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==References==
==References==
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{{reflist3 test|refs=
<!--        Normal  0          false  false  false    EN-US  X-NONE  X-NONE                                                                                                                                                                                                                                                                                                                                                            <ref name=barnes1982>Barnes J. (1982) [ ''The Presocratic Philosophers']. Psychology Press. ISBN 978041505079. | [http://books.google.com/books?id=9EQXMQtS9SYC&dq=Thales+amber&source=gbs_navlinks_s Google Book extracts]. | Thales probably considered the attractive force of rubbed amber a reflection of an animate nature of amber.</ref>  -->


<!-- <ref name=franklin1747>Franklin B. (1747) Letter: To Peter Collinson, Philadelphia, July 11, 1747.  In: Albert Henry Smyth (editor). ''The Writings of Benjamin Franklin''. Vol. 2, Item #60. The Macmillan Company, 1905. | [http://books.google.com/books?id=7-B2AAAAMAAJ&dq=the+writings+of+benjamin+franklin&source=gbs_navlinks_s Google Book Full-Text].</ref> -->
<!-- <ref name=franklin1747>Franklin B. (1747) Letter: To Peter Collinson, Philadelphia, July 11, 1747.  In: Albert Henry Smyth (editor). ''The Writings of Benjamin Franklin''. Vol. 2, Item #60. The Macmillan Company, 1905. | [http://books.google.com/books?id=7-B2AAAAMAAJ&dq=the+writings+of+benjamin+franklin&source=gbs_navlinks_s Google Book Full-Text].</ref> -->

Revision as of 16:33, 12 June 2011

Introduction

Once you have established those basic ideas about electricity, "like charges repel and unlike charges attract", then you have the foundation for electricity and can build from there.
—Electric Charge, Hyperphysics Online

In reference to the physics and chemistry of electricity, charge, or more specifically, electric charge, is a fundamental property of matter that causes certain types of matter to generate and react to a force of attraction or repulsion to spatially separate matter that likewise manifests the property of electric charge.[1]

Whatever constitutes electric charge constitutes it in two separate varieties, or polarities, assigned the names 'positive' and 'negative', or 'plus' and 'minus'. The force of attraction between electrically charged items of matter arises between oppositely-charged items—positive-negative—whereas the force of repulsion arises between like-charged items—positive-positive, or negative-negative.

Familiar examples of positively charged matter are protons, constituents of the nuclei of atoms, and familiar examples of negatively charged matter are electrons, constituents of atoms that surround their nuclei.

Given that the terms 'positive' and 'negative' serve only as labels to distinguish the two polarities observed in the electric charge of matter, 'positivity' and 'negativity' do not themselves imply anything about the fundamental nature of electric charge. Other labels connoting di-polarity, such as yin/yang or bitter/sweet, could serve for labeling.

The atoms that comprise the chemical elements of the periodic table, while consisting in part of the electrically charged particles, protons and electrons, do not themselves manifest an electric charge, because protons in the nuclei and the surrounding electrons are equal in number and quantity of charge, that balance ensuring that the atoms as a whole manifest no net electric charge—a state referred to as electrical neutrality.

Discovery and naming of electric charge

The ancient Greeks as far back of Thales of Miletus in the 7th century BCE had observed some of the simple phenomenology related to electric charge, speculating on mechanism, though little came of it, including terminology.[2]

References

  1. Gibilisco S. (2005) Electricity Demystified. New York: McGraw-Hill. | Stan Gibilisco is an electronics engineer and mathematician, author of numerous technical books on electronics and mathematics.
  2. Houston EJ. (1905) Electricity in every-day life. New York: P. F. Collier & Son, 1905. | Google Book Full-Text Volume 1 of 3. | Compares rubbed amber with rubbed Aladdin's lamp.