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Community Contributions - Articles by goIITians
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| a great way of explaining electric fields.......plzzzz see this............. |
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Tagged with:
academic
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![[Post New]](/templates/default/images/icon_minipost_new.gif) posted on 7 Aug 2007 16:59:27 IST
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| Section 1. Gravitational Field vs. Electric Field | | |
| The concept of electric field was introduced by Michael Faraday. The electrical field force acts between two charges, in the same way that the gravitational field force acts between two masses. We know about accelaration of the earth, i.e., the gravity (g = 9.8 m/s2), but where does this number come from? It comes from Newton's law of universal gravitation. It states that every matter which has a mass attracts other matters with a force that is directly proportional to the product of their masses and inversely proportional to the square of the distance between the centers of gravity of the two matters. where:  or  (constant), - me = mass of the earth (kg),
- mo = mass of an object (kg), and
- d = distance between the earth and the object (m).
We already studied about gravitational force of an object on earth, which is F = m*g, where "m" is mass of the object and "g" is the gravity of the earth. Then, we can say that  . Therefore, gravity (g) of the earth is  , where "m e" is the mass of the earth and "d" is its radius (we are talking about gravitational force on the surface of the earth.). |
| | Electric field lines can be drawn using field lines. They are also called force lines. | | | 
(Positive charge electric field) | The field lines are originated from the positive charge. | 
(Negative charge electric field) | The field lines end up at the negative charge. | | |  | A positive charge exerts out and a negative charge exerts in equally to all directions; it is symetric. Field lines are drawn to show the direction and strength of field. The closer the lines are, the stronger the force acts on an object. If the lines are further each other, the strength of force acting on a object is weaker. | | | Section 3. Gravitational Potential vs. Electric Potential | | | Any matter lifted from the surface of the earth has a potential energy. This gravitational potential energy is given by the formula PE=mgh, and the potential energy can be altered by changing its height. The electrical potential energy also can be changed by changing distance between two charges. |
|  | Gravitational potential energy equals to product of the mass of an object, gravitational field force, and its height from the earth. PEG = mgh where: - m is the mass of the ball (kg),
- g is the gravitational field force (g = 9.8 m/s2), and
- h is the distance between the ball and the earth (m).
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| Electric potential energy equals to the electric potential energy divided by charge. PE = qEd (see right) where: - q is the charge of an object (C),
- E is electric field produced by Q (N/C), and
- d is the distance between the two charges. (see right)
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| Electric potential is called Voltage, which can be derived from above equation. Voltage is also related to force. V = Ed = (F/q)*d = Fd/q= W/q (W = Fd -- force times displacement in the direction of force is work (J)) A high voltage means that each individual charge is experiencing a large force. A low voltage means that each individual charge is experiencing a small force. | | | |  |  | | | "q" on A has smaller force than "q" on B. If the distance of B is one half of that of A, the force acting on B is twice as large as A because the force is inversely proportional to the square of the distance between two charges. | | | A has high potential energy because these particles want to separate from each other. B has high potential energy because these particles want to come together. It is the same priciple as the gravity. |  | | |  | C has lower potential energy compared to A because the electric field force is inversely proportional to the square of its distance. D has lower potential energy compare to B for the same reason. | | | When same charges are put close together, we say we have a high voltage because it has a high potential energy. |  | | |  | Largeer the distance is, the smaller the force and voltage are. | | | If the spheres are broght close together, the charge will try to get as far away from each other as possible. As a result, the voltage becomes equal on both sphere. | | |  | | | Charge will always move until the force acting on it is reduced to a minimum or until the voltage becomes the same. |
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this article: 28 points
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(posted on 7 Aug 2007 20:04:13 IST)
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| plzzz post ur comments..................!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
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(posted on 9 Aug 2007 12:23:48 IST)
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| any comments.........!!!!!!!!!!!!!!!!!!!! |
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(posted on 9 Aug 2007 18:53:24 IST)
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| good ............. |
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(posted on 9 Mar 2008 23:27:05 IST)
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| did u find it useful? |
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(posted on 10 Mar 2008 12:26:10 IST)
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| good |
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(posted on 10 Mar 2008 16:00:41 IST)
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| nice article.............. |
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(posted on 13 May 2008 17:20:31 IST)
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| good explanation |
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(posted on 19 Jun 2008 23:46:27 IST)
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| awesome ab mil gaye sab ek saal kyun nahi dekha ! |
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(posted on 20 Jun 2008 15:35:08 IST)
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| great! |
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(posted on 21 Jun 2008 22:51:25 IST)
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| nice article....!!!! |
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(posted on 22 Jun 2008 13:26:00 IST)
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| just excellent |
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(posted on 22 Jun 2008 13:38:46 IST)
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| yupp gud 1 |
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