Electric charge causes the leaves to visibly repel each other. By modern convention, the charge carried by
electrons is defined as negative, and that by
protons is positive. Before these particles were discovered,
Benjamin Franklin had defined a positive charge as being the charge acquired by a glass rod when it is rubbed with a silk cloth. A proton by definition carries a charge of exactly . This value is also defined as the
elementary charge. No object can have a charge smaller than the elementary charge, and any amount of charge an object may carry is a multiple of the elementary charge. An electron has an equal negative charge, i.e. . Charge is possessed not just by
matter, but also by
antimatter, each
antiparticle bearing an equal and opposite charge to its corresponding particle. The presence of charge gives rise to an electrostatic force: charges exert a
force on each other, an effect that was known, though not understood, in antiquity. A lightweight ball suspended by a fine thread can be charged by touching it with a glass rod that has itself been charged by rubbing with a cloth. If a similar ball is charged by the same glass rod, it is found to repel the first: the charge acts to force the two balls apart. Two balls that are charged with a rubbed amber rod also repel each other. However, if one ball is charged by the glass rod, and the other by an amber rod, the two balls are found to attract each other. These phenomena were investigated in the late eighteenth century by
Charles-Augustin de Coulomb, who deduced that charge manifests itself in two opposing forms. This discovery led to the well-known axiom:
like-charged objects repel and opposite-charged objects attract. The electromagnetic force is very strong, second only in strength to the
strong interaction, but unlike that force it operates over all distances. In comparison with the much weaker
gravitational force, the electromagnetic force pushing two electrons apart is 1042 times that of the
gravitational attraction pulling them together. Within the system, charge may be transferred between bodies, either by direct contact or by passing along a conducting material, such as a wire. By historical convention, a positive current is defined as having the same direction of flow as any positive charge it contains, or to flow from the most positive part of a circuit to the most negative part. Current defined in this manner is called
conventional current. The motion of negatively charged electrons around an
electric circuit, one of the most familiar forms of current, is thus deemed positive in the
opposite direction to that of the electrons. However, depending on the conditions, an electric current can consist of a flow of
charged particles in either direction or even in both directions at once. The positive-to-negative convention is widely used to simplify this situation. provides an energetic demonstration of electric current. The process by which electric current passes through a material is termed
electrical conduction, and its nature varies with that of the charged particles and the material through which they are travelling. Examples of electric currents include metallic conduction, where electrons flow through a
conductor such as metal, and
electrolysis, where
ions (charged
atoms) flow through liquids, or through
plasmas such as electrical sparks. While the particles themselves can move quite slowly, sometimes with an average
drift velocity only fractions of a millimetre per second, Current causes several observable effects, which historically were the means of recognising its presence. That water could be decomposed by the current from a voltaic pile was discovered by
Nicholson and
Carlisle in 1800, a process now known as
electrolysis. Their work was greatly expanded upon by
Michael Faraday in 1833. Current through a
resistance causes localised heating, an effect
James Prescott Joule studied mathematically in 1840. He had discovered
electromagnetism, a fundamental interaction between electricity and magnetics. The level of electromagnetic emissions generated by
electric arcing is high enough to produce
electromagnetic interference, which can be detrimental to the workings of adjacent equipment. In engineering or household applications, current is often described as being either
direct current (DC) or
alternating current (AC). These terms refer to how the current varies in time. Direct current, as produced by example from a
battery and required by most
electronic devices, is a unidirectional flow from the positive part of a circuit to the negative. If, as is most common, this flow is carried by electrons, they will be travelling in the opposite direction. Alternating current is any current that reverses direction repeatedly; almost always this takes the form of a
sine wave. The most visible natural occurrence of this is
lightning, caused when charge becomes separated in the clouds by rising columns of air, and raises the electric field in the air to greater than it can withstand. The voltage of a large lightning cloud may be as high as 100 MV and have discharge energies as great as 250 kWh.
Electric potential s. The + sign indicates the polarity of the potential difference between the battery terminals. The concept of electric potential is closely linked to that of the electric field. A small charge placed within an electric field experiences a force, and to have brought that charge to that point against the force requires
work. The electric potential at any point is defined as the energy required to bring a unit test charge from an infinite distance slowly to that point. It is usually measured in
volts, and one volt is the potential for which one
joule of work must be expended to bring a charge of one
coulomb from infinity. Electric potential is a
scalar quantity. That is, it has only magnitude and not direction. It may be viewed as analogous to
height: just as a released object will fall through a difference in heights caused by a gravitational field, so a charge will 'fall' across the voltage caused by an electric field. As relief maps show
contour lines marking points of equal height, a set of lines marking points of equal potential (known as
equipotentials) may be drawn around an electrostatically charged object. The equipotentials cross all lines of force at right angles. They must also lie parallel to a
conductor's surface, since otherwise there would be a force along the surface of the conductor that would move the charge carriers to even the potential across the surface. The electric field was formally defined as the force exerted per unit charge, but the concept of potential allows for a more useful and equivalent definition: the electric field is the local
gradient of the electric potential. Usually expressed in volts per metre, the vector direction of the field is the line of greatest slope of potential, and where the equipotentials lie closest together. Ørsted did not fully understand his discovery, but he observed the effect was reciprocal: a current exerts a force on a magnet, and a magnetic field exerts a force on a current. The phenomenon was further investigated by
Ampère, who discovered that two parallel current-carrying wires exerted a force upon each other: two wires conducting currents in the same direction are attracted to each other, while wires containing currents in opposite directions are forced apart. Experimentation by Faraday in 1831 revealed that a wire moving perpendicular to a magnetic field developed a potential difference between its ends. Further analysis of this process, known as
electromagnetic induction, enabled him to state the principle, now known as
Faraday's law of induction, that the potential difference induced in a closed circuit is proportional to the rate of change of
magnetic flux through the loop. Exploitation of this discovery enabled him to invent the first
electrical generator in 1831, in which he converted the mechanical energy of a rotating copper disc to electrical energy.
Electric circuits . The
voltage source V on the left drives a
current I around the circuit, delivering
electrical energy into the
resistor R. From the resistor, the current returns to the source, completing the circuit.|alt=refer to caption An electric circuit is an interconnection of electric components such that electric charge is made to flow along a closed path (a circuit), usually to perform some useful task. The components in an electric circuit can take many forms, which can include elements such as
resistors,
capacitors,
switches,
transformers and
electronics.
Electronic circuits contain
active components, usually
semiconductors, and typically exhibit
non-linear behaviour, requiring complex analysis. The simplest electric components are those that are termed
passive and
linear: while they may temporarily store energy, they contain no sources of it, and exhibit linear responses to stimuli. The
resistor is perhaps the simplest of passive circuit elements: as its name suggests, it
resists the current through it, dissipating its energy as heat. The resistance is a consequence of the motion of charge through a conductor: in metals, for example, resistance is primarily due to collisions between electrons and ions.
Ohm's law is a basic law of
circuit theory, stating that the current passing through a resistance is directly proportional to the potential difference across it. The resistance of most materials is relatively constant over a range of temperatures and currents; materials under these conditions are known as 'ohmic'. The
ohm, the unit of resistance, was named in honour of
Georg Ohm, and is symbolised by the Greek letter Ω. 1 Ω is the resistance that will produce a potential difference of one volt in response to a current of one amp.
Electronics electronic components Electronics deals with
electrical circuits that involve active electrical components such as
vacuum tubes,
transistors,
diodes,
sensors and
integrated circuits, and associated passive interconnection technologies. The
nonlinear behaviour of active components and their ability to control electron flows makes digital
switching possible, whereas the design and construction of
electronic circuits to solve practical problems are part of
electronics engineering. Electronic devices make use of the
transistor, perhaps one of the most important inventions of the twentieth century, and a fundamental building block of all modern circuitry. A modern
integrated circuit may contain many billions of miniaturised transistors in a region only a few centimetres square.
Electromagnetic wave Faraday's and Ampère's work showed that a time-varying magnetic field created an electric field, and a time-varying electric field created a magnetic field. Thus, when either field is changing in time, a field of the other is always induced. ==Production, storage and uses==