Tĩnh điện là gì

Tĩnh năng lượng điện là hiện tượng mất cân đối năng lượng điện bên trên mặt phẳng của một vật tư. Điện tích sẽ tiến hành lưu giữ làm việc kia cho tới Khi nó hoàn toàn có thể tương truyền khu vực không giống thông qua 1 loại điện hoặc sự phóng năng lượng điện.

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Static is generated when two objects made of different electrically neutral materials tương tác & then separate.

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1) Contact between objects A & B

Electrically neutral objects A và B (with equal quantities of positive và negative charges)

2) Transfer of charge

When metals tương tác each other, electrons move from one with a smaller work function to one with a larger work function. In other words, metal with a smaller work function will be charged positively và one with a larger work function negatively.

3) Separation between objects A & B

Object A is charged negatively and object B positively.

Figure 1. Static generation due to liên hệ charging

Static is generated when two objects tương tác & then separate. The combination of the two objects may be solid và solid, solid & liquid, or liquid và liquid. Figure 2 shows examples.

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Figure 2. Examples of static generation

All the above phenomemãng cầu involve sầu liên hệ between two objects & their separation.

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Figure 3. Examples of charging

Friction between two objects in a triboelectric series causes the object in the upper position of the series khổng lồ be charged positively và that in the lower position khổng lồ be charged negatively. Friction between two objects positioned far apart (C) also generates a larger amount of static than ones closer to each other (B) & much closer to lớn each other (A) (A

When an object is charged

When an object is charged electrostatically, an electrical field is generated around the charged object, as illustrated in Figure 4.

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Figure 4. Electrical field generated around charged objects

An electrical field is a space in which an electric charge induces its electric force (Coulomb force) to lớn work. An electrical field that does not change over time or spatially is called an electrostatic field. The number of lines of electric force that pass a unit area of a certain point (density of lines) indicates the strength of the electrical field, while the tangential direction of the lines of electric force on the point indicates the direction of the electrical field. The line of electric force also has the following characteristics.

Starts from a positive sầu electric charge and ends in a negative sầu electric chargeLines bởi not intersect each otherDoes not branch offThe electrical field is svào when lines of electric force are denseThe electrical field is unisize when lines of electric force are parallelComes out of (enters into) the surface of a conductor vertically

Figure 5 shows an example of lines of electric force formed between two charged objects.

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(a) Lines of electric force between objects with different electrical polarities

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(b) Lines of electric force between objects with the same electrical polarity

Figure 5. Lines of electric force formed between two charged objects

Lines of electric force are virtual lines used to lớn visualize an electrical field. Their use shows the state of an electrical field formed between two charged objects, making it easy to lớn picture the state of static, which is actually invisible. For example, Figure 6 shows lines of electric force between two objects with different quantities of electric charge. It shows lines of electric force that apply khổng lồ a case where the quantity of electric charge quận 1 of charged object A is smaller than the quantity of electric charge Q2 of charged object B. Because the size of the two charged objects is the same, the number of lines of electric force per unit surface area of charged object A is smaller than that of charged object B, và electrical field E2 is stronger than E1.

E1: Strength of electrical field on a conductor surface

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Density of lines of electric force: Low à Electrical field is weak

Charged conductive sầu sphere A

E2: Strength of electrical field on a conductor surface

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Density of lines of electric force: High à Electrical field is strong

Charged conductive sầu sphere B

Figure 6. Lines of electric force from two charged conductors with different quantities of electric charge

What is electrostatic force (Coulomb force)?

Electrostatic force (Coulomb force) is the source of an electrostatic phenomenon. As Figure 7 shows, the direction of the force between two charged objects differs according to lớn whether the objects have different electrical polarities or the same electrical polarity. Electrostatic force is an attractive force (a) when the polarities are different and a repulsive sầu force (b) when the two objects have sầu the same electrical polarity.

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(a) Force between objects with different electrical polarities

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(b) Force between objects with the same electrical polarity

Figure 7. Electrostatic force between two charged objects

As Formula (1) shows, the strength of the electrostatic force (Coulomb force) is proportional lớn the hàng hóa of the quantities of the electric charge of the two charged objects and inversely proportional lớn the square of the distance between the two objects.

F ∝Q1・Q2/r2 ・・・・・・・・・・・・(1)

Electrostatic induction is also caused by electrostatic force

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Figure 8. Electrostatic induction caused by electrostatic force

Electrostatic discharge is also caused by electrostatic force (Coulomb force)

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Figure 9. Generation of electrostatic discharge caused by electrostatic force

The electrical field around the charged object causes the negative ions (electrons) therein to lớn be accelerated by the electrostatic force (Coulomb force), thereby having kinetic energy (wv). When these negative ions strike gas molecules in the electrical field và the following formula is true,

Ionization energy of the gas molecules

electrons are sputtered from the gas molecules, resulting in generation of negative sầu ions and positive sầu ions. The gas molecules are ionized if the negative ions thus generated are subject khổng lồ action of the electrostatic force and the negative ions are accelerated in the electrical field with its kinetic energy meeting the condition expressed in formula (2) above sầu. Repetition of this process results in generation of electrostatic discharge.

Charge distribution of a conductor is also influenced by electrostatic force (Coulomb force)

1) Electric charges given to an electrically neutral conductor are distributed on the conductor’s surface. In other words, electric charges given vị not exist inside the conductor.Suppose that a conductor is given four negative electric charges, thereby charged negatively, as Figure 10 shows. If the four charges are given inside conductor (a), electrostatic force (repulsive sầu force) works among muốn them, forcing them lớn be distributed on the conductor surface.

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Figure 10. Distribution of electric charges on a charged conductive sphere

2) As explained in the previous section, electric charges given to an electrically neutral conductor are distributed on the conductor’s surface. These charges are distributed in a way that the surface will be equipotential. In other words, the charges given will not exist inside the conductor. Charges on a conductor are distributed in such a way that the surface will be equipotential.

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(a) Conductor with surface potential distribution

If a conductor surface has potential distribution (a), a potential gradient (electrical field Ex) is generated along the surface. Ex causes the electric charges on the conductor surface to move along the surface to a part with low potential, thereby heightening the potential of the part. This movement of electric charges continues until the surface becomes equipotential.As a result, the electrical field that comes out of (enters via) the surface of the conductor is vertical khổng lồ the surface (b).

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(b) Electric charges that are distributed in a way that makes the conductor surface equipotential

Figure 11. Electric charges are distributed on a conductor surface in a way that makes the surface equipotential.