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Electricity is a property of certain subatomic
particles, such as electrons and protons, that gives rise to attractive and repulsive forces between them. It
is one of the four fundamental forces of nature, and is a
conserved property of matter that can be quantified. In this sense, the phrase
"quantity of electricity" is used interchangeably with the phrases "charge of electricity" and "quantity of charge." There are
two types of electricity or charge: we call one kind of charge positive and the other negative. Through experimentation, we find
that like-charged objects repel and opposite-charged objects attract one another. The magnitude of the force of attraction or
repulsion is given by Coulomb's Law. Some electrical effects are
discussed under electrical phenomenon and electromagnetism.
The SI unit of electrical charge is the coulomb.
History
According to Thales of Miletus, writing circa
600 BC, electricity was known to the Ancient Greeks, who found that rubbing fur on various substances, such
as amber, would cause a particular attraction between the two. The Greeks noted that the amber buttons could attract light objects such as hair, and that if they rubbed the amber for long enough, they could even get a spark to jump.
An object found in Iraq in 1938, dated to about 250 BC and called the Baghdad Battery, resembles an
electrochemical cell and is believed by some to have been used for electroplating. There is no "firm" documentary
evidence to indicate what the object was used for, though there are other anachronistic descriptions of electrical devices on Egyptian walls and in ancient writings.
In 1600 the English scientist William Gilbert returned to the subject in De Magnete, and coined the modern Latin word
electricus from ηλεκτρον (elektron), the Greek word for amber,
which soon gave rise to the English words electric and electricity. He was followed in 1660 by Otto von Guericke, who invented an early electrostatic generator. Other European pioneers were Robert Boyle, who stated in 1675 that
electric attraction and repulsion can act across a vacuum; Stephen Gray,
who in 1729 classified materials as conductors and insulators; and C. F. Du Fay, who first identified the
two types of electric charge that would later be called positive and negative. The Leyden jar, a type of capacitor for storing electric
charge in large quantities, was invented at Leyden University by Pieter van
Musschenbroek in 1745. William
Watson, experimenting with the Leyden jar, discovered in 1747 that a discharge of
static electricity was equivalent to an electric current.
In June, 1752, Benjamin Franklin promoted his investigations of electricity and theories through the famous,
though extremely dangerous, experiment of flying a kite during a thunderstorm. Following these
experiments he invented a lightning rod and established the link between
lightning and electricity. If Franklin did fly a kite in a storm, he did not do it the way it is often described (as it would
have been dramatic but fatal). It was either Franklin (more frequently) or Ebenezer Kinnersley of
Philadelphia (less frequently) who created the convention of positive and
negative charge. Franklin's observations aided later scientists such as Michael Faraday, Luigi Galvani, Alessandro Volta, André-Marie Ampère, and Georg Simon Ohm whose work
provided the basis for modern electrical technology. The work of Faraday, Volta, Ampere, and Ohm is honored by society, in that
fundamental units of electrical measurement are named after them.
Volta worked with chemicals and discovered that chemical reactions could be
used to create positively charged anodes and negatively charged cathodes. When a conductor was attached between these, the difference
in the electrical potential (also known as voltage) drives a current between them through the conductor. The potential difference between two points is measured in units of volts in recognition of Volta's work.
The late 19th and early 20th century produced such giants of electrical engineering as Samuel Morse, inventor of the telegraph; Alexander Graham Bell, inventor of the telephone; Thomas Edison (inventor of the phonograph and a practical
incandescent light bulb); George Westinghouse, inventor of the electric locomotive; Charles
Steinmetz, inventor of alternating current.
Nikola Tesla performed experiments with very high voltages that are the
stuff of legend, involving ball lightning and other effects (some have
been duplicated or explained; and others which have not). Nikola Tesla, inventor of the induction motor and developer of polyphase systems, contributed to the world of electrodynamics the theory
of polyphase alternating current electricity, which he used to build the first
induction motor, invented in 1882. In May 1885, Westinghouse, then president of the
Westinghouse Electric Company in Pittsburgh,
Pennsylvania, bought the rights to Tesla's patents for polyphase alternating-current dynamos. This led to a contest in the
so-called court
of public opinion as to which system would be adopted as the standard for power transmission (known as the War of Currents), Edison's direct-current system or Westinghouse's
alternating-current method.
Edison conducted a spirited public relations campaign which
included his promotion of the electric chair as a method of execution. The electric chair ran on Westinghouse's AC; Edison wanted to prove that AC power was capable of killing, and
should therefore be viewed by the public as inherently dangerous. This fear, uncertainty and
doubt campaign included the electrocution of Topsy the
Elephant. AC power transmission was eventually adopted as the standard.
Electric power
Electric power, for most consumers, is generated centrally by
utility companies using coal, oil, hydropower, or
nuclear power. In 2000, U.S. electric utilities had 600 gigawatts of
maximum summer generating capacity including 261 GW from coal, 41 GW from petroleum, 118 GW from natural gas, 92 GW from hydropower and 86 GW from nuclear fuels. Little generating capacity is
presently based on renewable energy sources such as solar power and wind power. Some
individuals and communities prefer renewable sources because there is less pollution, and because users of renewable energy
sources can sometimes gain a measure of economic independence from the electrical utilities.
Things that are powered by electricity include lamps; computers and the Internet; radio and television; refrigeration; air conditioning; traffic signals; electric guitars and other electronic musical instruments; the spark plugs in automobiles.
Today, for residents of most developed countries, 24-hour, on-demand access to electrical power is taken for granted. People
gripe about their electric bill and about electric power monopolies and utility pricing, but by any comparison with
pre-industrial standards of living, electricity is still a bargain. Few would want to go back to life without it.
In electrical engineering, the energy in
electromagnetic fields is harnessed to perform useful work—either as a method to transmit energy to the appropriate place
and then convert it back into a different, useful form of energy (for instance, heat, light, or motion), or by using the presence
or level of electricity to convey information.
Today's electrical engineers enjoy the ability to design circuits using
pre-manufactured building blocks such as power supplies, resistors, capacitors, semiconductors such as transistors, and integrated circuits. An
integrated circuit inside a computer, a microprocessor, performs millions of
computations per second.
Electric current
A flow of electric charge is called an electric current. A direct
current (DC) is a steady flow; alternating current (AC)
is a flow whose time average is zero, but is not zero at all times. That definition of AC implies that the flow repeatedly
changes direction. (Polarity and numerical sign (i.e. negative vs. positive) are
additional terms for direction in this sense).
It is often important, particularly for safety reasons, that one side of a circuit be electrically bonded to an earth
terminal. Such an earth terminal is usually connected to an electrode buried in
the ground. The potential of earth (ground) is defined as zero by convention, and the electrical conductivity between similarly buried electrodes is considered to be low enough
that all earth terminals are effectively at the same voltage.
Flows of electric charge can be produced within conductors and cannot exist within insulators. Some
electrical devices that use electrical physics are called electronic devices.
See electrical conduction for more information about
current flow in materials.
Ohm's Law is an important relationship describing the behaviour of electric
currents: voltage potential difference = current * resistance, or:
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Electrical phenomena in nature
Sometimes due to problems, a phenomenon known as a power surge can be
created, which can be very damaging to sensitive electrical equipment such as computers. However, you can help to prevent such damage by using a surge protector.
Terminology issues
In addition to its definition by physicists, the word electricity has several popular definitions which are
contradictory. Rather than using the word electricity to refer to the quantity of electric charge, many sources instead say that electricity is the quantity of electromagnetic energy
measured in joules or kilowatt-hours. Other sources
call the flow of charges within a conductor by the name electricity and they measure the quantity of electricity in
terms of amperes. Still others call a wide variety of electrical phenomena by the name
electricity, e.g. bioelectricity, piezoelectricity, triboelectricity, etc. It is advisable to be extremely careful when
interpreting texts which use the frequently misused term electricity in place of the more accurate terms electric charge, electric current, electrical energy,
etc.
See also
External links
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