What is the force acting on a body. Power and concepts associated with it

If a body accelerates, then something acts on it. How to find this “something”? For example, what kind of forces act on a body near the surface of the earth? This is the force of gravity directed vertically downward, proportional to the mass of the body and for heights much smaller than the radius of the earth $(\large R)$, almost independent of the height; it is equal

$(\large F = \dfrac (G \cdot m \cdot M)(R^2) = m \cdot g )$

$(\large g = \dfrac (G \cdot M)(R^2) )$

so-called acceleration due to gravity. In the horizontal direction the body will move at a constant speed, but the movement in the vertical direction is according to Newton's second law:

$(\large m \cdot g = m \cdot \left (\dfrac (d^2 \cdot x)(d \cdot t^2) \right) )$

after contracting $(\large m)$, we find that the acceleration in the direction $(\large x)$ is constant and equal to $(\large g)$. This is the well-known motion of a freely falling body, which is described by the equations

$(\large v_x = v_0 + g \cdot t)$

$(\large x = x_0 + x_0 \cdot t + \dfrac (1)(2) \cdot g \cdot t^2)$

How is strength measured?

In all textbooks and smart books, it is customary to express force in Newtons, but except in the models that physicists operate, Newtons are not used anywhere. This is extremely inconvenient.

Newton newton (N) is a derived unit of force in the International System of Units (SI).
Based on Newton's second law, the unit newton is defined as the force that changes the speed of a body weighing one kilogram by 1 meter per second in one second in the direction of the force.

Thus, 1 N = 1 kg m/s².

Kilogram-force (kgf or kg) - gravitational metric unit strength, equal to strength, which acts on a body weighing one kilogram in the gravitational field of the earth. Therefore, by definition, a kilogram-force is equal to 9.80665 N. A kilogram-force is convenient in that its value is equal to the weight of a body weighing 1 kg.
1 kgf = 9.80665 newtons (approximately ≈ 10 N)
1 N ≈ 0.10197162 kgf ≈ 0.1 kgf

1 N = 1 kg x 1 m/s2.

Law of gravitation

Every object in the Universe is attracted to every other object with a force proportional to their masses and inversely proportional to the square of the distance between them.

$(\large F = G \cdot \dfrac (m \cdot M)(R^2))$

We can add that any body reacts to a force applied to it with acceleration in the direction of this force, in magnitude inversely proportional to the mass of the body.

$(\large G)$ — gravitational constant

$(\large M)$ — mass of the earth

$(\large R)$ — radius of the earth

$(\large G = 6.67 \cdot (10^(-11)) \left (\dfrac (m^3)(kg \cdot (sec)^2) \right) )$

$(\large M = 5.97 \cdot (10^(24)) \left (kg \right) )$

$(\large R = 6.37 \cdot (10^(6)) \left (m \right) )$

Within the framework of classical mechanics, gravitational interaction is described by Newton’s law of universal gravitation, according to which the force of gravitational attraction between two bodies of mass $(\large m_1)$ and $(\large m_2)$ separated by a distance $(\large R)$ is

$(\large F = -G \cdot \dfrac (m_1 \cdot m_2)(R^2))$

Here $(\large G)$ is the gravitational constant equal to $(\large 6.673 \cdot (10^(-11)) m^3 / \left (kg \cdot (sec)^2 \right) )$. The minus sign means that the force acting on the test body is always directed along the radius vector from the test body to the source of the gravitational field, i.e. gravitational interaction always leads to the attraction of bodies.
The gravity field is potential. This means that you can introduce the potential energy of gravitational attraction of a pair of bodies, and this energy will not change after moving the bodies along a closed loop. The potentiality of the gravitational field entails the law of conservation of the sum of kinetic and potential energy, which, when studying the motion of bodies in a gravitational field, often significantly simplifies the solution.
Within the framework of Newtonian mechanics, gravitational interaction is long-range. This means that no matter how a massive body moves, at any point in space the gravitational potential and force depend only on the position of the body at a given moment in time.

Heavier - Lighter

The weight of a body $(\large P)$ is expressed by the product of its mass $(\large m)$ and the acceleration due to gravity $(\large g)$.

$(\large P = m \cdot g)$

When on earth the body becomes lighter (presses less on the scales), this is due to a decrease masses. On the moon, everything is different; the decrease in weight is caused by a change in another factor - $(\large g)$, since the acceleration of gravity on the surface of the moon is six times less than on the earth.

mass of the earth = $(\large 5.9736 \cdot (10^(24))\ kg )$

moon mass = $(\large 7.3477 \cdot (10^(22))\ kg )$

acceleration of gravity on Earth = $(\large 9.81\ m / c^2 )$

gravitational acceleration on the Moon = $(\large 1.62 \ m / c^2 )$

As a result, the product $(\large m \cdot g )$, and therefore the weight, decreases by 6 times.

But it is impossible to describe both of these phenomena with the same expression “make it easier.” On the moon, bodies do not become lighter, but only fall less rapidly; they are “less epileptic”))).

Vector and scalar quantities

A vector quantity (for example, a force applied to a body), in addition to its value (modulus), is also characterized by direction. A scalar quantity (for example, length) is characterized only by its value. All classical laws of mechanics are formulated for vector quantities.

Picture 1.

In Fig. Figure 1 shows various options for the location of the vector $( \large \overrightarrow(F))$ and its projections $( \large F_x)$ and $( \large F_y)$ on the axis $( \large X)$ and $( \large Y )$ respectively:

• A. the quantities $( \large F_x)$ and $( \large F_y)$ are non-zero and positive
• B. the quantities $( \large F_x)$ and $( \large F_y)$ are non-zero, while $(\large F_y)$ is a positive quantity, and $(\large F_x)$ is negative, because the vector $(\large \overrightarrow(F))$ is directed in the direction opposite to the direction of the $(\large X)$ axis
• C.$(\large F_y)$ is a positive non-zero quantity, $(\large F_x)$ is equal to zero, because the vector $(\large \overrightarrow(F))$ is directed perpendicular to the axis $(\large X)$

Moment of power

A moment of power called vector product the radius vector drawn from the axis of rotation to the point of application of the force to the vector of this force. Those. According to the classical definition, the moment of force is a vector quantity. Within the framework of our problem, this definition can be simplified to the following: the moment of force $(\large \overrightarrow(F))$ applied to a point with coordinate $(\large x_F)$, relative to the axis located at point $(\large x_0 )$ is a scalar quantity equal to the product of the force modulus $(\large \overrightarrow(F))$ and the force arm - $(\large \left | x_F - x_0 \right |)$. And the sign of this scalar quantity depends on the direction of the force: if it rotates the object clockwise, then the sign is plus, if counterclockwise, then the sign is minus.

It is important to understand that we can choose the axis arbitrarily - if the body does not rotate, then the sum of the moments of forces about any axis is zero. The second important note is that if a force is applied to a point through which an axis passes, then the moment of this force about this axis is equal to zero (since the arm of the force will be equal to zero).

Let us illustrate the above with an example in Fig. 2. Let us assume that the system shown in Fig. 2 is in equilibrium. Consider the support on which the loads stand. It is acted upon by 3 forces: $(\large \overrightarrow(N_1),\ \overrightarrow(N_2),\ \overrightarrow(N),)$ points of application of these forces A, IN And WITH respectively. The figure also contains forces $(\large \overrightarrow(N_(1)^(gr)),\ \overrightarrow(N_2^(gr)))$. These forces are applied to the loads, and according to Newton's 3rd law

$(\large \overrightarrow(N_(1)) = - \overrightarrow(N_(1)^(gr)))$

$(\large \overrightarrow(N_(2)) = - \overrightarrow(N_(2)^(gr)))$

Now consider the condition for the equality of the moments of forces acting on the support relative to the axis passing through the point A(and, as we agreed earlier, perpendicular to the drawing plane):

$(\large N \cdot l_1 - N_2 \cdot \left (l_1 +l_2 \right) = 0)$

Please note that the moment of force $(\large \overrightarrow(N_1))$ was not included in the equation, since the arm of this force relative to the axis in question is equal to $(\large 0)$. If for some reason we want to select an axis passing through the point WITH, then the condition for equality of moments of forces will look like this:

$(\large N_1 \cdot l_1 - N_2 \cdot l_2 = 0)$

It can be shown that, from a mathematical point of view, the last two equations are equivalent.

Center of gravity

Center of gravity in a mechanical system is the point relative to which the total moment of gravity acting on the system is equal to zero.

Center of mass

The point of the center of mass is remarkable in that if a great many forces act on the particles forming a body (no matter whether it is solid or liquid, a cluster of stars or something else) (meaning only external forces, since all internal forces compensate each other), then the resulting the force leads to such an acceleration of this point as if the entire mass of the body $(\large m)$ were in it.

The position of the center of mass is determined by the equation:

$(\large R_(c.m.) = \frac(\sum m_i\, r_i)(\sum m_i))$

This is a vector equation, i.e. in fact, three equations - one for each of the three directions. But consider only the $(\large x)$ direction. What does the following equality mean?

$(\large X_(c.m.) = \frac(\sum m_i\, x_i)(\sum m_i))$

Suppose the body is divided into small pieces with the same mass $(\large m)$, and the total mass of the body will be equal to the number of such pieces $(\large N)$ multiplied by the mass of one piece, for example 1 gram. Then this equation means that you need to take the $(\large x)$ coordinates of all the pieces, add them and divide the result by the number of pieces. In other words, if the masses of the pieces are equal, then $(\large X_(c.m.))$ will simply be the arithmetic mean of the $(\large x)$ coordinates of all the pieces.

Mass and density

Mass - fundamental physical quantity. Mass characterizes several properties of the body at once and in itself has a number of important properties.

• Mass serves as a measure of the substance contained in a body.
• Mass is a measure of the inertia of a body. Inertia is the property of a body to maintain its speed unchanged (in the inertial frame of reference) when external influences are absent or compensate each other. In the presence of external influences, the inertia of a body is manifested in the fact that its speed does not change instantly, but gradually, and the more slowly, the greater the inertia (i.e. mass) of the body. For example, if a billiard ball and a bus are moving at the same speed and are braked by the same force, then it takes much less time to stop the ball than to stop the bus.
• The masses of bodies are the reason for their gravitational attraction to each other (see the section “Gravity”).
• The mass of a body is equal to the sum of the masses of its parts. This is the so-called additivity of mass. Additivity allows you to use a standard of 1 kg to measure mass.
• The mass of an isolated system of bodies does not change with time (law of conservation of mass).
• The mass of a body does not depend on the speed of its movement. Mass does not change when moving from one frame of reference to another.
• Density of a homogeneous body is the ratio of the mass of the body to its volume:

$(\large p = \dfrac (m)(V) )$

Density does not depend on the geometric properties of the body (shape, volume) and is a characteristic of the substance of the body. The densities of various substances are presented in reference tables. It is advisable to remember the density of water: 1000 kg/m3.

Newton's second and third laws

The interaction of bodies can be described using the concept of force. Force is a vector quantity, which is a measure of the influence of one body on another.
Being a vector, force is characterized by its modulus (absolute value) and direction in space. In addition, the point of application of the force is important: the same force in magnitude and direction, applied at different points of the body, can have different effects. So, if you grab the rim of a bicycle wheel and pull tangentially to the rim, the wheel will begin to rotate. If you pull along the radius, there will be no rotation.

Newton's second law

The product of the body mass and the acceleration vector is the resultant of all forces applied to the body:

$(\large m \cdot \overrightarrow(a) = \overrightarrow(F) )$

Newton's second law relates acceleration and force vectors. This means that the following statements are true.

1. $(\large m \cdot a = F)$, where $(\large a)$ is the acceleration modulus, $(\large F)$ is the resulting force modulus.
2. The acceleration vector has the same direction as the resultant force vector, since the mass of the body is positive.

Newton's third law

Two bodies act on each other with forces equal in magnitude and opposite in direction. These forces have the same physical nature and are directed along the straight line connecting their points of application.

Superposition principle

Experience shows that if several other bodies act on a given body, then the corresponding forces add up as vectors. More precisely, the principle of superposition is valid.
The principle of superposition of forces. Let the forces act on the body$(\large \overrightarrow(F_1), \overrightarrow(F_2),\ \ldots \overrightarrow(F_n))$ If you replace them with one force$(\large \overrightarrow(F) = \overrightarrow(F_1) + \overrightarrow(F_2) \ldots + \overrightarrow(F_n))$ , then the result of the impact will not change.
The force $(\large \overrightarrow(F))$ is called resultant forces $(\large \overrightarrow(F_1), \overrightarrow(F_2),\ \ldots \overrightarrow(F_n))$ or resulting by force.

Forwarder or carrier? Three secrets and international cargo transportation

Forwarder or carrier: who to choose? If the carrier is good and the forwarder is bad, then the first. If the carrier is bad and the forwarder is good, then the latter. This choice is simple. But how can you decide when both candidates are good? How to choose from two seemingly equivalent options? The fact is that these options are not equivalent.

Horror stories of international transport

BETWEEN A HAMMER AND A HILL.

It is not easy to live between the customer of transportation and the very cunning and economical owner of the cargo. One day we received an order. Freight for three kopecks, additional conditions for two sheets, the collection is called.... Loading on Wednesday. The car is already in place on Tuesday, and by lunchtime the next day the warehouse begins to slowly throw into the trailer everything that your forwarder has collected for its recipient customers.

AN ENCHANTED PLACE - PTO KOZLOVICHY.

According to legends and experience, everyone who transported goods from Europe by road knows what a terrible place the Kozlovichi VET, Brest Customs, is. What chaos the Belarusian customs officers create, they find fault in every possible way and charge exorbitant prices. And it is true. But not all...

ON THE NEW YEAR'S TIME WE WERE BRINGING POWDERED MILK.

Loading with groupage cargo at a consolidation warehouse in Germany. One of the cargoes is milk powder from Italy, the delivery of which was ordered by the Forwarder.... A classic example of the work of a forwarder-“transmitter” (he doesn’t delve into anything, he just transmits along the chain).

Documents for international transport

International road transport of goods is very organized and bureaucratic; as a result, a bunch of unified documents are used to carry out international road transport of goods. It doesn’t matter if it’s a customs carrier or an ordinary one - he won’t travel without documents. Although this is not very exciting, we tried to simply explain the purpose of these documents and the meaning that they have. They gave an example of filling out TIR, CMR, T1, EX1, Invoice, Packing List...

Axle load calculation for road freight transport

The goal is to study the possibility of redistributing loads on the axles of the tractor and semi-trailer when the location of the cargo in the semi-trailer changes. And applying this knowledge in practice.

In the system we are considering there are 3 objects: a tractor $(T)$, a semi-trailer $(\large ((p.p.)))$ and a load $(\large (gr))$. All variables related to each of these objects will be marked with the superscript $T$, $(\large (p.p.))$ and $(\large (gr))$ respectively. For example, the tare weight of a tractor will be denoted as $m^(T)$.

Why don't you eat fly agarics? The customs officer exhaled a sigh of sadness.

What is happening in the international road transport market? The Federal Customs Service of the Russian Federation has banned the issuance of TIR Carnets without additional guarantees for several years already federal districts. And she notified that from December 1 of this year she will completely terminate the agreement with the IRU as not meeting the requirements of the Customs Union and is putting forward financial claims that are not childish.
IRU in response: “The explanations of the Federal Customs Service of Russia regarding the alleged debt of ASMAP in the amount of 20 billion rubles are a complete fiction, since all the old TIR claims have been fully settled..... What do we, common carriers, think?

Stowage Factor Weight and volume of cargo when calculating the cost of transportation

The calculation of the cost of transportation depends on the weight and volume of the cargo. For sea transport, volume is most often decisive, for air transport - weight. For road transport of goods, a complex indicator is important. Which parameter for calculations will be chosen in a particular case depends on specific gravity of the cargo (Stowage Factor) .

>Strength

Description forces in physics: term and definition, laws of force, measurement of units in Newtons, Newton's second law and formula, diagram of the effect of force on an object.

Force– any impact leading to a change in the object’s movement, direction or geometric structure.

Learning Objective

• Create a relationship between mass and acceleration.

Main points

• Force acts as a vector concept with magnitude and direction. This also applies to mass and acceleration.
• To put it simply, force is a push or pull, which can be defined by various standards.
• Dynamics is the study of the force that causes objects or systems to move and deform.
• External forces are any external influences that affect the body, and internal forces act from within.

Terms

• Vector velocity is the rate of change of position in time and direction.
• Force is any influence that causes an object to change in motion, direction, or geometric structure.
• A vector is a directed quantity characterized by magnitude and direction (between two points).

Example

To study physics strength standards, causes and effects, use two rubber bands. Hang one on a hook in a vertical position. Find a small object and attach it to the dangling end. Measure the resulting stretch with various items. What is the relationship between the number of suspended objects and the length of the stretch? What happens to the glued weight if you move the tape with a pencil?

Force overview

In physics, a force is any phenomenon that causes an object to go through changes in motion, direction, or geometric design. Measured in Newtons. A force is something that causes an object with mass to change its speed or deform. Force is also described in intuitive terms such as “push” or “push.” Has magnitude and direction (vector).

Characteristics

Newton's second law states that the net force exerted on an object is equal to the rate at which its momentum changes. Also, the acceleration of an object is directly proportional to the force acting on it and is in the direction of the net force and inversely proportional to the mass.

Don't forget that force is a vector quantity. A vector is a one-dimensional array with magnitude and direction. It contains mass and acceleration:

Also associated with force are thrust (increases the speed of an object), braking (decreases speed), and torque (changes speed). Forces that are not applied equally in all parts of an object also lead to mechanical stress (deformation of matter). If in a solid object it gradually deforms it, then in a liquid it changes pressure and volume.

Dynamics

It is the study of the forces that set objects and systems in motion. We understand force as a certain push or pull. They have magnitude and direction. In the figure you can see several examples of the use of force. Top left – roller system. The force to be applied to the cable must equal and exceed the force generated by mass, objects, or the effects of gravity. The top right shows that any object placed on the surface will affect it. Below is the attraction of magnets.

DEFINITION

Force is a vector quantity that is a measure of the action of other bodies or fields on a given body, as a result of which a change in the state of this body occurs. In this case, a change in state means a change or deformation.

The concept of force refers to two bodies. You can always indicate the body on which the force acts and the body from which it acts.

Strength is characterized by:

• module;
• direction;
• application point.

The magnitude and direction of the force are independent of the choice.

The unit of force in the C system is 1 Newton.

In nature, there are no material bodies that are outside the influence of other bodies, and, therefore, all bodies are under the influence of external or internal forces.

Several forces can act on a body at the same time. In this case, the principle of independence of action is valid: the action of each force does not depend on the presence or absence of other forces; the combined action of several forces is equal to the sum of the independent actions of the individual forces.

Resultant force

To describe the motion of a body in this case, the concept of resultant force is used.

DEFINITION

Resultant force is a force whose action replaces the action of all forces applied to the body. Or, in other words, the resultant of all forces applied to the body is equal to the vector sum of these forces (Fig. 1).

Fig.1. Determination of resultant forces

Since the movement of a body is always considered in some coordinate system, it is convenient to consider not the force itself, but its projections onto the coordinate axes (Fig. 2, a). Depending on the direction of the force, its projections can be either positive (Fig. 2, b) or negative (Fig. 2, c).

Fig.2. Projections of force onto coordinate axes: a) on a plane; b) on a straight line (the projection is positive);
c) on a straight line (projection is negative)

Fig.3. Examples illustrating the vector addition of forces

We often see examples illustrating the vector addition of forces: a lamp hangs on two cables (Fig. 3, a) - in this case, equilibrium is achieved due to the fact that the resultant of the tension forces is compensated by the weight of the lamp; the block slides along an inclined plane (Fig. 3, b) - the movement occurs due to the resultant forces of friction, gravity and support reaction. Famous lines from the fable by I.A. Krylov “and the cart is still there!” - also an illustration of the equality of the resultant of three forces to zero (Fig. 3, c).

Examples of problem solving

EXAMPLE 1

Exercise	Two forces act on the body and . Determine the modulus and direction of the resultant of these forces if: a) the forces are directed in one direction; b) forces are directed in opposite directions; c) the forces are directed perpendicular to each other.
Solution	a) forces are directed in one direction; Resultant force: b) forces are directed in opposite directions; Resultant force: Let's project this equality onto the coordinate axis: c) forces are directed perpendicular to each other; Resultant force:

The word “power” is so comprehensive that giving it a clear concept is an almost impossible task. The variety from muscle strength to mind strength does not cover the entire spectrum of concepts included in it. Force, considered as a physical quantity, has a clearly defined meaning and definition. The force formula specifies a mathematical model: the dependence of force on basic parameters.

The history of the study of forces includes the determination of dependence on parameters and experimental proof of the dependence.

Power in Physics

Force is a measure of the interaction of bodies. The mutual action of bodies on each other fully describes the processes associated with changes in speed or deformation of bodies.

As a physical quantity, force has a unit of measurement (in the SI system - Newton) and a device for measuring it - a dynamometer. The operating principle of the force meter is based on comparing the force acting on the body with the elastic force of the dynamometer spring.

A force of 1 newton is taken to be the force under the influence of which a body weighing 1 kg changes its speed by 1 m in 1 second.

Strength as defined:

• direction of action;
• application point;
• module, absolute value.

When describing interaction, be sure to indicate these parameters.

Types of natural interactions: gravitational, electromagnetic, strong, weak. Gravitational universal gravitation with its variety - gravity) exists due to the influence of gravitational fields surrounding any body that has mass. The study of gravitational fields has not yet been completed. It is not yet possible to find the source of the field.

A larger number of forces arise due to the electromagnetic interaction of the atoms that make up the substance.

Pressure force

When a body interacts with the Earth, it exerts pressure on the surface. The force of which has the form: P = mg, is determined by body mass (m). Gravity acceleration (g) has different meanings at different latitudes of the Earth.

The vertical pressure force is equal in magnitude and opposite in direction to the elastic force arising in the support. The formula of force changes depending on the movement of the body.

Change in body weight

The action of a body on support due to interaction with the Earth is often called body weight. Interestingly, the amount of body weight depends on the acceleration of movement in the vertical direction. In the case where the direction of acceleration is opposite to the acceleration of gravity, an increase in weight is observed. If the acceleration of the body coincides with the direction of free fall, then the weight of the body decreases. For example, being in an ascending elevator, at the beginning of the ascent a person feels an increase in weight for some time. There is no need to say that its mass changes. At the same time, we separate the concepts of “body weight” and its “mass”.

Elastic force

When the shape of a body changes (its deformation), a force appears that tends to return the body to its original shape. This force was given the name "elasticity force". It arises as a result of the electrical interaction of the particles that make up the body.

Let's consider the simplest deformation: tension and compression. Tension is accompanied by an increase in the linear dimensions of bodies, compression - by their decrease. The quantity characterizing these processes is called body elongation. Let's denote it "x". The elastic force formula is directly related to elongation. Each body undergoing deformation has its own geometric and physical parameters. The dependence of the elastic resistance to deformation on the properties of the body and the material from which it is made is determined by the elasticity coefficient, let's call it rigidity (k).

The mathematical model of elastic interaction is described by Hooke's law.

The force arising during deformation of the body is directed against the direction of displacement of individual parts of the body and is directly proportional to its elongation:

• F y = -kx (in vector notation).

The “-” sign indicates the opposite direction of deformation and force.

In scalar form negative sign absent. The elastic force, the formula of which has the following form F y = kx, is used only for elastic deformations.

Interaction of magnetic field with current

The effect of a magnetic field on a direct current is described. In this case, the force with which the magnetic field acts on a conductor with current placed in it is called the Ampere force.

The interaction of the magnetic field with causes force manifestation. Ampere's force, the formula of which is F = IBlsinα, depends on (B), the length of the active part of the conductor (l), (I) in the conductor and the angle between the direction of the current and the magnetic induction.

Thanks to the last dependence, it can be argued that the vector of action of the magnetic field can change when the conductor is rotated or the direction of the current changes. The left hand rule allows you to establish the direction of action. If left hand positioned so that the magnetic induction vector enters the palm, four fingers are directed along the current in the conductor, then bent 90 ° thumb will show the direction of action of the magnetic field.

Mankind has found applications for this effect, for example, in electric motors. Rotation of the rotor is caused by a magnetic field created by a powerful electromagnet. The force formula allows you to judge the possibility of changing engine power. As the current or field strength increases, the torque increases, which leads to an increase in motor power.

Particle trajectories

The interaction of a magnetic field with a charge is widely used in mass spectrographs in the study of elementary particles.

The action of the field in this case causes the appearance of a force called the Lorentz force. When a charged particle moving at a certain speed enters a magnetic field, the formula of which has the form F = vBqsinα, causes the particle to move in a circle.

In this mathematical model, v is the modulus of the velocity of a particle whose electric charge is q, B is the magnetic induction of the field, α is the angle between the directions of velocity and magnetic induction.

The particle moves in a circle (or arc of a circle), since the force and speed are directed at an angle of 90 ° to each other. Changing the direction of linear velocity causes acceleration to appear.

The rule of the left hand, discussed above, also occurs when studying the Lorentz force: if the left hand is positioned in such a way that the magnetic induction vector enters the palm, four fingers extended in a line are directed along the speed of a positively charged particle, then bent by 90 ° the thumb will indicate the direction of the force.

Plasma problems

The interaction of a magnetic field and matter is used in cyclotrons. Problems associated with the laboratory study of plasma do not allow it to be kept in closed vessels. High can only exist when high temperatures. Plasma can be kept in one place in space using magnetic fields, twisting the gas in the form of a ring. Controlled ones can also be studied by twisting high-temperature plasma into a cord using magnetic fields.

An example of the effect of a magnetic field under natural conditions on an ionized gas - Polar Lights. This majestic spectacle is observed above the Arctic Circle at an altitude of 100 km above the earth's surface. The mysterious colorful glow of the gas could only be explained in the 20th century. The earth's magnetic field near the poles cannot prevent the solar wind from entering the atmosphere. The most active radiation, directed along magnetic induction lines, causes ionization of the atmosphere.

Phenomena associated with charge movement

Historically, the main quantity characterizing the flow of current in a conductor is called current strength. It is interesting that this concept has nothing to do with force in physics. Current strength, the formula of which includes the charge flowing per unit time through cross section conductor has the form:

• I = q/t, where t is the flow time of charge q.

In fact, current is the amount of charge. Its unit of measurement is Ampere (A), as opposed to N.

Definition of work of force

The force exerted on a substance is accompanied by the performance of work. The work of a force is a physical quantity numerically equal to the product of the force and the displacement passed under its action and the cosine of the angle between the directions of force and displacement.

The required work of force, the formula of which is A = FScosα, includes the magnitude of the force.

The action of a body is accompanied by a change in the speed of the body or deformation, which indicates simultaneous changes in energy. The work done by a force directly depends on the magnitude.

1.Strength- vector physical quantity, which is a measure of the intensity of impact on a given body other bodies, as well as fields Attached to massive force in the body is the reason for its change speed or occurrence in it deformations and stresses.

Force as a vector quantity is characterized module, direction And "point" of the application strength. By the last parameter, the concept of force as a vector in physics differs from the concept of a vector in vector algebra, where vectors equal in magnitude and direction, regardless of the point of their application, are considered the same vector. In physics, these vectors are called free vectors. In mechanics, the idea of ​​coupled vectors is extremely common, the beginning of which is fixed at a certain point in space or can be located on a line that continues the direction of the vector (sliding vectors).

The concept is also used line of force, denoting the straight line passing through the point of application of the force along which the force is directed.

Newton's second law states that in inertial reference systems, the acceleration of a material point in direction coincides with the resultant of all forces applied to the body, and in magnitude is directly proportional to the magnitude of the force and inversely proportional to the mass of the material point. Or, equivalently, the rate of change of momentum of a material point is equal to the applied force.

When a force is applied to a body of finite dimensions, mechanical stresses arise in it, accompanied by deformations.

From the point of view of the Standard Model of particle physics, fundamental interactions (gravitational, weak, electromagnetic, strong) are carried out through the exchange of so-called gauge bosons. Experiments in high energy physics conducted in the 70−80s. XX century confirmed the assumption that the weak and electromagnetic interactions are manifestations of the more fundamental electroweak interaction.

The dimension of force is LMT −2, the unit of measurement in the International System of Units (SI) is newton (N, N), in the GHS system it is dyne.

2.Newton's first law.

Newton's first law states that there are frames of reference in which bodies maintain a state of rest or uniform rectilinear motion in the absence of actions on them from other bodies or in the case of mutual compensation of these influences. Such reference systems are called inertial. Newton suggested that everyone massive object has a certain reserve of inertia, which characterizes the “natural state” of movement of this object. This idea rejects the view of Aristotle, who considered rest to be the “natural state” of an object. Newton's first law contradicts Aristotelian physics, one of the provisions of which is the statement that a body can move at a constant speed only under the influence of force. The fact that in Newtonian mechanics in inertial frames of reference rest is physically indistinguishable from uniform rectilinear motion is the rationale for Galileo's principle of relativity. Among a set of bodies, it is fundamentally impossible to determine which of them are “in motion” and which are “at rest.” We can talk about motion only relative to some reference system. The laws of mechanics are satisfied equally in all inertial frames of reference, in other words, they are all mechanically equivalent. The latter follows from the so-called Galilean transformations.

3.Newton's second law.

Newton's second law modern formulation sounds like this: in an inertial reference frame, the rate of change of momentum of a material point is equal to the vector sum of all forces acting on this point.

where is the momentum of the material point, is the total force acting on the material point. Newton's second law states that the action of unbalanced forces leads to a change in the momentum of a material point.

By definition of momentum:

where is mass, is speed.

In classical mechanics, at speeds much lower than the speed of light, the mass of a material point is considered unchanged, which allows it to be taken out of the differential sign under these conditions:

Given the definition of the acceleration of a point, Newton's second law takes the form:

It is considered to be "the second most famous formula in physics", although Newton himself never explicitly wrote his second law in this form. For the first time this form of the law can be found in the works of K. Maclaurin and L. Euler.

Since in any inertial reference frame the acceleration of the body is the same and does not change when transitioning from one frame to another, then the force is invariant with respect to such a transition.

In all natural phenomena force, regardless of your origin, appears only in a mechanical sense, that is, as the reason for the violation of the uniform and rectilinear motion of the body in the inertial coordinate system. The opposite statement, i.e. establishing the fact of such movement, does not indicate the absence of forces acting on the body, but only that the actions of these forces are mutually balanced. Otherwise: their vector sum is a vector with modulus equal to zero. This is the basis for measuring the magnitude of a force when it is compensated by a force whose magnitude is known.

Newton's second law allows us to measure the magnitude of a force. For example, knowledge of the mass of a planet and its centripetal acceleration when moving in orbit allows us to calculate the magnitude of the gravitational attraction force acting on this planet from the Sun.

4.Newton's third law.

For any two bodies (let's call them body 1 and body 2), Newton's third law states that the force of action of body 1 on body 2 is accompanied by the appearance of a force equal in magnitude, but opposite in direction, acting on body 1 from body 2. Mathematically, the law is written So:

This law means that forces always occur in action-reaction pairs. If body 1 and body 2 are in the same system, then the total force in the system due to the interaction of these bodies is zero:

This means that there are no unbalanced internal forces in a closed system. This leads to the fact that the center of mass of a closed system (that is, one that is not acted upon by external forces) cannot move with acceleration. Individual parts of the system can accelerate, but only in such a way that the system as a whole remains in a state of rest or uniform linear motion. However, if external forces act on the system, its center of mass will begin to move with acceleration proportional to the external resultant force and inversely proportional to the mass of the system.

5.Gravity.

Gravity ( gravity) - universal interaction between any types of matter. Within the framework of classical mechanics, it is described by the law of universal gravitation, formulated by Isaac Newton in his work “Mathematical Principles of Natural Philosophy”. Newton obtained the magnitude of the acceleration with which the Moon moves around the Earth, assuming in his calculation that the force of gravity decreases in inverse proportion to the square of the distance from the gravitating body. In addition, he also established that the acceleration caused by the attraction of one body by another is proportional to the product of the masses of these bodies. Based on these two conclusions, the law of gravitation was formulated: any material particles are attracted towards each other with a force directly proportional to the product of masses ( and ) and inversely proportional to the square of the distance between them:

Here is the gravitational constant, the value of which was first obtained by Henry Cavendish in his experiments. Using this law, you can obtain formulas for calculating the gravitational force of bodies of arbitrary shape. Newton's theory of gravity describes the motion of planets well solar system and many other celestial bodies. However, it is based on the concept of long-range action, contrary to theory relativity. Therefore, the classical theory of gravity is not applicable to describe the motion of bodies moving at speeds close to the speed of light, the gravitational fields of extremely massive objects (for example, black holes), as well as the variable gravitational fields created by moving bodies at large distances from them.

A more general theory of gravity is Albert Einstein's general theory of relativity. In it, gravity is not characterized by an invariant force independent of the reference frame. Instead, the free movement of bodies in a gravitational field, perceived by the observer as movement along curved trajectories in three-dimensional space-time with variable speed, is considered as inertial movement along a geodesic line in a curved four-dimensional space-time, in which time flows differently at different points . Moreover, this line is in a sense “the most direct” - it is such that the space-time interval (proper time) between two space-time positions of a given body is maximum. The curvature of space depends on the mass of bodies, as well as on all types of energy present in the system.

6.Electrostatic field (field of stationary charges).

The development of physics after Newton added to the three main quantities (length, mass, time) an electric charge with dimension C. However, based on the requirements of practice, they began to use not a unit of charge, but a unit of electric current as the main unit of measurement. Thus, in the SI system, the basic unit is the ampere, and the unit of charge, the coulomb, is a derivative of it.

Since the charge, as such, does not exist independently of the body carrying it, the electrical interaction of bodies manifests itself in the form of the same force considered in mechanics, which serves as the cause of acceleration. In relation to the electrostatic interaction of two point charges of magnitude and located in a vacuum, Coulomb's law is used. In the form corresponding to the SI system, it looks like:

where is the force with which charge 1 acts on charge 2, is the vector directed from charge 1 to charge 2 and is equal in magnitude to the distance between the charges, and is the electrical constant equal to ≈ 8.854187817 10 −12 F/m. When charges are placed in a homogeneous and isotropic medium, the interaction force decreases by a factor of ε, where ε is the dielectric constant of the medium.

The force is directed along the line connecting the point charges. Graphically, the electrostatic field is usually depicted as a picture of lines of force, which are imaginary trajectories along which a charged particle without mass would move. These lines start on one charge and end on another.

7.Electromagnetic field (direct current field).

The existence of a magnetic field was recognized back in the Middle Ages by the Chinese, who used the “loving stone” - a magnet, as a prototype of a magnetic compass. Graphically, a magnetic field is usually depicted in the form of closed lines of force, the density of which (as in the case of an electrostatic field) determines its intensity. Historically, a visual way to visualize a magnetic field was with iron filings sprinkled, for example, on a piece of paper placed on a magnet.

Oersted established that the current flowing through a conductor causes a deflection of the magnetic needle.

Faraday came to the conclusion that a magnetic field is created around a current-carrying conductor.

Ampere put forward a hypothesis, recognized in physics, as a model of the process of the emergence of a magnetic field, which consists in the existence in materials of microscopic closed currents, which together provide the effect of natural or induced magnetism.

Ampere established that in a reference frame located in a vacuum, in relation to which the charge is in motion, that is, it behaves like electricity, a magnetic field arises, the intensity of which is determined by the magnetic induction vector lying in a plane located perpendicular to the direction of charge movement.

The unit of measurement of magnetic induction is tesla: 1 T = 1 T kg s −2 A −2
The problem was solved quantitatively by Ampere, who measured the force of interaction between two parallel conductors with currents flowing through them. One of the conductors created a magnetic field around itself, the second reacted to this field by approaching or moving away with a measurable force, knowing which and the magnitude of the current it was possible to determine the module of the magnetic induction vector.

The force interaction between electric charges that are not in motion relative to each other is described by Coulomb's law. However, charges in motion relative to each other create magnetic fields, through which the currents created by the movement of charges in the general case come into a state of force interaction.

The fundamental difference between the force that arises during the relative motion of charges and the case of their stationary placement is the difference in the geometry of these forces. For the case of electrostatics, the forces of interaction between two charges are directed along the line connecting them. Therefore, the geometry of the problem is two-dimensional and consideration is carried out in a plane passing through this line.

In the case of currents, the force characterizing the magnetic field created by the current is located in a plane perpendicular to the current. Therefore, the picture of the phenomenon becomes three-dimensional. The magnetic field created by an infinitely small element of the first current, interacting with the same element of the second current, generally creates a force acting on it. Moreover, for both currents this picture is completely symmetrical in the sense that the numbering of currents is arbitrary.

The law of interaction of currents is used to standardize direct electric current.

8.Strong interaction.

The strong force is the fundamental short-range interaction between hadrons and quarks. In the atomic nucleus, the strong force holds together positively charged (experiencing electrostatic repulsion) protons through the exchange of pi mesons between nucleons (protons and neutrons). Pi mesons have a very short lifespan; their lifetime is only enough to provide nuclear forces within the radius of the nucleus, which is why nuclear forces are called short-range. An increase in the number of neutrons “dilutes” the nucleus, reducing electrostatic forces and increasing nuclear ones, but at large quantities neutrons, they themselves, being fermions, begin to experience repulsion due to the Pauli principle. Also, when the nucleons get too close, the exchange of W bosons begins, causing repulsion, due to this atomic nuclei don't "collapse".

Within the hadrons themselves, the strong interaction holds together the quarks - the constituent parts of hadrons. Strong field quanta are gluons. Each quark has one of three “color” charges, each gluon consists of a “color”-“anticolor” pair. Gluons bind quarks in the so-called. “confinement”, due to which free quarks have not been observed in the experiment at the moment. As quarks move away from each other, the energy of gluon bonds increases, and does not decrease as in nuclear interaction. By spending a lot of energy (by colliding hadrons in an accelerator), you can break the quark-gluon bond, but at the same time a jet of new hadrons is released. However, free quarks can exist in space: if some quark managed to avoid confinement during big bang, then the probability of annihilating with the corresponding antiquark or turning into a colorless hadron for such a quark is vanishingly small.

9.Weak interaction.

The weak interaction is a fundamental short-range interaction. Range 10 −18 m. Symmetrical with respect to the combination of spatial inversion and charge conjugation. All fundamental elements are involved in weak interaction.fermions (leptons And quarks). This is the only interaction that involvesneutrino(not to mention gravity, negligible in laboratory conditions), which explains the colossal penetrating ability of these particles. The weak interaction allows leptons, quarks and theirantiparticles exchange energy, mass, electric charge And quantum numbers- that is, turn into each other. One of the manifestations isbeta decay.