Electric Polarization: Difference between revisions
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== See Also == | == See Also == | ||
[[*Charge]] | |||
=== Further Reading === | === Further Reading === | ||
Physics of Dielectrics for the Engineer by Roland Coelho | Physics of Dielectrics for the Engineer by Roland Coelho |
Revision as of 13:48, 4 December 2015
Claimed by Jae
The Main Idea
Electric polarization is the process of inducing an object to separate charges inside it. One portion of the object would be mostly positive charges and the other portion would be mostly negative.
When an object is charged, either positively or negatively, it is attracted to another object through polarization. Even if the net charge of the second object is zero, it would still be attracted to the first object. Although the neutral object initially does not make an electric field that attracts or repels the charged object, the charged object affects the neutral object to be an induced dipole. However, this dipole is not permanent. If the charged object is removed, there would be no electric field applied and no polarization. The induced dipole will go back to being a neutral object.
Cause of Polarization
Structure of atom explains polarization. Protons in an atom are in the nucleus, and they are tightly bound. However, electrons located in the electron cloud of an atom are loosely bound compared to the protons. Therefore, the electrons can be induced to move to one side of the atom, and this phenomenon causes polarization of the atom, making it to be an induced dipole.
Conductors and Insulators
Polarization for insulators occurs in a different manner from conductors. When a conductor is polarized, electrons move across the surface of one side of the conductor to the other side. Unlike conductors, in insulators, electrons are not able to freely move around. Thus, individual molecules in the insulators are polarized, but electrons move only small distance compared to the case in conductors, so the charges are not on the surface of the object. Excess charges on conductors can only exist on the surface, while they exist anywhere on or inside insulators.
Misconception
Polarization is a different idea from charging or discharging. While polarization causes a separation of charges in an object, it does not cause imbalance of charges, which forms a charged object. Polarization still maintains an equal number of protons and electrons in an object. Therefore charging is a different discussion from polarization.
Examples
Connectedness
Polarization is one of the main ideas in electricity and occurs whenever there is a charged object near another object. Real life applications includes when a balloon sticks to a wall after it is charged. Balloon causes the wall to polarized, and it is attracted to it in the air.
Polarization is connected to mechanical engineering major, since using charged object as a material for designing something would require the person to take consideration possible interaction or attraction of the invention with other objects due to polarization.
Polarization is a process that is used for certain charging methods. For example, induction charging is when polarization causes a neutral object to be a induced dipole, and the positive part of it attracts electrons, making the object to be negatively charged.
History
Benjamin Franklin was the first person to use "positive" and "negative" in describing charges and came up with principle of conservation of charges. In 1897, J.J. Thomson experimented with cathode rays and found out that electrons exist in the rays. In 1911, Ernest Rutherford discovered that atoms have a concentrated positive center with protons fixed inside nucleus.
See Also
Further Reading
Physics of Dielectrics for the Engineer by Roland Coelho
Application
http://www.nrcresearchpress.com/doi/abs/10.1139/t89-067?journalCode=cgj#.VmFE97mFPIU
External Links
https://courses.cit.cornell.edu/ece303/Lectures/lecture7.pdf
Reference
http://www.physicsclassroom.com/class/estatics/Lesson-1/Polarization
https://www.youtube.com/watch?v=3xSIA5UVAo8
http://scienceline.ucsb.edu/getkey.php?key=408
https://www.aip.org/history/gap/Franklin/Franklin.html
Matter and Interactions Fourth Edition by Ruth W. Chabay, Bruce A. Sherwood