Most people can easily name the three classical states of matter: liquid, solid, and gas. Those who know a little science will add plasma to these three. But over time, scientists have expanded the list of possible states of matter beyond these four.
Amorphous and solid
Amorphous solids are a rather interesting subset of the well-known solid state. In a normal solid object, the molecules are well organized and don't have much room to move. This gives the solid a high viscosity, which is a measure of resistance to flow. Liquids, on the other hand, have a disorganized molecular structure that allows them to flow, spread, change shape, and take on the shape of the container they are in. Amorphous solids are somewhere in between these two states. During the process of vitrification, liquids cool and their viscosity increases until the substance no longer flows like a liquid, but its molecules remain disordered and do not take on a crystalline structure like normal solids.
The most common example of an amorphous solid is glass. For thousands of years, people have made glass from silicon dioxide. When glassmakers cool silica from its liquid state, it does not actually solidify when it drops below its melting point. As the temperature drops, the viscosity increases and the substance appears harder. However, its molecules still remain disordered. And then the glass becomes amorphous and hard at the same time. This transitional process allowed artisans to create beautiful and surreal glass structures.
What is the functional difference between amorphous solids and the normal solid state? In everyday life it is not particularly noticeable. Glass appears completely solid until you study it at the molecular level. And the myth that glass drips over time is not worth a penny. Most often, this myth is supported by the argument that old glass in churches seems thicker at the bottom, but this is due to imperfections in the glassblowing process at the time the glass was created. However, studying amorphous solids like glass is interesting from a scientific point of view for studying phase transitions and molecular structure.
Supercritical fluids (fluids)
Most phase transitions occur at a certain temperature and pressure. It is common knowledge that an increase in temperature eventually turns a liquid into a gas. However, when pressure increases along with temperature, the liquid makes the leap into the realm of supercritical fluids, which have the properties of both a gas and a liquid. For example, supercritical fluids can pass through solids like a gas, but can also act as a solvent like a liquid. Interestingly, a supercritical fluid can be made more like a gas or more like a liquid, depending on the combination of pressure and temperature. This has allowed scientists to find many applications for supercritical fluids.
Although supercritical fluids are not as common as amorphous solids, you probably interact with them just as often as you interact with glass. Supercritical carbon dioxide is loved by brewing companies for its ability to act as a solvent when reacting with hops, and coffee companies use it to make the best decaf coffee. Supercritical fluids have also been used to make hydrolysis more efficient and to allow power plants to operate at higher temperatures. In general, you probably use supercritical fluid byproducts every day.
Degenerate gas
While amorphous solids are at least found on planet Earth, degenerate matter is only found in certain types of stars. A degenerate gas exists when the external pressure of a substance is determined not by temperature, as on Earth, but by complex quantum principles, in particular the Pauli principle. Because of this, the external pressure of the degenerate substance will be maintained even if the temperature of the substance drops to absolute zero. Two main types of degenerate matter are known: electron-degenerate and neutron-degenerate matter.
Electronically degenerate matter exists mainly in white dwarfs. It forms in the core of a star when the mass of matter around the core tries to compress the core's electrons to a lower energy state. However, according to the Pauli principle, two identical particles cannot be in the same energy state. Thus, the particles "push" the matter around the nucleus, creating pressure. This is only possible if the star's mass is less than 1.44 solar masses. When a star exceeds this limit (known as the Chandrasekhar limit), it simply collapses into a neutron star or black hole.
When a star collapses and becomes a neutron star, it no longer has electron-degenerate matter, it is made of neutron-degenerate matter. Because a neutron star is heavy, electrons fuse with protons in its core to form neutrons. Free neutrons (neutrons not bound in the atomic nucleus) have a half-life of 10.3 minutes. But in the core of a neutron star, the mass of the star allows neutrons to exist outside the cores, forming neutron-degenerate matter.
Other exotic forms of degenerate matter may also exist, including strange matter, which can exist in the rare stellar form of quark stars. Quark stars are a stage between a neutron star and a black hole, where the quarks in the core are decoupled and form a soup of free quarks. We have not yet observed this type of star, but physicists admit their existence.
Superfluidity
Let's return to Earth to discuss superfluids. Superfluidity is a state of matter that exists in certain isotopes of helium, rubidium and lithium cooled to near absolute zero. This state is similar to a Bose-Einstein condensate (Bose-Einstein condensate, BEC), with a few differences. Some BECs are superfluids, and some superfluids are BECs, but not all are identical.
Liquid helium is known for its superfluidity. When helium is cooled to the "lambda point" of -270 degrees Celsius, part of the liquid becomes superfluid. If you cool most substances to a certain point, the attraction between atoms overcomes the thermal vibrations in the substance, allowing them to form a solid structure. But helium atoms interact with each other so weakly that they can remain liquid at a temperature of almost absolute zero. It turns out that at this temperature the characteristics of individual atoms overlap, giving rise to strange superfluidity properties.
Superfluids have no internal viscosity. Superfluids placed in a test tube begin to creep up the sides of the test tube, seemingly defying the laws of gravity and surface tension. Liquid helium leaks easily because it can slip through even microscopic holes. Superfluidity also has strange thermodynamic properties. In this state, substances have zero thermodynamic entropy and infinite thermal conductivity. This means that two superfluids cannot be thermally distinct. If you add heat to a superfluid substance, it will conduct it so quickly that heat waves are formed that are not characteristic of ordinary liquids.
Bose-Einstein condensate
The Bose-Einstein condensate is probably one of the most famous obscure forms of matter. First, we need to understand what bosons and fermions are. A fermion is a particle with half-integer spin (like an electron) or a composite particle (like a proton). These particles obey the Pauli exclusion principle, which allows electron-degenerate matter to exist. A boson, however, has full integer spin, and several bosons can occupy the same quantum state. Bosons include any force-carrying particles (such as photons), as well as some atoms, including helium-4 and other gases. Elements in this category are known as bosonic atoms.
In the 1920s, Albert Einstein built on the work of Indian physicist Satyendra Nath Bose to propose a new form of matter. Einstein's original theory was that if you cooled certain elemental gases to a temperature a fraction of a degree above absolute zero, their wave functions would merge, creating one "superatom." Such a substance will exhibit quantum effects at the macroscopic level. But it wasn't until the 1990s that the technologies needed to cool elements to such temperatures emerged. In 1995, scientists Eric Cornell and Carl Wieman were able to combine 2,000 atoms into a Bose-Einstein condensate that was large enough to be seen with a microscope.
Bose-Einstein condensates are closely related to superfluids, but also have their own set of unique properties. It's also funny that BEC can slow down the normal speed of light. In 1998, Harvard scientist Lene Howe was able to slow light to 60 kilometers per hour by shining a laser through a cigar-shaped BEC sample. In later experiments, Howe's group was able to completely stop the light in the BEC by turning off the laser as the light passed through the sample. These experiments opened up a new field of light-based communications and quantum computing.
Jahn-Teller metals
Jahn-Teller metals are the newest baby in the world of states of matter, as scientists were only able to successfully create them for the first time in 2015. If the experiments are confirmed by other laboratories, these metals could change the world, since they have the properties of both an insulator and a superconductor.
Scientists led by chemist Cosmas Prassides experimented by introducing rubidium into the structure of carbon-60 molecules (commonly known as fullerenes), which caused the fullerenes to take on a new form. This metal is named after the Jahn–Teller effect, which describes how pressure can change the geometric shape of molecules into new electronic configurations. In chemistry, pressure is achieved not only by compressing something, but also by adding new atoms or molecules to a pre-existing structure, changing its basic properties.
When Prassides' research group began adding rubidium to carbon-60 molecules, the carbon molecules changed from insulators to semiconductors. However, due to the Jahn–Teller effect, the molecules tried to stay in the old configuration, creating a substance that tried to be an insulator but had the electrical properties of a superconductor. The transition between insulator and superconductor had never been considered until these experiments began.
The interesting thing about Jahn-Teller metals is that they become superconductors at high temperatures (-135 degrees Celsius, rather than the usual 243.2 degrees). This brings them closer to acceptable levels for mass production and experimentation. If confirmed, we may be one step closer to creating superconductors that operate at room temperature, which in turn will revolutionize many areas of our lives.
Photonic matter
For many decades, it was believed that photons were massless particles that did not interact with each other. However, over the past few years, scientists at MIT and Harvard have discovered new ways to "give" light mass—and even create "light molecules" that bounce off each other and bond together. Some considered this to be the first step towards creating a lightsaber.
The science of photonic matter is a little more complicated, but it is quite possible to comprehend. Scientists began creating photonic matter by experimenting with supercooled rubidium gas. When a photon shoots through the gas, it reflects and interacts with rubidium molecules, losing energy and slowing down. After all, the photon leaves the cloud very slowly.
Strange things start to happen when you pass two photons through a gas, creating a phenomenon known as Rydberg block. When an atom is excited by a photon, nearby atoms cannot be excited to the same degree. The excited atom finds itself in the path of the photon. For an atom nearby to be excited by a second photon, the first photon must pass through the gas. Photons do not normally interact with each other, but when they encounter a Rydberg block, they push each other through the gas, exchanging energy and interacting with each other. From the outside, photons appear to have mass and act as a single molecule, although they are actually massless. When the photons come out of the gas, they appear to come together, like a molecule of light.
The practical application of photonic matter is still in question, but it will certainly be found. Perhaps even lightsabers.
Disordered superuniformity
When trying to determine whether a substance is in a new state, scientists look at the structure of the substance as well as its properties. In 2003, Salvatore Torquato and Frank Stillinger of Princeton University proposed a new state of matter known as disordered superuniformity. Although this phrase seems like an oxymoron, at its core it suggests a new type of substance that appears disordered when viewed closely, but is hyper-uniform and structured from afar. Such a substance must have the properties of a crystal and a liquid. At first glance, this already exists in plasmas and liquid hydrogen, but recently scientists discovered a natural example where no one expected: in a chicken eye.
Chickens have five cones in their retina. Four detect color and one is responsible for light levels. However, unlike the human eye or the hexagonal eyes of insects, these cones are randomly distributed, with no real order. This happens because the cones in a chicken's eye have exclusion zones around them, and these do not allow two cones of the same type to be close together. Due to the exclusion zone and shape of the cones, they cannot form ordered crystalline structures (as in solids), but when all the cones are considered as one, they appear to have a highly ordered pattern, as seen in the Princeton images below. Thus, we can describe these cones in the retina of a chicken eye as a liquid when viewed closely and as a solid substance when viewed from afar. This is different from the amorphous solids we talked about above because this super-homogeneous material will act as a liquid while an amorphous solid will not.
Scientists are still investigating this new state of matter because it may also be more common than originally thought. Now scientists at Princeton University are trying to adapt such superhomogeneous materials to create self-organizing structures and light detectors that respond to light of a specific wavelength.
String networks
What state of matter is the vacuum of space? Most people don't think about it, but in the last ten years, Xiao Gang-Wen of MIT and Michael Levine of Harvard have proposed a new state of matter that could lead us to the discovery of fundamental particles beyond the electron.
The path to developing a string-network fluid model began in the mid-90s, when a group of scientists proposed so-called quasiparticles, which seemed to appear in an experiment when electrons passed between two semiconductors. There was a commotion because the quasiparticles acted as if they had a fractional charge, which seemed impossible for the physics of that time. Scientists analyzed the data and suggested that the electron is not a fundamental particle of the Universe and that there are fundamental particles that we have not yet discovered. This work brought them the Nobel Prize, but later it turned out that an error in the experiment had crept into the results of their work. Quasiparticles were conveniently forgotten.
But not all. Wen and Levin took the idea of quasiparticles as a basis and proposed a new state of matter, the string-net state. The main property of such a state is quantum entanglement. As with disordered superuniformity, if you look at string-net matter up close, it looks like a disordered collection of electrons. But if you look at it as a whole structure, you will see high order due to the quantum entangled properties of the electrons. Wen and Lewin then expanded their work to cover other particles and entanglement properties.
Working through computer models of the new state of matter, Wen and Levin discovered that the ends of the string nets could produce a variety of subatomic particles, including the legendary "quasiparticles." An even bigger surprise was that when the string-network material vibrates, it does so in accordance with Maxwell's equations for light. Wen and Levin proposed that the cosmos is filled with string networks of entangled subatomic particles, and that the ends of these string networks represent the subatomic particles that we observe. They also suggested that the string-net fluid could provide the existence of light. If the vacuum of space is filled with string-net fluid, it could allow us to combine light and matter.
This may all seem very far-fetched, but in 1972 (decades before the string-net proposals), geologists discovered a strange material in Chile - herbertsmithite. In this mineral, electrons form triangular structures that seem to contradict everything we know about how electrons interact with each other. Additionally, this triangular structure was predicted by the string-network model, and the scientists worked with artificial herbertsmithite to accurately confirm the model.
Quark-gluon plasma
Speaking of the last state of matter on this list, consider the state that started it all: quark-gluon plasma. In the early Universe, the state of matter differed significantly from the classical one. First, a little background.
Quarks are elementary particles that we find inside hadrons (such as protons and neutrons). Hadrons consist of either three quarks or one quark and one antiquark. Quarks have fractional charges and are held together by gluons, which are exchange particles of the strong nuclear force.
We don't see free quarks in nature, but right after the Big Bang, free quarks and gluons existed for a millisecond. During this time, the temperature of the Universe was so high that quarks and gluons moved at almost the speed of light. During this period, the Universe consisted entirely of this hot quark-gluon plasma. After another fraction of a second, the Universe cooled enough for heavy particles like hadrons to form, and quarks began to interact with each other and gluons. From that moment on, the formation of the Universe we know began, and hadrons began to bond with electrons, creating primitive atoms.
Already in the modern Universe, scientists have tried to recreate quark-gluon plasma in large particle accelerators. During these experiments, heavy particles such as hadrons collided with each other, creating a temperature at which the quarks separated for a short time. In the course of these experiments, we learned a lot about the properties of quark-gluon plasma, which was completely frictionless and more liquid-like than ordinary plasma. Experiments with exotic states of matter allow us to learn a lot about how and why our Universe formed as we know it.
Nov 15, 2017 Gennady
A team of physicists from the Center for Ultracold Atoms at Harvard University and the Massachusetts Institute of Technology (Harvard-MIT Center for Ultracold Atoms), led by our compatriot Mikhail Lukin, has obtained a previously unprecedented type of matter.
This substance, according to the authors of the study, contradicts scientists’ ideas about the nature of light. Photons are considered massless particles, unable to interact with each other. For example, if you direct two laser beams at each other, they will simply pass through without interacting with each other.
But this time Lukin and his team managed to experimentally refute this belief. They forced particles of light to form strong bonds with each other and even assemble into molecules. Previously, such molecules were only in theory.
“Photon molecules behave not like ordinary laser beams, but like something close to science fiction - Jedi lightsabers, for example,” Lukin says.
"Most of the described properties of light come from the belief that photons have no mass. That is why they do not interact with each other in any way. All we have done is create a special environment in which particles of light interact with each other so strongly that they begin to behave , as if they had mass, and form into molecules,” explains the physicist.
In creating photonic molecules, or rather, a medium suitable for their formation, Lukin and his colleagues could not count on the Force. They had to conduct a complex experiment with precise calculations, but absolutely amazing results.
To begin, the researchers placed rubidium atoms in a vacuum chamber and used lasers to cool the atomic cloud to just a few degrees above absolute zero. Then, creating very weak laser pulses, the scientists sent one photon at a time into the rubidium cloud.
"When photons enter a cloud of cold atoms, their energy causes the atoms to go into an excited state. As a result, the particles of light slow down. The photons move through the cloud, and the energy is transferred from atom to atom until it leaves the medium along with the photon itself. When In this case, the state of the environment remains the same as it was before the photon “visited,” says Lukin.
The study authors compare this process to the refraction of light in a glass of water. When a ray penetrates a medium, it gives it part of its energy, and inside the glass it represents a “bundle” between light and matter. But coming out of the glass, it is still light. Almost the same process takes place in Lukin’s experiment. The only physical difference is that the light slows down greatly and gives off more energy than during normal refraction in a glass of water.
At the next stage of the experiment, scientists sent two photons into the rubidium cloud. Imagine their surprise when they caught two photons bound into a molecule at the output. This can be called a unit of never-before-seen matter. But what is the reason for this connection?
The effect was previously described theoretically and is called Rydberg block. According to this model, when one atom is excited, other neighboring atoms cannot go into the same excited state. In practice, this means that when two photons enter a cloud of atoms, the first will excite the atom and move forward before the second photon excites neighboring atoms.
As a result, the two photons will push and pull each other as they pass through the cloud as their energy is transferred from one atom to the other.
“This is a photon interaction, which is mediated by atomic interaction. Thanks to this, two photons will behave like one molecule, rather than like two separate particles, when leaving the medium,” explains Lukin.
The authors of the study admit that they conducted this experiment more for fun, to test the strength of the fundamental boundaries of science. However, such an amazing discovery could have many practical applications.
For example, photons are the optimal carrier of quantum information; the only problem was the fact that light particles do not interact with each other. To build a quantum computer, it is necessary to create a system that will store units of quantum information and process it using quantum logical operations.
The problem is that such logic requires interaction between individual quanta in such a way that the systems switch and perform information processing.
"Our experiment proves that this is possible. But before we can build a quantum switch or photonic logic gate, we need to improve the performance of photonic molecules," says Lukin. Thus, the current result is only proof of the concept in practice.
The discovery of physicists will also be useful in the production of classical computers and computing machines. It will help solve a number of power loss problems faced by computer chip manufacturers.
In the distant future, Lukin's followers may one day be able to create a three-dimensional structure, like a crystal, made entirely of light.
A description of the experiment and the scientists’ conclusions can be read in the article by Lukin and his colleagues, published in the journal Nature.
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Rydberg atoms(named in honor of J.R. Rydberg) - hydrogen-like atoms and alkali metal atoms, in which the outer electron is in a highly excited state (up to levels n about 1000). To transfer an atom from the ground state to an excited state, it is irradiated with resonant laser light or a radio frequency discharge is initiated. The size of a Rydberg atom can exceed the size of the same atom in the ground state by almost 10 6 times for n = 1000 (see table below).
Electron rotating in an orbit of radius r around the nucleus, according to Newton's second law, experiences a force
From these two equations we obtain an expression for the orbital radius of an electron in the state n :
Where Ry = 13.6 eV is the Rydberg constant, and δ is the nuclear charge defect, which at large n insignificant. Energy difference between n-m and ( n+1)th energy levels is equal to
Characteristic size of an atom r n and the typical semiclassical period of revolution of an electron are equal
Wavelength of radiation of a hydrogen atom during transition from n′ = 91 on n = 90 equal to 3.4 cm.
When atoms are excited from the ground state to the Rydberg state, an interesting phenomenon occurs, called “dipole blockade”.
The coherent control of dipole blockade of Rydberg atoms by laser light makes them a promising candidate for the practical implementation of a quantum computer. According to scientific press reports, until 2009, the two-qubit gate, an important element for computing in a quantum computer, had not been experimentally implemented. However, there are reports of the observation of collective excitation and dynamic interaction between two atoms in mesoscopic samples.
Strongly interacting Rydberg atoms are characterized by quantum critical behavior, which ensures fundamental scientific interest in them regardless of applications.
Research related to the Rydberg states of atoms can be divided into two groups: the study of the atoms themselves and the use of their properties for other purposes.
In 2009, researchers managed to obtain the Rydberg molecule (English) .
The first experimental data on Rydberg atoms in radio astronomy were obtained in 1964 by R. S. Sorochenko et al. (FIAN) on a 22-meter reflecting radio telescope created to study the radiation of cosmic objects in the centimeter frequency range. When the telescope was oriented towards the Omega Nebula, in the spectrum of radio emission coming from this nebula, an emission line was detected at a wavelength λ ≃ 3.4 cm. This wavelength corresponds to the transition between Rydberg states n′ = 91 And n = 90 in the spectrum of a hydrogen atom
RYDBERG STATES- states of atoms, ions and molecules with large values of the main n(highly excited states). Named in honor of I.R. Rydberg, who was the first to experimentally study atomic spectra near the boundary.
R.s. atoms and ions are characterized by extremely small (on an atomic scale) ionization. potentials, long lifetimes (since the probability of radiative quantum transitions from them is small) and large radii of the orbits of a highly excited (Rydberg) electron. R.s. similar to the states of the hydrogen atom. Transitions between neighboring rivers. are in the radio range. Great importance P allows you to use R. s. to describe it. quasi-classical approximation and use classical concepts for them. mechanics. The large size of the orbits and low binding energies of the Rydbert electron determine the high sensitivity of the laser system. to the effects of electricity and mag. fields and large eff. cross sections for the interaction of atoms in R.S. with charged particles.
In table 1 shows the basic values. characteristics of atoms and atomic ions located in the R. s.
Table 1.
Systematic study of R. s. became possible from the beginning. 1970s thanks to success laser spectroscopy, which allowed research in the laboratory. conditions of R. s. with ha ~300, as well as radio astronomy, since absorption lines between R. s. were discovered in interstellar clouds. with 700 hectares.
Wave functions and energies of Rydberg states of atoms. Wave functions R.s. can be represented with good accuracy as the product of the wave functions of the Rydberg electron and the remaining atomic system - the atomic residue. Properties of the atom in R.s. are mainly determined by the wave function of a highly excited electron, which is its own. function:
where is the momentum operator, U(r) is the potential energy of interaction of a Rydberg electron with an atomic residue. At distances r electron from the atomic nucleus, many large atomic residues, U(r) transforms into the Coulomb potential: U(r) = Ze 2 /r.
Energy R. s. isolated atoms, measured from the ionization boundary, are determined by the Rydberg function:
Where M- mass of the atomic residue, - quantum defect, weakly dependent on n and for the orbital quantum number l> 2 very quickly decreasing with growth l. Values for S-, P- And D-states of alkali metal atoms are given in Table. 2.
Table 2.
Probabilities will be emitted. quantum transitions of the atom on the R.S. fall quickly with growth P And l. For insulated atom in R.s. with ha data and l lifetime . If the distribution of atoms over l thermodynamically equilibrium [~(2l + 1)], then the probability will be emitted. transitions between R. s. With n And n" is determined by the Kramers formula (with an error of less than 20%):
where are the level energies measured from the ionization boundary. Wed. the probability of transition from a given level to all other energy levels is the reciprocal of cf. lifetime of the system at this level.
Rydberg states in an electric field are fundamentally non-stationary - the atom is ionized by the field. However, for weak fields the probability of autoionization ( ionization field) is exponentially small and R. s. can be considered quasi-stationary. In electric field, highly excited energy levels experience Stark splitting and shift (see. Stark effect), their wave functions are their own. functions of the Hamiltonian:
Where H 0- Hamiltonian (1) of an atom in the absence of a field. If potential energy U(r)has a Coulomb nature (i.e. H 0- Hamiltonian of a hydrogen-like ion), then the Schrödinger equation corresponding to the Hamiltonian (4) is divided into a parabolic equation. coordinates Magnetic projection moment on the direction of the field is still the integral of motion. With an accuracy of second order perturbation theory, the energy of stationary states measured from the ionization boundary is given by the expression 
(n 1, n 2- parabolic quantum numbers satisfying the condition: n 1 + n 2 + 1 = n -
t, t- mag. quantum number). The expression fe-ro for the order of perturbation theory is given in. F-la (5) is also valid for R. s. in non-hydrogen-like atoms, if the scale of Stark splitting, determined by the second term, exceeds the energy difference between states with different 
. In Fig. Figure 1 shows, as an example, a diagram of the levels of Li in electricity. field. 
Rice. 1. Diagram of energy levels of a Li atom in an electric field for n ~ 15 (|m| = 1).
Probability of electrical ionization field of hydrogen-like atoms in R.s. asymptotic is determined. f-loy: 
The probability of ionization of an atom in the R.S. increases sharply when the electrical tension fields E approaches the value 
, with which autoionization is possible within the classical framework. mechanics.
Rydberg states in a magnetic field. Unlike ordinary weakly excited states, for which basic. paramagnetic plays a role. interaction of an atom with a magnet. field (see Seemap effect, Paschen - Baka effect), for atoms in R.s. Diamagn plays an important role. an interaction that grows very quickly with increasing p.r.s. in mag. the field is described by the Hamiltonian:
Where L and S are the total momentum and spin of the atom, respectively, IN- mag. induction, 
- Bohr magneton, - the angle between the radius vector of the Rydberg electron and the magnetic intensity vector. fields. The second term describes paramagnetic, and the third - diamagnetic interactions. For R. s. diamagn. interaction grows for high P becomes decisive. In weak fields the main The role is played by the second term, which gives a splitting into m-components with a characteristic value that is qualitatively the same as for weakly excited states. As the field strength increases, the diamagnetic contribution increases. interactions, which connect states with the same m l And 
. [For 4p state ( t = 1) in a hydrogen atom diamagn. and paramagnetic interactions are aligned when B = 2*10 7 G.] Each level with quantum numbers P And T splits into a component. With a further increase in field strength, levels with different P and the spectrum of hydrogen in magnesium. the field (Fig. 2) becomes similar to the spectrum of an atom in an electric field. field. In the case of extremely strong fields, main. interaction with magnet plays a role. field and R. s. are Landau states (see Landau levels).,The Coulomb interaction can be considered as a perturbation. 
Rice. 2. Diagram of the energy levels of the H atom in Rydberg states in a magnetic field (m = 1, even states).
Interaction of atoms in the Rydberg state with charged particles. Eff. cross sections s of quantum transitions in atoms located in the R.S. when colliding with charged particles (electrons, ions), they grow like a geom. cross section ~n 4 . For transitions with small 
basic The role is played by long-range dipole interaction, which leads to 
, and at high energies ext. particle dependence on energy is given by a multiplier (quantum logarithm!). With growth, the short-range interaction begins to play an increasingly important role, making it possible to neglect the field of the atomic residue during the collision process, and to consider the collision itself within the framework of the classical theory. mechanics. This approach, called classical. binary approximation, allows us to obtain 
; at high energies. In the Born approximation, the transition cross section in collisions with electrons is determined by f-loy (3):
Function for n = 100 is given in table. 3.
Table 3.
Transitions between R. s. in collisions with electrons are basic. the cause of additional (in addition to Doppler) inelastic broadening recombination radio links, observed from a number of astrophysics. objects (planetary nebulae, interstellar medium, NI zones, etc.).
B will collide. transitions between R. s. with the same P basic Ions usually play a role. Naib. the cross sections for transitions between neighboring levels due to dipole interaction are large. They are an order of magnitude or more superior to geom. section
Interaction of atoms in the Rydberg state with neutral atoms. If P is sufficiently large, then the cross section of the process of interaction of atoms in a reactive system. with neutral atoms is expressed through the amplitude of scattering of a free electron on a neutral atom and the amplitude of scattering of an atom on a positively charged atomic residue. For example, as a result of interaction with neutral atoms of R. s. experience broadening and shift proportional to the concentration of disturbing particles N:
coefficient are expressed through the amplitude of elastic scattering of an electron on an atom and the parameters of interaction of a neutral atom with an atomic residue and for sufficiently large P strive for constants; in the intermediate region their behavior can be very complex and depends on the specific type of perturbing particles. For Cs atoms in the R. system, perturbed, for example, by Ar atoms, asymptotic. values ,; if the perturbing atoms are Cs atoms, then it increases by 20 times, and by 2 orders of magnitude. Asimitotic coefficient values and are achieved when interacting with atoms of inert gases at , and when interacting with atoms of alkali metals at . Behavior of cross sections of other processes of interaction of atoms in R.S. with neutral atoms (mixing of states along l, disorientation, etc.) is qualitatively similar to the behavior of broadening cross sections.
Laboratory experiments. R.s. to the lab conditions are created most often by excitation of an atom from the base. states one or several. light beams of high intensity (at least at the first stage of excitation - pumping). For pumping, an N 2 laser or the second (third) harmonic of a neodymium glass laser is usually used. To receive R.s. with given quantum numbers p, l, t, at the second stage, the atomic system is excited by radiation from powerful tunable dye lasers.
To register R. s. max. The fluorescent method and the electrical ionization method have become widespread. field. The fluorescent method is based on the analysis of the cascade emission of light during atomic transitions from R.S. This method is selective, but the intensity of the detected radiation in the visible region is low in this case. The fluorescent method is used, as a rule, to study R. s. With P< 20.
In the electrical ionization method. The field detects electrons released as a result of the ionization of an atom in the electron beam. when exposed to electricity. fields. In this case, selectivity is ensured by the extremely sharp dependence of the ionization probability on quantum numbers P And T. Most often, this method is used in a time-resolved mode: after pulsed excitation of the R.S. a sawtooth electric pulse is supplied. fields. Each R. s. in time-resolved ionization. The signal gives a peak after a strictly defined time from the moment the field is turned on. The method is characterized by its simplicity, high sensitivity, and, unlike the fluorescent method, is especially effective in the study of R. s. with big P, when ionization does not require high electrical voltages. fields.
Spectra of atoms and ions in R.S. Various are being investigated. methods. Using conventional multimode lasers, a spectral resolution of the order of the Doppler level width is achieved, which makes it possible to study laser radiation. With . If higher resolution is required, then the method of crossed atomic-laser beams, which gives a resolution of several MHz, or nonlinear laser spectroscopy methods are used. For example, using two-photon spectroscopy, a spectrum with a resolution of the order of kHz was obtained. In cases where the intervals between adjacent R.s. are of interest, methods are more convenient radio spectroscopy,, quantum beats and level crossings (see. Interference of states). Instead of adjusting the radiation frequency to the transition frequency between radio stations, to a given external one. By using the field, the frequency can be adjusted by the radios themselves. In this case, R. s. allow you to amplify a weak microwave signal. This method obtained sensitivity in the millimeter range; there is reason to expect an increase in sensitivity by another 2 orders of magnitude.
Of particular interest are experiments with atoms in R.S. in resonators. For n~ 30 transitions between R.. s. lie in the millimeter range, for which there are resonators with very high . At the same time, the influence of electrical fields on atoms in R.s. more significantly than, for example, for molecular rotations. energy levels, therefore, with the help of R. s. For the first time, it was possible to demonstrate a number of quantum effects predicted in the 50s and 60s: suppression of spontaneous radiation. transcoding in the resonator, Rabi nutation - interaction with fields of one photon in, cooperative Dicke effects for several. atoms (see Superradiation)and etc. .
Astrophysical applications of Rydberg states. The first observations will emit transitions between R. s. from astrophysics objects (lines and) were made in the USSR. Radio emission lines corresponding to transitions between radio stations are observed up to n~ 300 from galactic. H II zones, planetary nebulae, central regions of our Galaxy and certain other galaxies. Lines He, He II, and C II were also detected. Basic mechanism of formation of R. s. in astrophysics objects is photorecombination, therefore radio emission lines are called. also recombinant. radio links. Radio links between R. s. play an important role in the diagnosis of astrophysis. objects. For P < 100 ширина таких линий обусловлена и позволяет судить о ионной темп-ре космич. плазмы. Для более высоких P collisions with electrons contribute to the broadening, etc. The width of radio lines can also be used to estimate electrons. The ratio of the intensities of radio lines and continuum gives the electronic temperature.
Radio absorption lines belonging to the C II ion and corresponding to transitions between radio waves have been discovered in interstellar clouds. With P > 700.
Lit.: 1) R y d b e r g J. R., “Z. Phys. Chem.”, 1890, Bd 5, S. 227; 2) Rydberg states of atoms and molecules, trans. from English, M., 1985; 3) Vainshtein L.A., Sobelman I.I., Yuk about in E.A., Excitation of atoms and, M., 1979; 4) Nagoye S., Raimond J. M., “Adv. in Atom. and Molec. Phys.”, 1985, v. 20, p. 347; 5) Sorochenko R.L., Recombination radio lines, in the book: Physics of Space, 2nd ed., M., 1986. I. L. Beigman,
Rydberg states of molecules. The highly excited electronic states of molecules, as well as the atomic ones, are similar to a series of states of the hydrogen atom. The Rydberg orbitals of molecules are denoted by the principal P and orbital l quantum numbers and group type symmetry of the molecule(eg. nsa 1, npb 1). Energy R. s. (measured from the molecular ionization boundary) is determined by the Rydberg function (2). For a molecule consisting of atoms of the first period, the value of the quantum defect for nd-orbitals are very small (0.1), for nр-orbitals are slightly higher (0.3-0.5), and for ns-orbitals are much larger (0.9-1.2). Stability of R. s. molecules depends on the stability of the base. state or low-lying excited state of a molecular ion resulting from the removal of a Rydberg electron, since the Rydberg orbital is, generally speaking, nonbonding. The stability of an ion depends on whether an electron is removed from a bonding, antibonding, or nonbonding molecular orbital. state of a neutral molecule. For example, for H 2 O from occupied molecular orbitals in the axis. the highest state is nonbonding molecular orbital 1 b 1. Therefore the main the state of the H 2 O + ion resulting from the removal of an electron from this orbital is as stable as the base. state of the H 2 O molecule: almost all R.s. molecules H 2 O converging to the base. state of the H 2 O + ion, stable.
If an electron moves from a low-lying to a higher molecular orbital with the same P, then the resulting states are called. Subrydberg and. Because P is not a well-defined quantum number for low molecular orbitals; sub-Rydberg states differ little from the R.s. molecules, although sub-Rydberg orbitals can also be bonding ones.
R.s. molecules differ from R. s. atoms ch. arr. due to vibrations, rotations and the possibility of dissociation of the ionic core of the molecule. If the ionic core is in an excited vibration. state, then a Rydberg electron, when penetrating into the ion core (which happens quite rarely, with probability), can experience an inelastic collision with the core, acquire sufficient kinetic. energy due to vibrations. core energy and lead to ionization of the molecule, called. vibrational autoionization. The autoionization process is also possible due to rotation. Highly excited R. s. molecules usually lie so close that the energy the interval between them is of the same order or even less than the quantum of oscillation. or rotate. molecular energy. Therefore, often the separation of electronic and nuclear motions, adopted in the Bern-Oppenheimer approximation, for molecules in R.S. becomes unusable.
Lit.: Herzberg G., Electronic spectra and structure of polyatomic molecules, trans. from English, M., 1969; Rydberg states of atoms and molecules, ed. R. Stebbings, F. Dunwing, trans. from English, M., 1985. M. R. Aliyev.
Mikhail Lukin, a professor of physics at Harvard University, and Vladan Vuletic, his colleague from Serbia, a professor of physics at the Massachusetts Institute of Technology, in a unique experiment, were able to force quanta of electromagnetic radiation to bind and form a completely new state of matter, like a molecule. Their work is described in the September 25, 2013 issue of Nature.
The probability of the existence of such matter has so far been studied only theoretically.
Such a theory, according to the authors, contradicts basic ideas about the nature of light.
It is a generally accepted fact that photons are massless particles that do not interact with each other: laser beams directed towards each other pass through one another.
Scientists managed to build a special type of environment. They showed that in such an environment the quanta interact so strongly that they behave as if they had mass.
Lukin makes a comparison with lightsabers from space fantasy. When photons interact, they repel each other and are deflected to the side. The phenomena occurring with molecules remind Lukin of the Jedi battle with lightsabers in the film “Star Wars”.
Mikhail Lukin and his colleagues (Ofer Fisterberg and Alexey Gorshkov from Harvard, Thibaut Peyronel and Qi Liang from Massachusetts) created special environmental conditions in order to force photons, which normally have no mass, to interact. To do this, rubidium atoms were placed in a vacuum chamber, and then the atomic cloud was cooled to almost absolute zero using a laser. And finally, they fired single ultra-weak laser pulses into the resulting cloud.
The basic principle is that, passing through a cloud of cold atoms, the energy of a photon causes oncoming atoms to be excited, which leads to a significant slowdown in the movement of the quantum. The photon moves through the cloud, and its energy is transferred to neighboring atoms and in the end leaves the cloud along with the quantum, while it retains its identity.
A similar effect is observed when light is refracted in a glass of water. Light gives a share of its energy to the environment and is inside it both as light and as matter. But upon leaving the water, it retains its identity. In an experiment with photons, we observe the same principle: light slows down significantly and transfers more energy to the environment than with refraction.
In an experiment, scientists discovered that when two quanta are shot into a cloud, they come out as one molecule. This effect is called Rydberg block.
When an atom is excited, neighboring atoms cannot be excited to the same level. This means that when two quanta enter a cloud, the first one excites the nearby atom, but before the second one excites the neighboring one, the first photon must move forward. In other words, due to the fact that the photon energy is transferred to neighboring atoms, they push each other through the medium. The authors conclude: atomic interaction predetermines quantum interaction, as a result, this effect causes photons to enter the medium like a single molecule and leave it as a single photon.
What is the practical application of this effect?
Today, photons are the leading means for transporting quantum information.
To create a quantum computer, you need a system capable of storing and analyzing quantum information, and for this you need to understand the principle of interaction of photons.
Scientists were able to prove that the creation of a quantum switch and quantum logic operator is possible. To achieve this, it is necessary to improve the efficiency of the open process, but it is only a matter of time. For now, this discovery exemplifies the fundamental idea behind photonic interaction.
Mikhail Lukin gives an example that the created system can soon be used to create three-dimensional crystal-like structures from photons.
