Electricity Course
One of my aims is to inform and educate. I believe that the more knowledge I have of the world around us, the better I will be at my job. You can only reach great heights if you build upon a broad base.
What is worrying me at the moment is that some people have rather strange ideas about electricity.
There are some who think that, if you remove a light globe from its socket, then electricity will leak out. They have supposedly proved this hypothesis by sticking a finger in the socket. The ones who survived now believe that there is, indeed, electricity in there and that it is leaking out.
These people also believe that switches work by applying pressure to the wires so that the current cannot get through and that dimmer switches have a screw action that varies the pressure gradually.
In order to correct these and other misconceptions about electricity I have developed a short course. Completing this will allow you to understand the subject in such a way as to talk knowledgeably as well as use the stuff safely. The theories might not always be completely correct but if you really want to understand the subject you need to do a university degree like what I done.
Electricity was discovered when the ancient Greeks rubbed their cats with amber rods. The Greeks called this 'Static Electricity' even though the cat was more often seen running out of the house hotly pursued by an ancient experimenter. Maybe the name was some form of wishful thinking on the part of the Greeks. Whatever, the sparks that emanated from the hurtling cat were man's first feeble attempt at creating electricity.
Having created static electricity, the Greeks did not know what to do with highly charged cats so they spent their time inventing democracy and building ruins in Athens
Many years later an Italian discovered that frogs legs could be made to leap all round the room by prodding them with metal electrodes. This discovery led to the creation of the battery.
A battery consisted of a number of metal plates with pads of paper soaked in a salt solution. How the connection between frogs legs and metal plates was made is a well kept Latin secret. Why the French now like to eat frogs legs is an even bigger mystery.
Having heard about the invention of the battery, which is a source of moving electricity, the sort that can travel through wires, Faraday, an Englishman, went one better and invented the generator. He did this by first inventing the electric motor. He then connected it in reverse so that when the rotor was turned in a brisk and energetic manner, electricity came flooding out of the wires. (If you thought that the English have unusual thought processes this should re-enforce that belief.)
Faraday knew that electricity was coming out of the generator because there was a reading on a couple of meters he had put into the electric circuit. The meters that he used were a volt meter and an amp meter. By a strange coincidence, the volt meter was named after Volta (an Italian) and the amp meter after Ampere (a Frenchman)
The European nature of electricity does not end there. The ratio of volts to amps is known as resistance, which is measured in ohms (after a German) and is represented by omega, a greek letter. This takes us full circle back to where it all started, Greece
Anyway, enough of the history of electricity. What about some of the interesting properties of this amazing phenomenon. The most common thing that electricity moves in is wire. For normal, low power electricity there are two wires, one red, one black. However, for really powerful electricity there is a third wire, a green one, that carries a special booster so that extra large appliances can be connected. In most houses there is a box containing thin wire that is not strong enough for all occasions. This thin wire is known as fuse wire, because it has a habit of melting, often causing inconvenience late at night and in the cold. When I first discovered this, I replaced the fuse by a short length of fencing wire, after which it did not cause any trouble at all, even when the washing machine went up in smoke after the motor seized and burst into flames.
When television was first invented, the only electricity fast enough to do the job was the black and white variety. It took a number of years before fast, coloured electricity was developed. Engineers always knew that coloured TV was achievable because, on their way to work every day, they went past traffic lights that changed colour. The traffic lights changed colour only very slowly but at least it was possible and was a constant taunt to TV engineers. The breakthrough came when they realised that traffic lights used coloured light whereas what they needed was coloured electricity. Once this had occurred to them it was a relatively easy task to develop different coloured wires in which the new forms of electricity could run. If you do not believe this, open up the back of your TV and you will find lots of different coloured wires.
Batteries are very interesting. They have 'direct' electricity instead of the 'alternating' electricity that comes into your house through the mains wires and which then comes out through various sockets in the wall. The reason that it is called direct is that when you buy batteries you put them directly into the radio or tape recorder or other device. When they run down they go directly into the garbage. The mains electricity is called alternating because you can plug your appliance into a socket in the kitchen or alternatively in the lounge, or alternatively in the bathroom. Simple isn't it?
Electricity can be converted into light by making a small gap in the wire so that the electricity jumps across the gap. This is seen as a spark because the electricity heats the air up as it crosses the gap. A light bulb is simply a small gap surrounded by a large magnifying lens. This theory is in direct contradiction to the dark sucker theory referred to in an earlier report. However science has never been harmed by having alternative theories to explain natural phenomena. You just choose the one that appeals to you more and the world carries on regardless.
To some people, electric watches have always been a mystery. Even when they manage to open one they cannot figure out how it works. The explanation is quite simple.
Research is being conducted into the mysteries of other electrical phenomena such as why water and electricity do not mix and the associated problem of how submarines can use electricity safely underwater. Then there is the problem of remote controls. Why do you need one for the television and one for the video and how is it that the two devices do not get confused?
This current report might be the first in a series on the topic of electricity, if we can get some bright spark with the capacity to generate enough material to illuminate the subject. If we encounter resistance from the odd live wire we are positive that we could transform the topic and fuse it with soldering, unless the reaction was too negative. Alternatively, we could charge for the next one and connect up with others in the field thus producing them at a greater frequency. Now that would be a shock to the system, especially if it was out of phase and it Hertz.
There are a battery of reasons why this could be the only report, not the least of which is that finding any more puns has become too difficult.
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Here is some information on the book, Electrical History by Tom Henry. This book was written in appreciation of the more than 15 million men and women that work in the electrical industry to keep the lights burning every second, every minute, 24 hours a day, everyday.
Did Edison invent the light bulb, Marconi the radio, Bell the telephone, Morse the telegraph? The answers are no. They didn't invent the wheel. They were instrumental in making it better and, in some cases, obtaining the patent.
Electrical history goes back before Christ and brings us to the computer age. Along this journey you will discover it took several people, along the way, to make the light bulb glow.
The journey won't end with this book, as we are constantly discovering new inventions that will someday even take us to the stars.
Benjamin Franklin (1706-1790)
His kite experiment demonstrated that lightning is electricity. He was the first to use the terms positive and negative charge.
Franklin was one of seventeen children. He quit school at age ten to become a printer. His life is the classic story of a self-made man achieving wealth and fame through determination and intelligence.
James Watt (1736-1819) was born in Scotland. Although he conducted no electrical experiments, he must not be overlooked. He was an instrument maker by trade and set up a repair shop in Glasgow in 1757. Watt thought that the steam engine would replace animal power, where the number of horses replaced seemed an obvious way to measure the charge for performance. Interestingly, Watt measured the rate of work exerted by a horse drawing rubbish up an old mine shaft and found it amounted to about 22,000 ft-lbs per minute. He added a margin of 50% arriving at 33,000 ft-lbs.
William Thomson, Lord Kelvin (1824-1907) was best known in his invention of a new temperature scale based on the concept of an absolute zero of temperature at -273°C (-460°F). To the end of his life, Thomson maintained fierce opposition to the idea that energy emitted by radioactivity came from within the atom. One of the greatest scientific discoveries of the 19th century, Thomson died opposing one of the most vital innovations in the history of science.
Thomas Seebeck (1770-1831) a German physicist was the discoverer of the "Seebeck effect".
He twisted two wires made of different metals and heated a junction where the two wires met. He produced a small current. The current is the result of a flow of heat from the hot to the cold junction. This is called thermoelectricity. Thermo is a Greek word meaning heat.
Michael Faraday (1791-1867) an Englishman, made one of the most significant discoveries in the history of electricity: Electromagnetic induction. His pioneering work dealt with how electric currents work. Many inventions would come from his experiments, but they would come fifty to one hundred years later.
Failures never discouraged Faraday. He would say; "the failures are just as important as the successes." He felt failures also teach. The farad, the unit of capacitance is named in the honor of Michael Faraday.
James Maxwell (1831-1879) a Scottish mathematician translated Faraday's theories into mathematical expressions. Maxwell was one of the finest mathematicians in history. A maxwell is the electromagnetic unit of magnetic flux, named in his honor.
Today he is widely regarded as secondary only to Isaac Newton and Albert Einstein in the world of science.
Thomas Alva Edison (1847-1931) was one of the most well known inventors of all time with 1093 patents. Self-educated, Edison was interested in chemistry and electronics.During the whole of his life, Edison received only three months of formal schooling, and was dismissed from school as being retarded, though in fact a childhood attack of scarlet fever had left him partially deaf.
Nikola Tesla was born of Serbian parents July 10, 1856 and died a broke and lonely man in New York City January 7, 1943. He envisioned a world without poles and power lines. Referred to as the greatest inventive genius of all time. Tesla's system triumphed to make possible the first large-scale harnessing of Niagara Falls with the first hydroelectric plant in the United States in 1886.
October 1893 George Westinghouse (1846-1914)was awarded the contract to build the first generators at Niagara Falls. He used his money to buy up patents in the electric field. One of the inventions he bought was the transformer from William Stanley. Westinghouse invented the air brake system to stop trains, the first of more than one hundred patents he would receive in this area alone. He soon founded the Westinghouse Air Brake Company in 1869.
Alexander Graham Bell (1847-1922) born in Scotland, was raised in a family that was interested and involved in the science of sound. Bell's father and grandfather both taught speech to the deaf. A unit of sound level is called a bel in his honor. Sound levels are measured in tenths of a bel, or decibels. The abbreviation for decibel is dB.
Heinrich Hertz (1857-1894) a German physicist, laid the ground work for the vacuum tube. He laid the foundation for the future development of radio, telephone, telegraph, and even television. He was one of the first people to demonstrate the existence of electric waves. Hertz was convinced that there were electromagnetic waves in space.
Otto Hahn (1879-1968), a German chemist and physicist, made the vital discovery which led to the first nuclear reactor. He uncovered the process of nuclear fission by which nuclei of atoms of heavy elements can break into smaller nuclei, in the process releasing large quantities of energy. Hahn was awarded the Nobel prize for chemistry in 1944.
Albert Einstein (1879-1955). Einstein's formula proved that one gram of mass can be converted into a torrential amount of energy. To do this, the activity of the atoms has to occur in the nucleus. E = energy, M = mass, and C = the speed of light which is 186,000 miles per second. When you square 186,000 you can see it would only take a small amount of mass to produce a huge amount of energy.
History
A Ridiculously Brief History of Electricity and Magnetism
Mostly from E. T. Whittaker's
A History of the Theories of Aether and Electricity...
900 BC - Magnus, a Greek shepherd, walks across a field of black stones which pull the iron nails out of his sandals and the iron tip from his shepherd's staff (authenticity not guaranteed). This region becomes known as Magnesia.
600 BC - Thales of Miletos rubs amber (elektron in Greek) with cat fur and picks up bits of feathers.
1269 - Petrus Peregrinus of Picardy, Italy, discovers that natural spherical magnets (lodestones) align needles with lines of longitude pointing between two pole positions on the stone.
1600 - William Gilbert, court physician to Queen Elizabeth, discovers that the earth is a giant magnet just like one of the stones of Peregrinus, explaining how compasses work. He also discusses static electricity and invents an electric fluid which is liberated by rubbing.
ca. 1620 - Niccolo Cabeo discovers that electricity can be repulsive as well as attractive.
1630 - Vincenzo Cascariolo, a Bolognese shoemaker, discovers fluorescence.
1638 - Rene Descartes theorizes that light is a pressure wave through the second of his three types of matter of which the universe is made. He invents properties of this fluid that make it possible to calculate the reflection and refraction of light. The ``modern'' notion of the aether is born.
1638 - Galileo attempts to measure the speed of light by a lantern relay between distant hilltops. He gets a very large answer.
1644 - Rene Descartes theorizes that the magnetic poles are on the central axis of a spinning vortex of one of his fluids. This vortex theory remains popular for a long time, enabling Leonhard Euler and two of the Bernoullis to share a prize of the French Academy as late as 1743.
1657 - Pierre de Fermat shows that the principle of least time is capable of explaining refraction and reflection of light. Fighting with the Cartesians begins. (This principle for reflected light had been anticipated anciently by Hero of Alexandria.)
1665 - Francesco Maria Grimaldi, in a posthumous report, discovers and gives the name of diffraction to the bending of light around opaque bodies.
1667 - Robert Hooke reports in his Micrographia the discovery of the rings of light formed by a layer of air between two glass plates. These were actually first observed by Robert Boyle, which explains why they are now called Newton's rings. In the same work he gives the matching-wave-front derivation of reflection and refraction that is still found in most introductory physics texts. These waves travel through the aether. He also develops a theory of color in which white light is a simple disturbance and colors are complex distortions of the basic simple white form.
1671 - Isaac Newton destroys Hooke's theory of color by experimenting with prisms to show that white light is a mixture of all the colors and that once a pure color is obtained it can never be changed into another color. Newton argues against light being a vibration of the ether, preferring that it be something else that is capable of traveling through the aether. He doesn't insist that this something else consist of particles, but allows that it may be some other kind of emanation or impulse. In Newton's own words, ``...let every man here take his fancy.''
1675 - Olaf Roemer repeats Galileo's experiment using the moons of Jupiter as the distant hilltop. He measures 
m/s.
m/s.
1678 - Christiaan Huygens introduces his famous construction and principle, thinks about translating his manuscript into Latin, then publishes it in the original French in 1690. He uses his theory to discuss the double refraction of Iceland Spar. His is a theory of pulses, however, not of periodic waves.
1717 - Newton shows that the ``two-ness'' of double refraction clearly rules out light being aether waves. (All aether wave theories were sound-like, so Newton was right; longitudinal waves can't be polarized.)
1728 - James Bradley shows that the orbital motion of the earth changes the apparent motions of the stars in a way that is consistent with light having a finite speed of travel.
1729 - Stephen Gray shows that electricity doesn't have to be made in place by rubbing but can also be transferred from place to place with conducting wires. He also shows that the charge on electrified objects resides on their surfaces.
1733 - Charles Francois du Fay discovers that electricity comes in two kinds which he called resinous(-) and vitreous(+).
1742 - Thomas Le Seur and Francis Jacquier, in a note to the edition of Newton's Principia that they publish, show that the force law between two magnets is inverse cube.
1749 - Abbe
Jean-Antoine Nollet invents the two-fluid theory electricity.
Jean-Antoine Nollet invents the two-fluid theory electricity.
1745 - Pieter van Musschenbroek invents the Leyden jar, or capacitor, and nearly kills his friend Cunaeus.
1747 - Benjamin Franklin invents the theory of one-fluid electricity in which one of Nollet's fluids exists and the other is just the absence of the first. He proposes the principle of conservation of charge and calls the fluid that exists and flows ``positive''. This educated guess ensures that undergraduates will always be confused about the direction of current flow. He also discovers that electricity can act at a distance in situations where fluid flow makes no sense.
1748 - Sir William Watson uses an electrostatic machine and a vacuum pump to make the first glow discharge. His glass vessel is three feet long and three inches in diameter: the first fluorescent light bulb.
1750 - John Michell discovers that the two poles of a magnet are equal in strength and that the force law for individual poles is inverse square.
1752 - Johann Sulzer puts lead and silver together in his mouth, performing the first recorded ``tongue test'' of a battery.
1759 - Francis Ulrich Theodore Aepinus shows that electrical effects are a combination of fluid flow confined to matter and action at a distance. He also discovers charging by induction.
1762 - Canton reports that a red hot poker placed close to a small electrified body destroys its electrification.
1764 - Joseph Louis Lagrange discovers the divergence theorem in connection with the study of gravitation. It later becomes known as Gauss's law. (See 1813).
1766 - Joseph Priestly, acting on a suggestion in a letter from Benjamin Franklin, shows that hollow charged vessels contain no charge on the inside and based on his knowledge that hollow shells of mass have no gravity inside correctly deduces that the electric force law is inverse square.
ca 1775 - Henry Cavendish invents the idea of capacitance and resistance (the latter without any way of measuring current other than the level of personal discomfort). But being indifferent to fame he is content to wait for his work to be published by Lord Kelvin in 1879.
1777 - Joseph Louis Lagrange invents the concept of the scalar potential for gravitational fields.
1780 - Luigi Galvani causes dead frog legs to twitch with static electricity, then also discovers that the same twitching can be caused by contact with dissimilar metals. His followers invent another invisible fluid, that of ``animal electricity'', to describe this effect.
1782 - Pierre Simon Laplace shows that Lagrange's potential satisfies 
.
.
1785 - Charles Augustin Coulomb uses a torsion balance to verify that the electric force law is inverse square. He also proposes a combined fluid/action-at-a-distance theory like that of Aepinus but with two conducting fluids instead of one. Fighting breaks out between single and double fluid partisans. He also discovers that the electric force near a conductor is proportional to its surface charge density and makes contributions to the two-fluid theory of magnetism.
1793 - Alessandro Volta makes the first batteries and argues that animal electricity is just ordinary electricity flowing through the frog legs under the impetus of the force produced by the contact of dissimilar metals. He discovers the importance of ``completing the circuit.'' In 1800 he discovers the Voltaic pile (dissimilar metals separated by wet cardboard) which greatly increases the magnitude of the effect.
1800 - William Nicholson and Anthony Carlisle discover that water may be separated into hydrogen and oxygen by the action of Volta's pile.
1801 - Thomas Young gives a theory of Newton's rings based on constructive and destructive interference of waves. He explains the dark spot in the middle by proposing that there is a phase shift on reflection between a less dense and more dense medium, then uses essence of sassafras (whose index of refraction is intermediate between those of crown and flint glass) to get a light spot at the center.
1803 - Thomas Young explains the fringes at the edges of shadows by means of the wave theory of light. The wave theory begins its ascendance, but has one important difficulty: light is thought of as a longitudinal wave, which makes it difficult to explain double refraction effects in certain crystals.
1807 - Humphrey Davy shows that the essential element of Volta's pile is chemical action since pure water gives no effect. He argues that chemical effects are electrical in nature.
1808 - Laplace gives an explanation of double refraction using the particle theory, which Young attacks as improbable.
1808 - Etienne Louis Malus, a military engineer, enters a prize competition sponsored by the French Academy ``To furnish a mathematical theory of double refraction, and to confirm it by experiment.'' He discovers that light reflected at certain angles from transparent substances as well as the separate rays from a double-refracting crystal have the same property of polarization. In 1810 he receives the prize and emboldens the proponents of the particle theory of light because no one sees how a wave theory can make waves of different polarizations.
1811 - Arago shows that some crystals alter the polarization of light passing through them.
1812 - Biot shows that Arago's crystals rotate the plane of polarization about the propagation direction.
1812 - Simeon Denis Poisson further develops the two-fluid theory of electricity, showing that the charge on conductors must reside on their surfaces and be so distributed that the electric force within the conductor vanishes. This surface charge density calculation is carried out in detail for ellipsoids. He also shows that the potential within a distribution of electricity satisfies the equation 
1812 - Michael Faraday, a bookbinders apprentice, writes to Sir Humphrey Davy asking for a job as a scientific assistant. Davy interviews Faraday and finds that he has educated himself by reading the books he was supposed to be binding. He gets the job.
ca. 1813 - Laplace shows that at the surface of a conductor the electric force is perpendicular to the surface and that 
.
.
1813 - Karl Friedrich Gauss rediscovers the divergence theorem of Lagrange. It will later become known as Gauss's law.
1815 - David Brewster establishes his law of complete polarization upon reflection at a special angle now known as Brewster's angle. He also discovers that in addition of uniaxial cystals there are also biaxial ones. For uniaxial crystals there is the faint possibility of a wave theory of longitudinal-type, but this appears to be impossible for biaxial ones.
1816 - David Brewster invents the kaleidoscope.
1816 - Francois Arago, an associate of Augustin Fresnel, visits Thomas Young and describes to him a series of experiments performed by Fresnel and himself which shows that light of differing polarizations cannot interfere. Reflecting later on this curious effect Young sees that it can be explained if light is transverse instead of longitudinal. This idea is communicated to Fresnel in 1818 and he immediately sees how it clears up many of the remaining difficulties of the wave theory. Six years later the particle theory is dead.
1817 - Augustin Fresnel annoys the French Academy. The Academy, hoping to destroy the wave theory once and for all, proposes diffraction as the prize subject for 1818. To the chagrin of the particle-theory partisans in the Academy the winning memoir in 1818 is that of Augustin Fresnel who explains diffraction as the mutual interference of the secondary waves emitted by the unblocked portions of the incident wave, in the style of Huygens. One of the judges from the particle camp of the Academy is Poisson, who points out that if Fresnel's theory were to be indeed correct, then there should be a bright spot at the center of the shadow of a circular disc. This, he suggests to Fresnel, must be tested experimentally. The experiment doesn't go as Poisson hopes, however, and the spot becomes known as ``Poisson's spot.''
1820 - Hans Christian Oersted discovers that electric current in a wire causes a compass needle to orient itself perpendicular to the wire.
1820 - Andre Marie Ampere, one week after hearing of Oersted's discovery, shows that parallel currents attract each other and that opposite currents attract.
1820 - Jean-Baptiste Biot and Felix Savart show that the magnetic force exerted on a magnetic pole by a wire falls off like 1/r and is oriented perpendicular to the wire. Whittaker then says that ``This result was soon further analyzed,'' to obtain
1820 - John Herschel shows that quartz samples that rotate the plane of polarization of light in opposite directions have different crystalline forms. This difference is helical in nature.
1821 - Faraday begins electrical work by repeating Oersted's experiments.
1821 - Humphrey Davy shows that direct current is carried throughout the volume of a conductor and establishes that
for long wires. He also discovers that resistance is increased as the temperature rises.
for long wires. He also discovers that resistance is increased as the temperature rises.
1822 - Thomas Johann Seebeck discovers the thermoelectric effect by showing that a current will flow in a circuit made of dissimilar metals if there is a temperature difference between the metals.
1824 - Poisson invents the concept of the magnetic scalar potential and of surface and volume pole densities described by the formulas
He also finds the magnetic field inside a spherical cavity within magnetized material.
He also finds the magnetic field inside a spherical cavity within magnetized material.
1825 - Ampere publishes his collected results on magnetism. His expression for the magnetic field produced by a small segment of current is different from that which follows naturally from the Biot-Savart law by an additive term which integrates to zero around closed circuit. It is unfortunate that electrodynamics and relativity decide in favor of Biot and Savart rather than for the much more sophisticated Ampere, whose memoir contains both mathematical analysis and experimentation, artfully blended together. In this memoir are given some special instances of the result we now call Stokes theorem or as we usually write it 
. Maxwell describes this work as ``one of the most brilliant achievements in science. The whole, theory and experiment, seems as if it had leaped, full-grown and full-armed, from the brain of the `Newton of electricity'. It is perfect in form and unassailable in accuracy; and it is summed up in a formula from which all the phenomena may be deduced, and which must always remain the cardinal formula of electrodynamics.''
. Maxwell describes this work as ``one of the most brilliant achievements in science. The whole, theory and experiment, seems as if it had leaped, full-grown and full-armed, from the brain of the `Newton of electricity'. It is perfect in form and unassailable in accuracy; and it is summed up in a formula from which all the phenomena may be deduced, and which must always remain the cardinal formula of electrodynamics.''
1825 - Fresnel shows that combinations of waves of opposite circular polarization traveling at different speeds can account for the rotation of the plane of polarization.
1826 - Georg Simon Ohm establishes the result now known as Ohm's law. V=IR seems a pretty simple law to name after someone, but the importance of Ohm's work does not lie in this simple proportionality. What Ohm did was develop the idea of voltage as the driver of electric current. He reasoned by making an analogy between Fourier's theory of heat flow and electricity. In his scheme temperature and voltage correspond as do heat flow and electrical current. It was not until some years later that Ohm's electroscopic force (V in his law) and Poisson's electrostatic potential were shown to be identical.
1827 - Augustin Fresnel publishes a decade of research in the wave theory of light. Included in these collected papers are explanations of diffraction effects, polarization effects, double refraction, and Fresnel's sine and tangent laws for reflection at the interface between two transparent media.
1827 - Claude Louis Marie Henri Navier publishes the correct equations for vibratory motions in one type of elastic solid. This begins the quest for a detailed mathematical theory of the aether based on the equations of continuum mechanics.
1827 - F. Savery, after noticing that the current from a Leyden jar magnetizes needles in alternating layers, conjectures that the electric motion during the discharge consists of a series of oscillations.
1828 - George Green generalizes and extends the work of Lagrange, Laplace, and Poisson and attaches the name potential to their scalar function. Green's theorems are given, as well as the divergence theorem (Gauss's law), but Green doesn't know of the work of Lagrange and Gauss and only references Priestly's deduction of the inverse square law from Franklin's experimental work on the charging of hollow vessels.
1828 - Augustine Louis Cauchy presents a theory similar to Navier's, but based on a direct study of elastic properties rather than using a molecular hypothesis. These equations are more general than Navier's. In Cauchy's theory, and in much of what follows, the aether is supposed to have the same inertia in each medium, but different elastic properties.
1828 - Poisson shows that the equations of Navier and Cauchy have wave solutions of two types: transverse and longitudinal. Mathematical physicists spend the next 50 years trying to invent an elastic aether for which the longitudinal waves are absent.
1831 - Faraday shows that changing currents in one circuit induce currents in a neighboring circuit. Over the next several years he performs hundreds of experments and shows that they can all be explained by the idea of changing magnetic flux. No mathematics is involved, just picture thinking using his field-lines.
1831 - Ostrogradsky rediscovers the divergence theorem of Lagrange, Gauss, and Green.
1832 - Joseph Henry independently discovers induced currents.
1833 - Faraday begins work on the relation of electricity to chemistry. In one of his notebooks he concludes after a series of experiments, ``...there is a certain absolute quantity of the electric power associated with each atom of matter.''
1834 - Faraday discovers self inductance.
1834 - Jean Charles Peltier discovers the flip side of Seebeck's thermoelectric effect. He finds that current driven in a circuit made of dissimilar metals causes the different metals to be at different temperatures.
1834 - Emil Lenz formulates his rule for determining the direction of Faraday's induced currents. In its original form it was a force law rather than an induced emf law: ``Induced currents flow in such a direction as to produce magnetic forces that try to keep the magnetic flux the same.'' So Lenz would predict that if you try to push a conductor into a strong magnetic field, it will be repelled. He would also predict that if you try to pull a conductor out of a strong magnetic field that the magnetic forces on the induced currents will oppose the pull.
1835 - James MacCullagh and Franz Neumann extend Cauchy's theory to crystalline media
1837 - Faraday discovers the idea of the dielectric constant.
1837 - George Green attacks the elastic aether problem from a new angle. Instead of deriving boundary conditions between different media by finding which ones give agreement with the experimental laws of optics, he derives the correct boundary conditions from general dynamical principles. This advance makes the elastic theories not quite fit with light.
1838 - Faraday shows that the effects of induced electricity in insulators are analogous to induced magnetism in magnetic materials. Those more mathematically inclined immediately appropriate Poisson's theory of induced magnetism, inventing 
, 
, and 
.
, , and .
1838 - Faraday discovers Faraday's dark space, a dark region in a glow discharge near the negative electrode.
1839 - James MacCullagh invents an elastic aether in which there are no longitudinal waves. In this aether the potential energy of deformation depends only on the rotation of the volume elements and not on their compression or general distortion. This theory gives the same wave equation as that satisfied by 
and 
in Maxwell's theory.
and in Maxwell's theory.
1839 - William Thomson (Lord Kelvin) removes some of the objections to MacCullagh's rotation theory by inventing a mechanical model which satisfies MacCullagh's energy of rotation hypothesis. It has spheres, rigid bars, sliding contacts, and flywheels.
1839 - Cauchy and Green present more refined elastic aether theories, Cauchy's removing the longitudinal waves by postulating a negative compressibility, and Green's using an involved description of crystalline solids.
1841 - Michael Faraday is completely exhausted by his efforts of the previous 2 decades, so he rests for 4 years.
1841 - James Prescott Joule shows that energy is conserved in electrical circuits involving current flow, thermal heating, and chemical transformations.
1842 - F. Neumann and Matthew O'Brien suggest that optical properties in materials arise from differences in the amount of force that the particles of matter exert on the aether as it flows around and between them.
1842 - Julius Robert Mayer asserts that heat and work are equivalent. His paper is rejected by Annalen der Physik.
1842 - Joseph Henry rediscovers the result of F. Savery about the oscillation of the electric current in a capacitive discharge and states, ``The phenomena require us to admit the existence of a principal discharge in one direction, and then several reflex actions backward and forward, each more feeble than the preceding, until equilibrium is restored.''
1842 - Christian Doppler gives the theory of the Doppler effect.
1845 - Faraday quits resting and discovers that the plane of polarization of light is rotated when it travels in glass along the direction of the magnetic lines of force produced by an electromagnet (Faraday rotation).
1845 - Franz Neumann uses (i) Lenz's law, (ii) the assumption that the induced emf is proportional to the magnetic force on a current element, and (iii) Ampere's analysis to deduce Faraday's law. In the process he finds a potential function from which the induced electric field can be obtained, namely the vector potential 
(in the Coulomb gauge), thus discovering the result which Maxwell wrote as 
.
(in the Coulomb gauge), thus discovering the result which Maxwell wrote as .
1846 - George Airy modifies MacCullagh's elastic aether theory to account for Faraday rotation.
1846 - Faraday, inspired by his discovery of the magnetic rotation of light, writes a short paper speculating that light might electro-magnetic in nature. He thinks it might be transverse vibrations of his beloved field lines.
1846 - Faraday discovers diamagnetism. He sees the effect in heavy glass, bismuth, and other materials.
1846 - Wilhelm Weber combines Ampere's analysis, Faraday's experiments, and the assumption of Fechner that currents consist of equal amounts of positive and negative electricity moving opposite to each other at the same speed to derive an electromagnetic theory based on forces between moving charged particles. This theory has a velocity-dependent potential energy and is wrong, but it stimulates much work on electromagnetic theory which eventually leads to the work of Maxwell and Lorenz. It also inspires a new look at gravitation by William Thomson to see if a velocity-dependent correction to the gravitational energy could account for the precession of Mercury's perihelion.
1846 - William Thomson shows that Neumann's electromagnetic potential is in fact the vector potential from which may be obtained via 
.
is in fact the vector potential from which may be obtained via .
1847 - Weber proposes that diamagnetism is just Faraday's law acting on molecular circuits. In answering the objection that this would mean that everything should be diamagnetic he correctly guesses that diamagnetism is masked in paramagnetic and ferromagnetic materials because they have relatively strong permanent molecular currents. This work rids the world of magnetic fluids.
1847 - Hermann von Helmholtz writes a memoir ``On the Conservation of Force'' which emphatically states the principle of conservation of energy: ``Conservation of energy is a universal principle of nature. Kinetic and potential energy of dynamical systems may be converted into heat according to definite quantitative laws as taught by Rumford, Mayer, and Joule. Any of these forms of energy may be converted into chemical, electrostatic, voltaic, and magnetic forms.'' He reads it before the Physical Society of Berlin whose older members regard it as too speculative and reject it for publication in Annalen der Physik.
1848-9 - Gustav Kirchoff extends Ohm's work to conduction in three dimensions, gives his laws for circuit networks, and finally shows that Ohm's ``electroscopic force'' which drives current through resistors and the old electrostatic potential of Lagrange, Laplace, and Poisson are the same. He also shows that in steady state electrical currents distribute themselves so as to minimize the amount of Joule heating.
1849 - A. Fizeau repeats Galileo's hilltop experiment (9 km separation distance) with a rapidly rotating toothed wheel and measures 
m/s.
m/s.
1849 - George Gabriel Stokes studies diffraction around opaque bodies both theoretically and experimentally and shows that the vibration of aether particles are executed at right angles to the plane of polarization. Three years later he comes to the same conclusion by applying aether theory to light scattered from the sky. This result is, however, inconsistent with optics in crystals.
ca. 1850 - Stokes overcomes some of the difficulties with crystals by turning Cauchy's hypothesis around and letting the elastic properties of the aether be the same in all materials, but allowing the inertia to differ. This gives rise to the conceptual difficulty of having the inertia be different in different directions (in anisotropic crystals).
ca. 1850 - Jean Foucault improves on Fizeau's measurement and uses his apparatus to show that the speed of light is less in water than in air.
1850 - Stokes law is stated without proof by Lord Kelvin (William Thomson). Later Stokes assigns the proof of this theorem as part of the examination for the Smith's Prize. Presumably, he knows how to do the problem. Maxwell, who was a candidate for this prize, later remembers this problem, traces it back to Stokes and calls it Stokes theorem.
1850 - William Thomson (Lord Kelvin) invents the idea of magnetic permeability and susceptibility, along with the separate concepts of , 
, and 
.
, , and .
1851 - Thomson gives a general theory of thermoelectric phenomena, describing the effects seen by Seebeck and Peltier.
1853 - Thomson uses Poisson's magnetic theory to derive the correct formula for magnetic energy: 
. He also gives the formula 
and gives the world the powerful, but confusing, analysis where the forces on circuits are obtained by taking either the positive or negative gradient of the magnetic energy. Knowing which sign to use is, of course, the confusing part.
. He also gives the formula and gives the world the powerful, but confusing, analysis where the forces on circuits are obtained by taking either the positive or negative gradient of the magnetic energy. Knowing which sign to use is, of course, the confusing part.
1853 - Thomson gives the theory of the RLC circuit providing a mathematical description for the observations of Henry and Savery.
1854 - Faraday clears up the problem of disagreements in the measured speeds of signals along transmission lines by showing that it is crucial to include the effect of capacitance.
1854 - Thomson, in a letter to Stokes, gives the equation of telegraphy ignoring the inductance: 
, where R is the cable resistance and where C is the capacitance per unit length. Since this is the diffusion equation, the signal does not travel at a definite speed.
, where R is the cable resistance and where C is the capacitance per unit length. Since this is the diffusion equation, the signal does not travel at a definite speed.
1855 - Faraday retires, living quietly in a house provided by the Queen until his death in 1867.
1855 - James Clerk Maxwell writes a memoir in which he attempts to marry Faraday's intuitive field line ideas with Thomson's mathematical analogies. In this memoir the physical importance of the divergence and curl operators for electromagnetism first become evident. The equations 
, 
, and 
appear in this memoir.
, , and appear in this memoir.
1857 - Gustav Kirchoff derives the equation of telegraphy for an aerial coaxial cable where the inductance is important and derives the full telegraphy equation: : 
, where L and C are the inductance per unit length and the capacitance per unit length. He recognizes that when the resistance is small, this is the wave equation with propagation speed 
, which for a coaxial cable turns out to be very close to the speed of light. Kirchoff notices the coincidence, and is thus the first to discover that electromagnetic signals can travel at the speed of light.
, where L and C are the inductance per unit length and the capacitance per unit length. He recognizes that when the resistance is small, this is the wave equation with propagation speed , which for a coaxial cable turns out to be very close to the speed of light. Kirchoff notices the coincidence, and is thus the first to discover that electromagnetic signals can travel at the speed of light.
1861 - Bernhard Riemann develops a variant of Weber's electromagnetic theory which is also wrong.
1861 - Maxwell publishes a mechanical model of the electromagnetic field. Magnetic fields correspond to rotating vortices with idle wheels between them and electric fields correspond to elastic displacements, hence displacement currents. The equation for now becomes 
, where 
is the total current, conduction plus displacement, and is conserved: 
. This addition completes Maxwell's equations and it is now easy for him to derive the wave equation exactly as done in our textbooks on electromagnetism and to note that the speed of wave propagation was close to the measured speed of light. Maxwell writes, ``We can scarcely avoid the inference that light in the transverse undulations of the same medium which is the cause of electric and magnetic phenomena.'' Thomson, on the other hand, says of the displacement current, ``(it is a) curious and ingenious, but not wholly tenable hypothesis.''
now becomes , where is the total current, conduction plus displacement, and is conserved: . This addition completes Maxwell's equations and it is now easy for him to derive the wave equation exactly as done in our textbooks on electromagnetism and to note that the speed of wave propagation was close to the measured speed of light. Maxwell writes, ``We can scarcely avoid the inference that light in the transverse undulations of the same medium which is the cause of electric and magnetic phenomena.'' Thomson, on the other hand, says of the displacement current, ``(it is a) curious and ingenious, but not wholly tenable hypothesis.''
1864 - Maxwell reads a memoir before the Royal Society in which the mechanical model is stripped away and just the equations remain. He also discusses the vector and scalar potentials, using the Coulomb gauge. He attributes physical significance to both of these potentials. He wants to present the predictions of his theory on the subjects of reflection and refraction, but the requirements of his mechanical model keep him from finding the correct boundary conditions, so he never does this calculation.
1867 - Stokes performs experiments that kill his own anisotropic inertia theory.
1867 - Joseph Boussinesq suggests that instead of aether being different in different media, perhaps the aether is the same everywhere, but it interacts differently with different materials, similar to the modern electromagnetic wave theory.
1867 - Riemann proposes a simple electric theory of light in which Poisson's equation is replaced by 
.
.
1867 - Ludwig Lorenz develops an electromagnetic theory of light in which the scalar and vector potentials, in retarded form, are the starting point. He shows that these retarded potentials each satisfy the wave equation and that Maxwell's equations for the fields and can be derived from his potentials. His vector potential does not obey the Coulomb gauge, however, but another relation now known as the Lorenz gauge. Although he is able to derive Maxwell's equations from his retarded potentials, he does not subscribe to Maxwell's view that light involves electromagnetic waves in the aether. He feels, rather, that the fundamental basis of all luminous vibrations is electric currents, arguing that space has enough matter in it to support the necessary currents.
and can be derived from his potentials. His vector potential does not obey the Coulomb gauge, however, but another relation now known as the Lorenz gauge. Although he is able to derive Maxwell's equations from his retarded potentials, he does not subscribe to Maxwell's view that light involves electromagnetic waves in the aether. He feels, rather, that the fundamental basis of all luminous vibrations is electric currents, arguing that space has enough matter in it to support the necessary currents.
1868 - Maxwell decides that giving physical significance to the scalar and vector potentials is a bad idea and bases his further work on light on and .
and .
1869 - Maxwell presents the first calculation in which a dispersive medium is made up of atoms with natural frequencies. This makes possible detailed modeling of dispersion with refractive indices having resonant denominators.
1869 - Hittorf finds that cathode rays can cast a shadow.
1870 - Helmholtz derives the correct laws of reflection and refraction from Maxwell's equations by using the following boundary conditions: 
, 
, and are continuous. Once these boundary conditions are taken Maxwell's theory is just a repeat of MacCullagh's theory. The details were not given by Helmholtz himself, but appear rather in the inaugural dissertation of H. A. Lorentz.
, , and are continuous. Once these boundary conditions are taken Maxwell's theory is just a repeat of MacCullagh's theory. The details were not given by Helmholtz himself, but appear rather in the inaugural dissertation of H. A. Lorentz.
1870-1900 - The hunt is on for physical models of the aether which are natural and from which Maxwell's equations can be derived. The physicists who work on this problem include Maxwell, Thomson, Kirchoff, Bjerknes, Leahy, Fitz Gerald, Helmholtz, and Hicks.
1872 - E. Mascart looks for the motion of the earth through the aether by measuring the rotation of the plane of polarization of light propagated along the axis of a quartz crystal. No motion is found with a sensitivity of 
.
.
1873 - Maxwell publishes his Treatise on Electricity and Magnetism, which discusses everything known at the time about electromagnetism from the viewpoint of Faraday. His own theory is not very thoroughly discussed, but he does introduce his electromagnetic stress tensor in this work, including the accompanying idea of electromagnetic momentum.
1875 - John Kerr shows that ordinary dielectrics subjected to strong electric fields become double refracting, showing directly that electric fields and light are closely related.
1876 - Henry Rowland performs an experiment inspired by Helmholtz which shows for the first time that moving electric charge is the same thing as an electric current.
1876 - A. Bartoli infers the necessity of light pressure from thermal arguments, thus beginnning the exploration of the connection between electromagnetism and thermodynamics.
1879 - J. Stefan discovers the Stefan-Boltzmann law, i.e., that radiant emission is proportional to 
.
.
1879 - Edwin Hall performs an experiment that had been suggested by Henry Rowland and discovers the Hall effect, including its theoretical description by means of the Hall term in Ohm's law.
1879 - Sir William Crookes invents the radiometer and studies the interaction of beams of cathode ray particles in vacuum tubes.
1879 - Ludwig Boltzmann uses Hall's result to estimate the speed of charge carriers (assuming that charge carriers are only of one sign.)
1880 - Rowland shows that Faraday rotation can be obtained by combining Maxwell's equations and the Hall term in Ohm's law, assuming that displacement currents are affected in the same way as conduction currents.
1881 - J. J. Thomson attempts to verify the existence of the displacement current by looking for magnetic effects produced by the changing electric field made by a moving charged sphere.
1881 - George Fitz Gerald points out that J. J. Thomson's analysis is incorrect because he left out the effects of the conduction current of the moving sphere. Including both currents makes the separate effect of the displacement current disappear.
1881 - Helmholtz, in a lecture in London, points out that the idea of charged particles in atoms can be consistent with Maxwell's and Faraday's ideas, helping to pave the way for our modern picture of particles and fields interacting instead of thinking about everything as a disturbance of the aether, as was popular after Maxwell.
1881 - Albert Michelson and Edwin Morley attempt to measure the motion of the earth through the aether by using interferometry. They find no relative velocity. Michelson interprets this result as supporting Stokes hypothesis in which the aether in the neighborhood of the earth moves at the earth's velocity.
1883 - Fitz Gerald proposes testing Maxwell's theory by using oscillating currents in what we would now call a magnetic dipole antenna (loop of wire). He performs the analysis and discovers that very high frequencies are required to make the test. Later that year he proposes obtaining the required high frequencies by discharging a capacitor into a circuit.
1883-5 - Horace Lamb and Oliver Heaviside analyze the interaction of oscillating electromagnetic fields with conductors and discover the effect of skin depth.
1884 - John Poynting shows that Maxwell's equations predict that energy flows through empty space with the energy flux given by 
. He also investigates energy flow in Faraday fashion by assigning energy to moving tubes of electric and magnetic flux.
. He also investigates energy flow in Faraday fashion by assigning energy to moving tubes of electric and magnetic flux.
1884 - Heinrich Hertz asserts that made by charges and made by a changing magnetic field are identical. Working from dynamical ideas based on this assumption and some of Maxwell's equations, Hertz is able to derive the rest of them.
made by charges and made by a changing magnetic field are identical. Working from dynamical ideas based on this assumption and some of Maxwell's equations, Hertz is able to derive the rest of them.
1887 - Svante Arrhenius deduces that in dilute solutions electrolytes are completely dissociated into positive and negative ions.
1887 - Hertz finds that ultraviolet light falling on the negative electrode in a spark gap facilitates conduction by the gas in the gap.
1888 - R. T. Glazebrook revives one of Cauchy's wave theories and combines it with Stokes anisotropic aether inertia theory to get agreement with the experiments of Stokes in 1867.
1888 - Hertz discovers that oscillating sparks can be produced in an open secondary circuit if the frequency of the primary is resonant with the secondary. He uses this radiator to show that electrical signals are propagated along wires and through the air at about the same speed, both about the speed of light. He also shows that his electric radiations, when passed through a slit in a screen, exhibit diffraction effects. Polarization effects using a grating of parallel metal wires are also observed.
1888 - Roentgen shows that when an uncharged dielectric is moved at right angles to a magnetic field is produced.
a magnetic field is produced.
1889 - Hertz gives the theory of radiation from his oscillating spark gap.
1889 - Oliver Heaviside finds the correct form for the electric and magnetic fields of a moving charged particle, valid for all speeds v < c.
1889 - J. J. Thomson shows that Canton's effect (1762) in which a red hot poker can neutralize the electrification of a small charged body is due to electron emission causing the air between the poker and the body to become conducting.
1890 - Fitz Gerald uses the retarded potentials of L. Lorenz to calculate electric dipole radiation from Hertz's radiator.
1892 - Oliver Lodge performs experiments on the propagation of light near rapidly moving steel disks to test Stokes hypothesis that moving matter drags the aether with it. No such effect is observed.
1892 - Hendrik Anton Lorentz presents his electron theory of electrified matter and the aether. This theory combines Maxwell's equations, with the source terms 
and 
, with the Lorentz force law for the acceleration of charged particles:
Lorentz's aether is simply space endowed with certain dynamical properties. Lorentz gives the modern theory of dielectrics involving and , and also includes the effect of magnetized matter. He also gives what we now call the Drude-Lorentz harmonic oscillator model of the index of refraction. But Lorentz's theory has a ``stationary aether'', which conflicts with the negative Michelson-Morley result.
and , with the Lorentz force law for the acceleration of charged particles:Lorentz's aether is simply space endowed with certain dynamical properties. Lorentz gives the modern theory of dielectrics involving
and , and also includes the effect of magnetized matter. He also gives what we now call the Drude-Lorentz harmonic oscillator model of the index of refraction. But Lorentz's theory has a ``stationary aether'', which conflicts with the negative Michelson-Morley result.
1892 - George Fitz Gerald proposes length contraction as a way to reconcile Lorentz's theory and the null results on the motion of the earth through the aether. At the end of this year Lorentz endorses this idea.
1894 - J. J. Thomson measures the speed of cathode rays and shows that they travel much more slowly than the speed of light. The aether model of cathode rays begins to die.
1894 - Philip Lenard studies the penetration of cathode rays through matter.
1895 - Pierre Curie experimentally discovers Curie's law for paramagnetism and also shows that there is no temperature effect for diamagnetism.
1895 - Lorentz, in his ``Search for a theory of electrical and optical effects in moving bodies'' gives the Lorentz transformation to first order in v/c. The transformed time variable he calls ``local time''.
1895 - Wilhelm Roentgen discovers X-rays produced by bremsstrahlung in cathode ray tubes.
1896 - Arthur Shuster, Emil Wiechert, and George Stokes propose that X-rays are aether waves of exceedingly small wavelength.
1896 - J. J. Thomson discovers that materials through which X-rays pass are rendered conducting.
1896 - Henri Becquerel discovers that some sort of natural radiation from uranium salts can expose a photographic plate wrapped in thick black paper.
1896 - P. Zeeman discovers the splitting of atomic line spectra by a magnetic field.
1896 - Lorentz gives an electron theory of the Zeeman effect.
1897 - J. J. Thomson argues that cathode rays must be charged particles smaller in size than atoms (Emil Wiechert made the same suggestion independently in this same year). In response Fitz Gerald suggests that ``we are dealing with free electrons in these cathode rays.''
1897 - W. Wien discovers that positively-charged moving particles can also be made (the so-called canal rays of E. Goldstein) and that they have a much smallerq/m ratio than cathode rays.
1897 - J. J. Thomson deflects cathode rays by crossed electric and magnetic fields and measures e/m.
1898 - Marie and Pierre Curie separate from pitchblende two highly radioactive elements which they name polonium and radium.
1899 - Ernest Rutherford discovers that the rays from uranium come in two types, which he calls alpha and beta radiation.
1900 - Marie and Pierre Curie show that beta rays and cathode rays are identical.
1900 - Emil Wiechert shows that simply replacing the distributed charge 
from Lorentz's theory with the charge of a moving point particle gives incorrect results. Instead the Lienard-Wiechert retarded potentials must be used.
from Lorentz's theory with the charge of a moving point particle gives incorrect results. Instead the Lienard-Wiechert retarded potentials must be used.
1900 - Joseph Larmor obtains the second order corrections to the Lorentz Transformation.
1901 - R. Blondlot performs experiments that show that Lorentz's theory in which there is no moving aether gives the correct result in cases where the hypothesis of a moving aether gives the wrong result.
1902 - Lord Rayleigh performs experiments to test whether the Fitz Gerald contraction is capable of causing double refraction in moving transparent substances. No such effect is found.
1903 - The Hagen-Rubens connections between the conductivity of metals and their optical properties are experimentally established.
1903 - Lorentz gives the famous square root formulas for the Lorentz transformation giving the effect to all orders in v/c.
1904 - Lorentz gives his electron-collision theory of electrical conduction
1905 - H. A. Wilson performs experiments similar to those of Blondlot; again, Lorentz's theory is found to give the correct result.
1905 - Albert Einstein completes Lorentz's work on space-time transformations and relativity is born.
Index
Aepinus, Francis Ulrich Theodore - 1759
Airy, George - 1846
Ampere, Andre Marie - 1820, 1825
Arago, Francois - 1811, 1816
Arrhenius, Svante - 1887
Bartoli, A. - 1876
Becquerel, Henri - 1896
Biot, Jean-Baptiste - 1812, 1820
Blondlot, R. - 1901
Boltzmann, Ludwig - 1879
Boussinesq, Joseph - 1867
Bradley, James - 1728
Brewster, David - 1815, 1816
Cabeo, Niccolo - 1620
Canton - 1762
Carlisle, Anthony - 1800
Cascariolo, Vincenzo - 1630
Cauchy, Augustine Louis - 1828, 1839
Cavendish, Henry - 1775
Coulomb, Charles Augustin - 1785
Crookes, William - 1879
Curie, Marie - 1895, 1900
Curie, Pierre - 1895, 1898, 1900
Davy, Humphrey - 1807, 1821
Descartes, Rene - 1638, 1644
Doppler, Christian - 1842
du Fay, Charles Francois - 1733
Einstein, Albert - 1905
Faraday, Michael - 1812, 1821, 1831, 1833, 1834, 1837, 1838, 1841, 1845, 1846, 1854, 1855
Fermat, Pierre de - 1657
Fitz Gerald, George - 1881, 1883, 1890, 1892
Fizeau, A. - 1849
Foucault, Jean - 1850
Franklin, Benjamin - 1747
Fresnel, Augustin - 1817, 1825, 1827
Galileo - 1638
Galvani, Luigi - 1780
Gauss,Karl Friedrich - 1813
Gilbert, William - 1600
Glazebrook, R. T. - 1888
Gray, Stephen - 1729
Green, George - 1828, 1837, 1839
Grimaldi, Francesco Maria - 1665
Hagen - 1903
Hall, Edwin - 1879
Heaviside, Oliver - 1883, 1889
Helmholtz, Hermann von - 1847, 1870, 1881
Henry, Joseph - 1832, 1842
Herschel, John - 1820
Hertz, Heinrich - 1884, 1887, 1888, 1889
Hittorf - 1869
Hooke, Robert - 1667
Huygens, Christiaan - 1678
Jacquier, Francis - 1742
Joule, James Prescott - 1841
Kerr, John - 1875
Kirchoff, Gustav - 1848, 1857
Lagrange, Joseph Louis - 1764, 1777
Lamb, Horace - 1883
Laplace, Pierre Simon - 1782, 1808, 1813
Larmor, Joseph - 1900
Le Seur, Thomas - 1742
Lenard, Philip - 1894
Lenz,Emil - 1834
Lodge, Oliver - 1892
Lorentz, Hendrik Anton - 1892, 1895, 1896, 1903, 1904
Lorenz, Ludwig - 1867
MacCullagh, James - 1835, 1839
Magnus - 900 BC
Malus, Etienne Louis - 1808
Mascart, E. - 1872
Maxwell, James Clerk - 1855, 1861, 1864, 1868, 1869, 1873
Mayer, Julius Robert - 1842
Michell, John - 1750
Michelson, Albert - 1881
Morley, Edwin - 1881
Musschenbroek, Pieter van - 1745
Navier, Claude Louis Marie Henri - 1827
Neumann, Franz - 1835, 1842, 1845
Newton, Isaac - 1671, 1717
Nicholson, William - 1800
Nollet, Abbe
Jean-Antoine - 1749
Jean-Antoine - 1749
O'Brien, Matthew - 1842
Oersted, Hans Christian - 1820
Ohm,Georg Simon - 1826
Ostrogradsky - 1831
Peltier, Jean Charles - 1834
Peregrinus, Peytrus - 1269
Poisson, Simeon Denis - 1812, 1824, 1828
Poynting, John - 1884
Priestly, Joseph - 1766
Rayleigh, Lord - 1902
Riemann, Bernhard - 1861, 1867
Roemer, Olaf - 1675
Roentgen, Wilhelm - 1888, 1895
Rowland, Henry - 1876, 1880
Rubens - 1903
Rutherford, Ernest - 1899
Savart, Felix - 1820
Savery, F. - 1827
Seebeck,Thomas Johann - 1822
Shuster, Arthur - 1896
Stefan, J. - 1879
Stokes, George Gabriel - 1825, 1849, 1850, 1867, 1896
Sulzer, Johann - 1752
Thales of Miletos - 600 BC
Thomson, J. J. - 1881, 1889, 1894, 1896, 1897
Thomson, William (Lord Kelvin) - 1839, 1846, 1850, 1851, 1853, 1854
Volta, Alessandro - 1793
Watson, William - 1748
Weber, Wilhelm - 1846, 1847
Wiechert, Emil - 1896, 1900
Wien, W. - 1897
Wilson, H. A. - 1905
Young, Thomas - 1801, 1803
Zeeman, Pieter - 1896
