of interaction. The thermal motion of liquid molecules consists of oscillations around equilibrium positions and relatively rare jumps from one equilibrium position to another, which is associated with the fluidity of the liquid.

10. Supercritical fluid(GFR) is the state of aggregation of a substance, in which the difference between the liquid and gas phases disappears. Any substance at a temperature and pressure above the critical point is a supercritical fluid. The properties of a substance in the supercritical state are intermediate between its properties in the gas and liquid phases. Thus, SCF has a high density, close to liquid, and low viscosity, like gases. The diffusion coefficient in this case has an intermediate value between liquid and gas. Substances in the supercritical state can be used as substitutes for organic solvents in laboratory and industrial processes. Supercritical water and supercritical carbon dioxide have received the greatest interest and distribution in connection with certain properties.
One of the most important properties of the supercritical state is the ability to dissolve substances. By changing the temperature or pressure of the fluid, one can change its properties in a wide range. Thus, it is possible to obtain a fluid whose properties are close to either a liquid or a gas. Thus, the dissolving power of a fluid increases with increasing density (at a constant temperature). Since the density increases with increasing pressure, changing the pressure can affect the dissolving power of the fluid (at a constant temperature). In the case of temperature, the dependence of fluid properties is somewhat more complicated - at a constant density, the dissolving power of the fluid also increases, but near the critical point, a slight increase in temperature can lead to a sharp drop in density, and, accordingly, dissolving power. Supercritical fluids mix with each other indefinitely, so when the critical point of the mixture is reached, the system will always be single-phase. The approximate critical temperature of a binary mixture can be calculated as the arithmetic mean of the critical parameters of the substances Tc(mix) = (mole fraction of A) x TcA + (mole fraction of B) x TcB.

11. Gaseous- (French gaz, from Greek chaos - chaos), the aggregate state of matter in which the kinetic energy of the thermal motion of its particles (molecules, atoms, ions) significantly exceeds the potential energy of interactions between them, and therefore the particles move freely, uniformly filling in the absence of external fields, the entire volume provided to them.

12. Plasma- (from the Greek plasma - fashioned, shaped), a state of matter, which is an ionized gas, in which the concentrations of positive and negative charges are equal (quasi-neutrality). The vast majority of matter in the Universe is in the plasma state: stars, galactic nebulae and the interstellar medium. Near the Earth, plasma exists in the form of the solar wind, magnetosphere, and ionosphere. High-temperature plasma (T ~ 106 - 108 K) from a mixture of deuterium and tritium is being investigated with the aim of implementing controlled thermonuclear fusion. Low-temperature plasma (T Ј 105K) is used in various gas-discharge devices (gas lasers, ion devices, MHD generators, plasma torches, plasma engines, etc.), as well as in technology (see Plasma metallurgy, Plasma drilling, Plasma technology) .

13. Degenerate matter- is an intermediate stage between plasma and neutronium. It is observed in white dwarfs and plays an important role in the evolution of stars. When atoms are under conditions of extremely high temperatures and pressures, they lose their electrons (they go into an electron gas). In other words, they are completely ionized (plasma). The pressure of such a gas (plasma) is determined by the electron pressure. If the density is very high, all particles are forced to approach each other. Electrons can be in states with certain energies, and two electrons cannot have the same energy (unless their spins are opposite). Thus, in a dense gas, all lower energy levels turn out to be filled with electrons. Such a gas is called degenerate. In this state, the electrons exhibit a degenerate electron pressure that opposes the forces of gravity.

14. Neutronium— state of aggregation into which matter passes under ultrahigh pressure, which is unattainable in the laboratory yet, but exists inside neutron stars. During the transition to the neutron state, the electrons of matter interact with protons and turn into neutrons. As a result, matter in the neutron state consists entirely of neutrons and has a density of the order of nuclear. The temperature of the substance in this case should not be too high (in energy equivalent, not more than a hundred MeV).
With a strong increase in temperature (hundreds of MeV and above), in the neutron state, various mesons begin to be born and annihilate. With a further increase in temperature, deconfinement occurs, and the matter passes into the state of quark-gluon plasma. It no longer consists of hadrons, but of constantly born and disappearing quarks and gluons.

15. Quark-gluon plasma(chromoplasm) is an aggregate state of matter in high-energy physics and elementary particle physics, in which hadronic matter passes into a state similar to the state in which electrons and ions are in ordinary plasma.
Usually the matter in hadrons is in the so-called colorless ("white") state. That is, quarks of different colors compensate each other. A similar state exists in ordinary matter - when all atoms are electrically neutral, that is,
positive charges in them are compensated by negative ones. At high temperatures, ionization of atoms can occur, while the charges are separated, and the substance becomes, as they say, "quasi-neutral". That is, the entire cloud of matter as a whole remains neutral, and its individual particles cease to be neutral. Presumably, the same thing can happen with hadronic matter - at very high energies, color is released and makes the substance "quasi-colorless".
Presumably, the matter of the Universe was in the state of quark-gluon plasma in the first moments after the Big Bang. Now quark-gluon plasma can be formed for a short time in collisions of particles of very high energies.
Quark-gluon plasma was obtained experimentally at the RHIC accelerator at Brookhaven National Laboratory in 2005. The maximum plasma temperature of 4 trillion degrees Celsius was obtained there in February 2010.

16. Strange substance- state of aggregation, in which matter is compressed to the limit values ​​of density, it can exist in the form of "quark soup". A cubic centimeter of matter in this state would weigh billions of tons; besides, it will turn any normal substance with which it comes into contact into the same "strange" form with the release of a significant amount of energy.
The energy that can be released during the transformation of the substance of the core of a star into a "strange substance" will lead to a super-powerful explosion of a "quark nova" - and, according to Leahy and Wyed, it was precisely this explosion that astronomers observed in September 2006.
The process of formation of this substance began with an ordinary supernova, into which a massive star turned. As a result of the first explosion, a neutron star was formed. But, according to Leahy and Wyed, it did not last long - as its rotation seemed to be slowed down by its own magnetic field, it began to shrink even more, with the formation of a clot of "strange stuff", which led to an even more powerful than in a normal supernova explosion, the release of energy - and the outer layers of the substance of the former neutron star, flying into the surrounding space at a speed close to the speed of light.

17. Strongly symmetrical matter- this is a substance compressed to such an extent that the microparticles inside it are layered on top of each other, and the body itself collapses into a black hole. The term "symmetry" is explained as follows: Let's take the aggregate states of matter known to everyone from the school bench - solid, liquid, gaseous. For definiteness, consider an ideal infinite crystal as a solid. It has a certain, so-called discrete symmetry with respect to translation. This means that if the crystal lattice is shifted by a distance equal to the interval between two atoms, nothing will change in it - the crystal will coincide with itself. If the crystal is melted, then the symmetry of the resulting liquid will be different: it will increase. In a crystal, only points that were distant from each other at certain distances, the so-called nodes of the crystal lattice, in which identical atoms were located, were equivalent.
The liquid is homogeneous throughout its volume, all its points are indistinguishable from one another. This means that liquids can be displaced by any arbitrary distances (and not just by some discrete ones, as in a crystal) or rotated by any arbitrary angles (which cannot be done in crystals at all) and it will coincide with itself. Its degree of symmetry is higher. The gas is even more symmetrical: the liquid occupies a certain volume in the vessel and there is an asymmetry inside the vessel, where there is liquid, and points where it is not. The gas, on the other hand, occupies the entire volume provided to it, and in this sense all its points are indistinguishable from one another. Nevertheless, it would be more correct to speak here not about points, but about small, but macroscopic elements, because at the microscopic level there are still differences. At some points in time there are atoms or molecules, while others do not. Symmetry is observed only on average, either in some macroscopic volume parameters, or in time.
But there is still no instantaneous symmetry at the microscopic level. If the substance is compressed very strongly, to pressures that are unacceptable in everyday life, compressed so that the atoms were crushed, their shells penetrated each other, and the nuclei began to touch, symmetry arises at the microscopic level. All nuclei are the same and pressed against each other, there are not only interatomic, but also internuclear distances, and the substance becomes homogeneous (strange substance).
But there is also a submicroscopic level. Nuclei are made up of protons and neutrons that move around inside the nucleus. There is also some space between them. If you continue to compress so that the nuclei are also crushed, the nucleons will tightly press against each other. Then, at the submicroscopic level, symmetry will appear, which is not even inside ordinary nuclei.
From what has been said, one can see a quite definite trend: the higher the temperature and the higher the pressure, the more symmetrical the substance becomes. Based on these considerations, the substance compressed to the maximum is called strongly symmetrical.

18. Weakly symmetrical matter- a state opposite to strongly symmetrical matter in its properties, which was present in the very early Universe at a temperature close to the Planck temperature, perhaps 10-12 seconds after the Big Bang, when strong, weak and electromagnetic forces were a single superforce. In this state, the matter is compressed to such an extent that its mass is converted into energy, which begins to inflate, that is, expand indefinitely. It is not yet possible to achieve energies for the experimental production of superpower and the transfer of matter to this phase under terrestrial conditions, although such attempts were made at the Large Hadron Collider in order to study the early universe. Due to the absence of gravitational interaction in the composition of the superforce that forms this substance, the superforce is not sufficiently symmetrical in comparison with the supersymmetric force, which contains all 4 types of interactions. Therefore, this state of aggregation received such a name.

19. Radiation matter- this, in fact, is no longer a substance, but energy in its purest form. However, it is this hypothetical state of aggregation that a body that has reached the speed of light will take. It can also be obtained by heating the body to the Planck temperature (1032K), that is, by dispersing the molecules of the substance to the speed of light. As follows from the theory of relativity, when the speed reaches more than 0.99 s, the mass of the body begins to grow much faster than with "normal" acceleration, in addition, the body lengthens, warms up, that is, it begins to radiate in the infrared spectrum. When crossing the threshold of 0.999 s, the body changes dramatically and begins a rapid phase transition up to the beam state. As follows from Einstein's formula, taken in full, the growing mass of the final substance is made up of masses that are separated from the body in the form of thermal, X-ray, optical and other radiation, the energy of each of which is described by the next term in the formula. Thus, a body approaching the speed of light will begin to radiate in all spectra, grow in length and slow down in time, thinning to the Planck length, that is, upon reaching speed c, the body will turn into an infinitely long and thin beam moving at the speed of light and consisting of photons that have no length, and its infinite mass will completely turn into energy. Therefore, such a substance is called radiation.