Lorentz force. General principles of the device

ABSTRACT

In the subject "Physics"
Topic: “Application of the Lorentz force”

Completed by: Student of group T-10915 Logunova M.V.

Teacher Vorontsov B.S.

Kurgan 2016

Introduction. 3

1. Use of the Lorentz force. 4

.. 4

1. 2 Mass spectrometry. 6

1. 3 MHD generator. 7

1. 4 Cyclotron. 8

Conclusion. eleven

List of used literature... 13

Introduction

Lorentz force- the force with which the electromagnetic field, according to classical (non-quantum) electrodynamics, acts on a point charged particle. Sometimes the Lorentz force is called the force acting on a moving object with speed υ charge q only from the outside magnetic field, often full strength - from the electromagnetic field in general, in other words, from the electric E and magnetic B fields.

IN International system units (SI) is expressed as:

F L = q υ B sin α

It is named after the Dutch physicist Hendrik Lorentz, who derived an expression for this force in 1892. Three years before Lorenz, the correct expression was found by O. Heaviside.

The macroscopic manifestation of the Lorentz force is the Ampere force.

Using the Lorentz force

The effect exerted by a magnetic field on moving charged particles is very widely used in technology.

The main application of the Lorentz force (more precisely, its special case - the Ampere force) is electrical machines (electric motors and generators). The Lorentz force is widely used in electronic devices to influence charged particles (electrons and sometimes ions), for example, in television cathode ray tubes, V mass spectrometry And MHD generators.

Also, in the currently created experimental installations for carrying out a controlled thermonuclear reaction, the action of a magnetic field on the plasma is used to twist it into a cord that does not touch the walls of the working chamber. The circular motion of charged particles in a uniform magnetic field and the independence of the period of such motion from the particle speed are used in cyclic accelerators of charged particles - cyclotrons.

1. 1. Electron beam devices

Electron beam devices (EBDs) are a class of vacuum electronic devices that use a flow of electrons, concentrated in the form of a single beam or beam of beams, which are controlled both in intensity (current) and position in space, and interact with a stationary spatial target (screen) of the device. The main scope of application of ELP is the conversion of optical information into electrical signals and the reverse conversion of the electrical signal into an optical signal - for example, into a visible television image.

The class of cathode-ray devices does not include X-ray tubes, photocells, photomultipliers, gas-discharge devices (dekatrons) and receiving and amplifying electron tubes (beam tetrodes, electric vacuum indicators, lamps with secondary emission, etc.) with a beam form of currents.

An electron beam device consists of at least three main parts:

· An electronic spotlight (gun) forms an electron beam (or a beam of rays, for example, three beams in a color picture tube) and controls its intensity (current);

· The deflection system controls the spatial position of the beam (its deviation from the axis of the spotlight);

· The target (screen) of the receiving ELP converts the energy of the beam into the luminous flux of a visible image; the target of the transmitting or storing ELP accumulates a spatial potential relief, read by a scanning electron beam

Rice. 1 CRT device

General principles devices.

A deep vacuum is created in the CRT cylinder. To create an electron beam, a device called an electron gun is used. The cathode, heated by the filament, emits electrons. By changing the voltage on the control electrode (modulator), you can change the intensity of the electron beam and, accordingly, the brightness of the image. After leaving the gun, the electrons are accelerated by the anode. Next, the beam passes through a deflection system, which can change the direction of the beam. Television CRTs use a magnetic deflection system as it provides large deflection angles. Oscillographic CRTs use an electrostatic deflection system as it provides greater performance. The electron beam hits a screen covered with phosphor. Bombarded by electrons, the phosphor glows and a rapidly moving spot of variable brightness creates an image on the screen.

1. 2 Mass spectrometry

Rice. 2

The Lorentz force is also used in instruments called mass spectrographs, which are designed to separate charged particles according to their specific charges.

Mass spectrometry(mass spectroscopy, mass spectrography, mass spectral analysis, mass spectrometric analysis) - a method for studying a substance based on determining the mass-to-charge ratio of ions formed by ionization of the sample components of interest. One of the most powerful ways of qualitative identification of substances, which also allows quantitative determination. We can say that mass spectrometry is the “weighing” of the molecules in a sample.

The diagram of the simplest mass spectrograph is shown in Figure 2.

In chamber 1, from which air has been pumped out, there is an ion source 3. The chamber is placed in a uniform magnetic field, at each point of which the induction B⃗ B→ is perpendicular to the plane of the drawing and directed towards us (in Figure 1 this field is indicated by circles). An accelerating voltage is applied between electrodes A and B, under the influence of which the ions emitted from the source are accelerated and at a certain speed enter the magnetic field perpendicular to the induction lines. Moving in a magnetic field along a circular arc, the ions fall on photographic plate 2, which makes it possible to determine the radius R of this arc. Knowing the magnetic field induction B and the speed υ of ions, according to the formula

the specific charge of ions can be determined. And if the charge of the ion is known, its mass can be calculated.

The history of mass spectrometry dates back to the seminal experiments of J. J. Thomson at the beginning of the 20th century. The ending “-metry” in the name of the method appeared after the widespread transition from detecting charged particles using photographic plates to electrical measurements of ion currents.

Especially wide application mass spectrometry finds in the analysis organic matter, since it provides confident identification of both relatively simple and complex molecules. The only thing general requirement- so that the molecule can be ionized. However, by now it has been invented

There are so many ways to ionize sample components that mass spectrometry can be considered an almost all-encompassing method.

1. 3 MHD generator

Magnetohydrodynamic generator, MHD generator - power plant, in which the energy of the working fluid (liquid or gaseous electrically conducting medium) moving in a magnetic field is converted directly into electrical energy.

The operating principle of an MHD generator, like a conventional machine generator, is based on the phenomenon electromagnetic induction, that is, on the occurrence of a current in a conductor crossing the magnetic field lines. Unlike machine generators, the conductor in an MHD generator is the working fluid itself.

The working fluid moves across the magnetic field, and under the influence of the magnetic field, oppositely directed flows of charge carriers of opposite signs arise.

The Lorentz force acts on a charged particle.

The following media can serve as the working fluid of the MHD generator:

· electrolytes;

· liquid metals;

· plasma (ionized gas).

The first MHD generators used electrically conductive liquids (electrolytes) as the working fluid. Currently, plasma is used in which the charge carriers are mainly free electrons and positive ions. Under the influence of a magnetic field, charge carriers deviate from the trajectory along which the gas would move in the absence of the field. In this case, in a strong magnetic field, a Hall field can arise (see Hall effect) - an electric field formed as a result of collisions and displacements of charged particles in a plane perpendicular to the magnetic field.

1. 4 Cyclotron

A cyclotron is a resonant cyclic accelerator of non-relativistic heavy charged particles (protons, ions), in which the particles move in a constant and uniform magnetic field, and a high-frequency electric field of constant frequency is used to accelerate them.

The circuit diagram of the cyclotron is shown in Fig. 3. Heavy charged particles (protons, ions) enter the chamber from an injector near the center of the chamber and are accelerated by an alternating field of a fixed frequency applied to the accelerating electrodes (there are two of them and they are called dees). Particles with charge Ze and mass m move in a constant magnetic field of intensity B, directed perpendicular to the plane of motion of the particles, in an unwinding spiral. The radius R of the trajectory of a particle having a speed v is determined by the formula

where γ = -1/2 is the relativistic factor.

In a cyclotron, for a nonrelativistic (γ ≈ 1) particle in a constant and uniform magnetic field, the orbital radius is proportional to the speed (1), and the rotation frequency of the nonrelativistic particle (the cyclotron frequency does not depend on the particle energy

E = mv 2 /2 = (Ze) 2 B 2 R 2 /(2m) (3)

In the gap between the dees, particles are accelerated by a pulse electric field(there is no electric field inside hollow metal dees). As a result, the energy and radius of the orbit increase. By repeating the acceleration by the electric field at each revolution, the energy and radius of the orbit are brought to the maximum acceptable values. In this case, the particles acquire a speed v = ZeBR/m and the corresponding energy:

At the last turn of the spiral, a deflecting electric field is turned on, leading the beam out. The constancy of the magnetic field and the frequency of the accelerating field make continuous acceleration possible. While some particles are moving along the outer turns of the spiral, others are in the middle of the path, and others are just beginning to move.

The disadvantage of the cyclotron is the limitation by essentially non-relativistic energies of particles, since even not very large relativistic corrections (deviations of γ from unity) disrupt the synchronism of acceleration at different turns and particles with significantly increased energies no longer have time to end up in the gap between the dees in the phase of the electric field required for acceleration . In conventional cyclotrons, protons can be accelerated to 20-25 MeV.

To accelerate heavy particles in an unwinding spiral mode to energies tens of times higher (up to 1000 MeV), a modification of the cyclotron called isochronous(relativistic) cyclotron, as well as a phasotron. In isochronous cyclotrons, relativistic effects are compensated by a radial increase in the magnetic field.

Conclusion

Hidden text

Written conclusion (the most basic for all subparagraphs of the first section - principles of action, definitions)

List of used literature

1. Wikipedia [ Electronic resource]: Lorentz force. URL: https://ru.wikipedia.org/wiki/Lorentz_Force

2. Wikipedia [Electronic resource]: Magnetohydrodynamic generator. URL: https://ru.wikipedia.org/wiki/ Magnetohydrodynamic_generator

3. Wikipedia [Electronic resource]: Electron beam devices. URL: https://ru.wikipedia.org/wiki/ Electron-beam_devices

4. Wikipedia [Electronic resource]: Mass spectrometry. URL: https://ru.wikipedia.org/wiki/Mass spectrometry

5. Nuclear physics on the Internet [Electronic resource]: Cyclotron. URL: http://nuclphys.sinp.msu.ru/experiment/accelerators/ciclotron.htm

6. Electronic textbook physics [Electronic resource]: T. Applications of the Lorentz force // URL: http://www.physbook.ru/index.php/ T. Applications of the Lorentz force

7. Academician [Electronic resource]: Magnetohydrodynamic generator // URL: http://dic.academic.ru/dic.nsf/enc_physics/MAGNETOHYDRODYNAMIC

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Ampere power, acting on a conductor segment of length Δ l with current strength I, located in a magnetic field B,

The expression for the Ampere force can be written as:

This force is called Lorentz force . The angle α in this expression is equal to the angle between the speed and vector of magnetic induction The direction of the Lorentz force acting on a positively charged particle, as well as the direction of the Ampere force, can be found by left hand rule or by gimlet rule. The relative position of the vectors , and for a positively charged particle is shown in Fig. 1.18.1.

Figure 1.18.1.

The relative position of the vectors , and The modulus of the Lorentz force is numerically equal to area of a parallelogram, built on vectors and multiplied by charge q

The Lorentz force is directed perpendicular to the vectors and

When a charged particle moves in a magnetic field, the Lorentz force does no work. Therefore, the magnitude of the velocity vector does not change when the particle moves.

If a charged particle moves in a uniform magnetic field under the influence of the Lorentz force, and its speed lies in a plane perpendicular to the vector, then the particle will move in a circle of radius

The period of revolution of a particle in a uniform magnetic field is equal to

called cyclotron frequency . The cyclotron frequency does not depend on the speed (and therefore on the kinetic energy) of the particle. This circumstance is used in cyclotrons – accelerators of heavy particles (protons, ions). The schematic diagram of the cyclotron is shown in Fig. 1.18.3.

A vacuum chamber is placed between the poles of a strong electromagnet, in which there are two electrodes in the form of hollow metal half-cylinders ( dees ). An alternating electrical voltage is applied to the dees, whose frequency is equal to the cyclotron frequency. Charged particles are injected into the center of the vacuum chamber. The particles are accelerated by the electric field in the space between the dees. Inside the dees, the particles move under the influence of the Lorentz force in semicircles, the radius of which increases as the energy of the particles increases. Every time a particle flies through the gap between the dees, it is accelerated by the electric field. Thus, in a cyclotron, as in all other accelerators, a charged particle is accelerated by an electric field and kept on its trajectory by a magnetic field. Cyclotrons make it possible to accelerate protons to energies of the order of 20 MeV.

Uniform magnetic fields are used in many devices and, in particular, in mass spectrometers – devices with which you can measure the masses of charged particles – ions or nuclei of various atoms. Mass spectrometers are used for separation isotopes, that is, atomic nuclei with the same charge, but different masses(for example, 20 Ne and 22 Ne). The simplest mass spectrometer is shown in Fig. 1.18.4. Ions escaping from the source S, pass through several small holes, forming a narrow beam. Then they get into speed selector , in which particles move in crossed homogeneous electric and magnetic fields. An electric field is created between the plates of a flat capacitor, a magnetic field is created in the gap between the poles of an electromagnet. The initial speed of charged particles is directed perpendicular to the vectors and

A particle moving in crossed electric and magnetic fields is acted upon by an electric force and magnetic Lorentz force. Given that E = υ B these forces exactly balance each other. If this condition is met, the particle will move uniformly and rectilinearly and, after flying through the capacitor, will pass through the hole in the screen. For given values of electric and magnetic fields, the selector will select particles moving at speed υ = E / B.

Next, particles with the same speed value enter the mass spectrometer chamber, in which a uniform magnetic field is created. The particles move in the chamber in a plane perpendicular to the magnetic field under the influence of the Lorentz force. Particle trajectories are circles of radii R = mυ / qB". Measuring the radii of trajectories for known values of υ and B" relationship can be determined q / m. In the case of isotopes ( q 1 = q 2) a mass spectrometer allows you to separate particles with different masses.

Modern mass spectrometers make it possible to measure the masses of charged particles with an accuracy higher than 10 –4.

If the velocity of a particle has a component along the direction of the magnetic field, then such a particle will move in a uniform magnetic field in a spiral. In this case, the radius of the spiral R depends on the modulus of the component perpendicular to the magnetic field υ ┴ of the vector and the pitch of the spiral p– from the modulus of the longitudinal component υ || (Fig. 1.18.5).

Thus, the trajectory of a charged particle seems to wind around the magnetic induction line. This phenomenon is used in technology for magnetic thermal insulation of high temperature plasma, that is, a completely ionized gas at a temperature of the order of 10 6 K. A substance in this state is obtained in Tokamak-type installations when studying controlled thermonuclear reactions. The plasma should not come into contact with the walls of the chamber. Thermal insulation is achieved by creating a magnetic field of a special configuration. As an example in Fig. 1.18.6 shows the trajectory of a charged particle in magnetic “bottle”(or trapped ).

A similar phenomenon occurs in the Earth’s magnetic field, which is a protection for all living things from flows of charged particles from outer space. Fast charged particles from space (mainly from the Sun) are “captured” by the Earth’s magnetic field and form so-called radiation belts (Fig. 1.18.7), in which particles, as in magnetic traps, move back and forth along spiral trajectories between the north and south magnetic poles in times of the order of fractions of a second. Only in the polar regions do some particles invade the upper atmosphere, causing auroras. The Earth's radiation belts extend from distances of the order of 500 km to tens of Earth radii. It should be remembered that the south magnetic pole of the Earth is located near the north geographic pole (in northwest Greenland). The nature of terrestrial magnetism has not yet been studied.

Control questions

1.Describe the experiments of Oersted and Ampere.

2.What is the source of the magnetic field?

3. What is Ampere’s hypothesis that explains the existence of the magnetic field of a permanent magnet?

4.What is the fundamental difference between a magnetic field and an electric one?

5. Formulate the definition of the magnetic induction vector.

6. Why is the magnetic field called vortex?

7. Formulate laws:

A) Ampere;

B) Bio-Savart-Laplace.

8. Why modulus is equal vector of magnetic induction of the forward current field?

9. State the definition of the unit of current (ampere) in the International System of Units.

10. Write down the formula expressing the quantity:

A) module of the magnetic induction vector;

B) Ampere forces;

B) Lorentz forces;

D) the period of revolution of a particle in a uniform magnetic field;

D) radius of curvature of a circle when a charged particle moves in a magnetic field;

Self-control test

What was observed in Oersted's experiment?

1) Interaction of two parallel conductors with current.

2) Interaction of two magnetic needles

3) Rotate a magnetic needle near a conductor when current is passed through it.

4) Emergence electric current in a coil when a magnet is pushed into it.

How do two parallel conductors interact if they carry currents in the same direction?

Attracted;

They push off;

The force and moment of forces are zero.

The force is zero, but the moment of force is not zero.

What formula determines the expression for the modulus of the Ampere force?

What formula determines the expression for the modulus of the Lorentz force?

IN)

0.6 N; 2) 1 N; 3) 1.4 N; 4) 2.4 N.

1) 0.5 T; 2) 1 T; 3) 2 T; 4) 0.8 T .

An electron with a speed V flies into a magnetic field with an induction module B perpendicular to the magnetic lines. What expression corresponds to the radius of the electron's orbit?

Answer: 1)
2)

4)

8. How will the period of revolution of a charged particle in a cyclotron change when its speed is doubled? (V<< c).

1) Increase by 2 times; 2) Increase by 2 times;

3) Increase by 16 times; 4) Will not change.

9. What formula determines the modulus of induction of a magnetic field created at the center of a circular current with a circle radius R?

1)
2)
3)
4)

10. The current strength in the coil is equal to I. Which formula determines the modulus of magnetic field induction in the middle of a coil of length l with the number of turns N?

1)
2)
3)
4)

Laboratory work No.

Determination of the horizontal component of the Earth's magnetic field induction.

Brief theory for laboratory work.

A magnetic field is a material medium that transmits so-called magnetic interactions. The magnetic field is one of the forms of manifestation of the electromagnetic field.

The sources of magnetic fields are moving electric charges, current-carrying conductors and alternating electric fields. Generated by moving charges (currents), the magnetic field, in turn, acts only on moving charges (currents), but has no effect on stationary charges.

The main characteristic of a magnetic field is the magnetic induction vector :

The magnitude of the magnetic induction vector is numerically equal to the maximum force acting from the magnetic field on a conductor of unit length through which a current of unit strength flows. Vector forms a right-handed triple with the force vector and current direction. Thus, magnetic induction is a force characteristic of a magnetic field.

The SI unit of magnetic induction is Tesla (T).

Magnetic field lines are imaginary lines, at each point of which the tangents coincide with the direction of the magnetic induction vector. Magnetic lines of force are always closed and never intersect.

Ampere's law determines the force action of a magnetic field on a current-carrying conductor.

If in a magnetic field with induction a current-carrying conductor is placed, then each current-directed element the conductor is acted upon by the Ampere force, determined by the relation

The direction of the Ampere force coincides with the direction of the vector product
, those. it is perpendicular to the plane in which the vectors lie And (Fig. 1).

Rice. 1. To determine the direction of the Ampere force

If perpendicular , then the direction of the Ampere force can be determined by the rule of the left hand: direct four outstretched fingers along the current, place the palm perpendicular to the lines of force, then thumb will show the direction of the Ampere force. Ampere's law is the basis for the definition of magnetic induction, i.e. relation (1) follows from formula (2), written in scalar form.

The Lorentz force is the force with which an electromagnetic field acts on a charged particle moving in this field. The Lorentz force formula was first obtained by G. Lorentz as a result of generalization of experience and has the form:

Where
– force acting on a charged particle in an electric field with intensity ;
– force acting on a charged particle in a magnetic field.

The formula for the magnetic component of the Lorentz force can be obtained from Ampere's law, taking into account that current is the ordered movement of electric charges. If the magnetic field did not act on moving charges, it would not have any effect on the current-carrying conductor. The magnetic component of the Lorentz force is determined by the expression:

This force is directed perpendicular to the plane in which the velocity vectors lie and magnetic field induction ; its direction coincides with the direction of the vector product
For q > 0 and with direction
For q>0 (Fig. 2).

Rice. 2. To determine the direction of the magnetic component of the Lorentz force

If the vector perpendicular to the vector , then the direction of the magnetic component of the Lorentz force for positively charged particles can be found using the left-hand rule, and for negatively charged particles using the rule right hand. Since the magnetic component of the Lorentz force is always directed perpendicular to the speed , then it does not do any work to move the particle. It can only change the direction of speed , bend the trajectory of a particle, i.e. act as a centripetal force.

The Biot-Savart-Laplace law is used to calculate magnetic fields (definitions ) created by conductors carrying current.

According to the Biot-Savart-Laplace law, each current-directed element of a conductor creates at a point at a distance from this element, a magnetic field, the induction of which is determined by the relation:

Where
H/m – magnetic constant; µ – magnetic permeability of the medium.

Rice. 3. Towards the Biot-Savart-Laplace law

Direction
coincides with the direction of the vector product
, i.e.
perpendicular to the plane in which the vectors lie And . Simultaneously
is tangent to the line of force, the direction of which can be determined by the gimlet rule: if the translational movement of the tip of the gimlet is directed along the current, then the direction of rotation of the handle will determine the direction of the magnetic field line (Fig. 3).

To find the magnetic field created by the entire conductor, you need to apply the principle of field superposition:

For example, let's calculate the magnetic induction in the center of the circular current (Fig. 4).

Rice. 4. Towards the calculation of the field at the center of the circular current

For circular current
And
, therefore relation (5) in scalar form has the form:

The total current law (magnetic induction circulation theorem) is another law for calculating magnetic fields.

The total current law for a magnetic field in vacuum has the form:

Where B l – projection per conductor element , directed along the current.

The circulation of the magnetic induction vector along any closed circuit is equal to the product of the magnetic constant and the algebraic sum of the currents covered by this circuit.

The Ostrogradsky-Gauss theorem for the magnetic field is as follows:

Where B n – vector projection to normal to the site dS.

The flux of the magnetic induction vector through an arbitrary closed surface is zero.

The nature of the magnetic field follows from formulas (9), (10).

The condition for the potentiality of the electric field is that the circulation of the intensity vector is equal to zero
.

A potential electric field is generated by stationary electric charges; The field lines are not closed, they begin on positive charges and end on negative ones.

From formula (9) we see that in a magnetic field the circulation of the magnetic induction vector is different from zero, therefore, the magnetic field is not potential.

From relation (10) it follows that magnetic charges capable of creating potential magnetic fields do not exist. (In electrostatics, a similar theorem smolders in the form
.

Magnetic lines of force close on themselves. Such a field is called a vortex field. Thus, the magnetic field is a vortex field. The direction of the field lines is determined by the gimlet rule. In a straight, infinitely long conductor carrying current, the lines of force have the form of concentric circles surrounding the conductor (Fig. 3).

Along with the Ampere force, Coulomb interaction, and electromagnetic fields, the concept of Lorentz force is often encountered in physics. This phenomenon is one of the fundamental ones in electrical engineering and electronics, along with, and others. It affects charges that move in a magnetic field. In this article we will briefly and clearly examine what the Lorentz force is and where it is applied.

Definition

When electrons move along a conductor, a magnetic field appears around it. At the same time, if you place a conductor in a transverse magnetic field and move it, an electromagnetic induction emf will arise. If a current flows through a conductor located in a magnetic field, the Ampere force acts on it.

Its value depends on the flowing current, the length of the conductor, the magnitude of the magnetic induction vector and the sine of the angle between the magnetic field lines and the conductor. It is calculated using the formula:

The force under consideration is partly similar to that discussed above, but it acts not on a conductor, but on a moving charged particle in a magnetic field. The formula looks like:

Important! The Lorentz force (Fl) acts on an electron moving in a magnetic field, and on a conductor - Ampere.

From the two formulas it is clear that in both the first and second cases, the closer the sine of the angle alpha is to 90 degrees, the greater the effect on the conductor or charge by Fa or Fl, respectively.

So, the Lorentz force characterizes not the change in velocity, but the effect of the magnetic field on a charged electron or positive ion. When exposed to them, Fl does not do any work. Accordingly, it is the direction of the charged particle’s velocity that changes, and not its magnitude.

As for the unit of measurement of the Lorentz force, as in the case of other forces in physics, a quantity such as Newton is used. Its components:

How is the Lorentz force directed?

To determine the direction of the Lorentz force, as with the Ampere force, the left-hand rule works. This means, in order to understand where the Fl value is directed, you need to open the palm of your left hand so that the magnetic induction lines enter your hand, and the extended four fingers indicate the direction of the velocity vector. Then the thumb, bent at a right angle to the palm, indicates the direction of the Lorentz force. In the picture below you can see how to determine the direction.

Attention! The direction of the Lorentz action is perpendicular to the particle motion and the magnetic induction lines.

In this case, to be more precise, for positively and negatively charged particles the direction of the four unfolded fingers matters. The left-hand rule described above is formulated for a positive particle. If it is negatively charged, then the lines of magnetic induction should be directed not towards the open palm, but towards its back, and the direction of the vector Fl will be the opposite.

Now we will tell in simple words, what this phenomenon gives us and what real impact it has on the charges. Let us assume that the electron moves in a plane perpendicular to the direction of the magnetic induction lines. We have already mentioned that Fl does not affect the speed, but only changes the direction of particle motion. Then the Lorentz force will have a centripetal effect. This is reflected in the figure below.

Application

Of all the areas where the Lorentz force is used, one of the largest is the movement of particles in the earth's magnetic field. If we consider our planet as a large magnet, then the particles that are located near the northern magnetic poles, make an accelerated movement in a spiral. As a result, they collide with atoms from upper layers atmosphere, and we see the northern lights.

However, there are other cases where this phenomenon applies. For example:

Cathode ray tubes. In their electromagnetic deflection systems. CRTs have been used for more than 50 years in a row in various devices, ranging from the simplest oscilloscope to televisions different forms and sizes. It is curious that when it comes to color reproduction and working with graphics, some still use CRT monitors.
Electrical machines – generators and motors. Although the Ampere force is more likely to act here. But these quantities can be considered as adjacent. However, these are complex devices during operation of which the influence of many physical phenomena is observed.
In accelerators of charged particles in order to set their orbits and directions.

Conclusion

Let us summarize and outline the four main points of this article in simple language:

The Lorentz force acts on charged particles that move in a magnetic field. This follows from the basic formula.
It is directly proportional to the speed of the charged particle and magnetic induction.
Does not affect particle speed.
Affects the direction of the particle.

Its role is quite large in the “electrical” areas. A specialist should not lose sight of the basic theoretical information about the fundamental physical laws. This knowledge will be useful, as well as for those who deal scientific work, design and just for general development.

Now you know what the Lorentz force is, what it is equal to and how it acts on charged particles. If you have any questions, ask them in the comments below the article!

Materials

The effect exerted by a magnetic field on moving charged particles is very widely used in technology.

For example, the deflection of an electron beam in TV picture tubes is carried out using a magnetic field, which is created by special coils. A number of electronic devices use a magnetic field to focus beams of charged particles.

In currently created experimental installations for carrying out a controlled thermonuclear reaction, the action of a magnetic field on the plasma is used to twist it into a cord that does not touch the walls of the working chamber. The circular motion of charged particles in a uniform magnetic field and the independence of the period of such motion from the particle speed are used in cyclic accelerators of charged particles - cyclotrons.

The Lorentz force is also used in devices called mass spectrographs, which are designed to separate charged particles according to their specific charges.

The diagram of the simplest mass spectrograph is shown in Figure 1.

In chamber 1, from which air has been pumped out, there is an ion source 3. The chamber is placed in a uniform magnetic field, at each point of which the induction \(~\vec B\) is perpendicular to the plane of the drawing and directed towards us (in Figure 1 this field is indicated by circles) . An accelerating voltage is applied between the electrodes A and B, under the influence of which the ions emitted from the source are accelerated and at a certain speed enter the magnetic field perpendicular to the induction lines. Moving in a magnetic field in a circular arc, the ions fall on photographic plate 2, which makes it possible to determine the radius R this arc. Knowing the magnetic field induction IN and speed υ ions, according to the formula

\(~\frac q m = \frac (v)(RB)\)

the specific charge of ions can be determined. And if the charge of the ion is known, its mass can be calculated.

Literature

Aksenovich L. A. Physics in high school: Theory. Tasks. Tests: Textbook. allowance for institutions providing general education. environment, education / L. A. Aksenovich, N. N. Rakina, K. S. Farino; Ed. K. S. Farino. - Mn.: Adukatsiya i vyakhavanne, 2004. - P. 328.

MINISTRY OF EDUCATION AND SCIENCE

RUSSIAN FEDERATION

FEDERAL STATE BUDGET EDUCATIONAL INSTITUTION OF HIGHER PROFESSIONAL EDUCATION

"KURGAN STATE UNIVERSITY"

ABSTRACT

In the subject "Physics" Topic: "Application of the Lorentz force"

Completed by: Student of group T-10915 Logunova M.V.

Teacher Vorontsov B.S.

Kurgan 2016

Introduction 3

1. Use of Lorentz force 4

1.1. Electron beam devices 4

1.2 Mass spectrometry 5

1.3 MHD generator 7

1.4 Cyclotron 8

Conclusion 10

References 11

Introduction

Lorentz force- the force with which the electromagnetic field, according to classical (non-quantum) electrodynamics, acts on a point charged particle. Sometimes the Lorentz force is called the force acting on a moving object with speed υ charge q only from the side of the magnetic field, often in full force - from the side of the electromagnetic field in general, in other words, from the side of the electric E immagnetic B fields.

In the International System of Units (SI) it is expressed as:

F L = qυ B sin α

It is named after the Dutch physicist Hendrik Lorentz, who derived an expression for this force in 1892. Three years before Lorenz, the correct expression was found by O. Heaviside.

The macroscopic manifestation of the Lorentz force is the Ampere force.

Using the Lorentz force

The effect exerted by a magnetic field on moving charged particles is very widely used in technology.

The main application of the Lorentz force (more precisely, its special case - the Ampere force) is electric machines (electric motors and generators). The Lorentz force is widely used in electronic devices to influence charged particles (electrons and sometimes ions), for example, in television cathode ray tubes, V mass spectrometry And MHD generators.

1. Electron beam devices

An electron beam device consists of at least three main parts:

An electronic spotlight (gun) forms an electron beam (or a beam of rays, for example, three beams in a color picture tube) and controls its intensity (current);

The deflection system controls the spatial position of the beam (its deviation from the axis of the spotlight);

The target (screen) of the receiving ELP converts the energy of the beam into the luminous flux of a visible image; the target of the transmitting or storing ELP accumulates a spatial potential relief, read by a scanning electron beam

Rice. 1 CRT device

General principles of the device.

2 Mass spectrometry

Rice. 2

The Lorentz force is also used in instruments called mass spectrographs, which are designed to separate charged particles according to their specific charges.

Mass spectrometry(mass spectroscopy, mass spectrography, mass spectral analysis, mass spectrometric analysis) - a method for studying a substance based on determining the mass-to-charge ratio of ions formed during the ionization of sample components of interest. One of the most powerful ways of qualitative identification of substances, which also allows quantitative determination. We can say that mass spectrometry is the “weighing” of the molecules in a sample.

The diagram of the simplest mass spectrograph is shown in Figure 2.

In chamber 1, from which the air has been pumped out, there is an ion source 3. The chamber is placed in a uniform magnetic field, at each point of which the induction B⃗B→ is perpendicular to the plane of the drawing and directed towards us (in Figure 1 this field is indicated by circles). An accelerating voltage is applied between electrodes A and B, under the influence of which the ions emitted from the source are accelerated and at a certain speed enter the magnetic field perpendicular to the induction lines. Moving in a magnetic field along a circular arc, the ions fall on photographic plate 2, which makes it possible to determine the radius R of this arc. Knowing the magnetic field induction B and the speed υ of ions, according to the formula

(1)

the specific charge of ions can be determined. And if the charge of the ion is known, its mass can be calculated.

Mass spectrometry is especially widely used in the analysis of organic substances, since it provides confident identification of both relatively simple and complex molecules. The only general requirement is that the molecule be ionizable. However, by now it has been invented

There are so many ways to ionize sample components that mass spectrometry can be considered an almost all-encompassing method.

3 MHD generator

Magnetohydrodynamic generator, MHD generator is a power plant in which the energy of a working fluid (liquid or gaseous electrically conducting medium) moving in a magnetic field is converted directly into electrical energy.

The operating principle of an MHD generator, like a conventional machine generator, is based on the phenomenon of electromagnetic induction, that is, on the occurrence of current in a conductor crossing the magnetic field lines. Unlike machine generators, the conductor in an MHD generator is the working fluid itself.

The working fluid moves across the magnetic field, and under the influence of the magnetic field, oppositely directed flows of charge carriers of opposite signs arise.

The Lorentz force acts on a charged particle.

The following media can serve as the working fluid of the MHD generator:

4 Cyclotron

Fig.5. Cyclotron diagram: top and side view: 1 -source of heavy charged particles (protons, ions), 2 - orbit of accelerated particle, 3 -accelerating electrodes (dees), 4 - accelerating field generator, 5 - electromagnet. Arrows show magnetic field lines). They are perpendicular to the plane of the top figure

where γ = -1/2 is the relativistic factor.

(2)

E = mv 2 /2 = (Ze) 2 B 2 R 2 /(2m) (3)

In the gap between the dees, particles are accelerated by a pulsed electric field (there is no electric field inside hollow metal dees). As a result, the energy and radius of the orbit increase. By repeating the acceleration by the electric field at each revolution, the energy and radius of the orbit are brought to the maximum permissible values. In this case, the particles acquire a speed v = ZeBR/m and the corresponding energy:

Conclusion

Hidden text

Written conclusion (the most basic for all subparagraphs of the first section - principles of action, definitions)

List of used literature

Wikipedia [Electronic resource]: Lorentz force. URL: https://ru.wikipedia.org/wiki/Lorentz_Force

Wikipedia [Electronic resource]: Magnetohydrodynamic generator. URL: https://ru.wikipedia.org/wiki/Magnetohydrodynamic_generator

Wikipedia [Electronic resource]: Electron beam devices. URL: https://ru.wikipedia.org/wiki/Electron-beam_devices

Wikipedia [Electronic resource]: Mass spectrometry. URL: https://ru.wikipedia.org/wiki/Mass spectrometry

Nuclear physics on the Internet [Electronic resource]: Cyclotron. URL: http://nuclphys.sinp.msu.ru/experiment/accelerators/ciclotron.htm

Electronic textbook of physics [Electronic resource]: T. Applications of the Lorentz force //URL: http://www.physbook.ru/index.php/ T. Applications of the Lorentz force

Academician [Electronic resource]: Magnetohydrodynamic generator //URL: http://dic.academic.ru/dic.nsf/enc_physics/MAGNETOHYDRODYNAMIC