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Вы можете ознакомиться и скачать презентацию на тему Electric Forces. Доклад-сообщение содержит 26 слайдов. Презентации для любого класса можно скачать бесплатно. Если материал и наш сайт презентаций Mypresentation Вам понравились – поделитесь им с друзьями с помощью социальных кнопок и добавьте в закладки в своем браузере.

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Physics 1 Voronkov Vladimir Vasilyevich

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Lecture 8 Electrostatics Electric charge. Coulomb’s law. Electric field. Gauss’ law. Electric potential.

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Electric Forces Electric forces are dominant in the behavior of matter. The electric forces are responsible for: Electrons, binding to a positive nucleus, forming a stable atom; Atoms, binding together into molecules; Molecules binding together into liquids and solids; All chemical reactions; All biological processes. Friction and other contact forces.

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Electrostatics Electrostatics is the science of stationary charges. There exists two types of charges – positive and negative. If an object has an excess of electrons, it is negatively charged; if it has a deficiency of electrons, it is positively charged. Like charges repel, and unlike charges attract.

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Charging by induction We have a neutrally charged conductor. Negatively charged rod polarizes the sphere. The charge in the rod repels electrons to the opposite side of the sphere. Then we ground the sphere and some part of electrons is repelled into the Earth. There is induced positive charge near the rod. Then ground connection is removed. Eventually, we get positively charged sphere.

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The Law of Conservation of Charge Charge of an isolated system is conserved. This law is a fundamental physical law: net charge is the same before and after any interaction.

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Elementary charges Elementary charges are electrons and protons. Usually only electrons can be free and take part in electrical processes. Excess of electrons causes negative charge and deficiency of electrons causes positive charge of a body.

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Coulomb’s law From Coulomb’s experiments, we can generalize the following properties of the electric force between two stationary point charges: is inversely proportional to the square of the separation r between the particles and directed along the line joining them; is proportional to the product of the charges q1 and q2 on the two particles; is attractive if the charges are of opposite sign and repulsive if the charges have the same sign; is a conservative force.

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Coulomb’s Law The magnitude of the electric force is is the Coulomb constant, it can be written in the following form: where is the electric permittivity of free space.

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In a vector form, the force exerted by charge q1 on q2 is: In a vector form, the force exerted by charge q1 on q2 is: Where is a unit vector directed from q1 to q2. (a) two similar charges repels (b) two different charges attracts

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Forces of Multiple Charges Electrostatic force is a vector quantity, so in the case of multiple charges the principle of superposition is applicable: The total force on charge q2 is the vector sum of all forces:

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Electric Field In general: field forces can act through space, producing an effect even when no physical contact occurs between interacting objects. Charges gives rise to an electric field. The electric field can be detected at any particular point by a small test positive charge qo and observing if it experiences a force. Then the electric field vector is: Note: force Fe and field E are not produced by the test charge qo .

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Electric Field Vector The force exerted by q on the test charge q0 is: Then dividing it by q0 we get the electric field vector: Electric field is created by a charge. If a charge is positive then the electric field vector is directed away from the source charge. If a charge is negative then the electric field vector is directed to the source charge.

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Continuous Charge Distribution Volume charge density Surface charge density Linear charge density

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Electric Field of a Uniformly Charged ring A ring of radius a carries a uniformly distributed positive total charge Q. Let’s find the electric field due to the ring along the central axis perpendicular to the plane of the ring.

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dE is the ﬁeld at point P on the x axis due to an element of charge dq. dE has two perpendicular components: EX and E. Using the symmetry: The perpendicular component of the field at P due to segment 1 is canceled by the perpendicular component due to segment 2. Thus the total E is directed along x axis.

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Extreme Case Analysis So we found the electric field of a uniformly charged ring along its symmetry axis at distance x from the centre of a ring: ke is the Coulomb constant, a – the ring’s radius, Q – the charge of the ring. Let’s analyze the obtained result for extreme cases: If x=0, then E=0. If x>>a, then we get the Coulomb formula for a point charge: Look more examples of calculating electric field for continuous charge distribution: in Serway p.721-723, Fishbane 642-647.

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Gauss’ Law The net flux of electric field through any enclosed surface are equal to the net charge inside that surface divided by permittivity of free space. Here E·dA is a scalar product of electric field and differential of area vectors.

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Electric Flux Ai is a vector, which magnitude represents the area of the i-th element of the surface and direction is deﬁned to be perpendicular to the surface element. The variation in the electric ﬁeld over one element of surface can be neglected if the element is sufﬁciently small.

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According to the Gauss’ theorem electric flux through any surface S1, S2, S3 is the same. According to the Gauss’ theorem electric flux through any surface S1, S2, S3 is the same. Electric flux from a charge located outside a surface equals zero. The number of lines entering the surface equals the number leaving the surface and the net number equals zero.

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Electric Potential Energy For infinitesimal displacement ds the work done by the electric field on the charge is . Then the change in the potential energy of the charge-field system is Thus for finite displacement from A to B the change in potential energy is This line integral is not path-dependant, as the electric force is conservative.

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Electric Potential The electric potential at any point in an electric field is The potential difference V=VB - VA between two points A and B in an electric field is defined as q0 is a test charge.

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Potential Properties Just as with potential energy, only differences in electric potential are meaningful. Electric potential is a scalar characteristic of an electric ﬁeld, independent of any charges that may be placed in the electric field. Electric potential energy depends on the magnitude of the charge, interacting with the field.