Australian Magnetic Solutions

Glossary of Magnetic Terms

Quick link - click on the first letter of the word you want to find:
A - B - C - D - E - F - G - H - I - J - K - L - M - N - O - P - Q - R - S - T - U - V - W - X - Y - Z

The lower part of the trunk of the body, the belly
Achilles tendon
Thickest and strongest tendon in the human body, extending from midcalf to the heel
Air Gap
A low permeability gap in the flux path of a magnetic circuit. Often air, but inclusive of other materials such as paint, aluminum, etc.
Anisotropic Magnet
A magnet having a preferred direction of magnetic orientation, so that the magnetic characteristics are optimum in one preferred direction.
Reduction of swelling
Inflammation of a joint
Bipolar Magnets
Both poles are on one side
Carpal tunnel
A painful and disabling disorder caused by inflammation in the tendons that run through the narrow carpal tunnel in the wrist
Continuing for a long time, deep seated and lasting
Closed Circuit
This exists when the flux path external to a permanent magnet is confined within high permeability materials that compose the magnet circuit.
Coercive Force, Hc
The demagnetising force, measured in Oersteds, necessary to reduce observed induction, B, to zero after the magnet has previously been brought to saturation.
The reduction of volume by pressure
Rolled together
Painful contraction of muscles of the body
Curie Temperature, Tc
The temperature at which the parallel alignment of elementary magnetic moments completely disappears, and the material is no longer able to hold magnetisation.
Demagnetisation Curve
The second quadrant of the hysteresis loop, generally describing the behavior of magnetic characteristics in actual use. Also known as the B-H Curve.
Dense medium
This medium is a suspension of solid particles in water
Eddy Currents
Circulating electrical currents that are induced in electrically conductive elements when exposed to changing magnetic fields, creating an opposing force to the magnetic flux. Eddy currents can be harnessed to perform useful work (such as damping of movement), or may be unwanted consequences of certain designs, which should be accounted for or minimized.
A magnet, consisting of a solenoid with an iron core, which has a magnetic field existing only during the time of current flow through the coil.
Energy Product
Indicates the energy that a magnetic material can supply to an external magnetic circuit when operating at any point on its demagnetisation curve. Calculated as Bd x Hd, and measured in Mega Gauss Oersteds, MGOe.
Ferromagnetic Material
A material whose permeability is very much larger than 1 (from 60 to several thousand times 1), and which exhibits hysteresis phenomena.
The process of making many fine particles join together into fewer but coarser particles
The condition existing in a medium subjected to a magnetising force. This quantity is characterized by the fact that an electromotive force is induced in a conductor surrounding the flux at any time the flux changes in magnitude. The cgs unit of flux is the Maxwell.
Flux Density, B
The magnetic flux per unit area of a section normal to the direction of flux. Also known as magnetic induction. Measured in Gauss, in the cgs system of units.
An instrument that measures the change of flux linkage with a search coil.
When you observe waves in a pool or as they hit the edge or a cork bobbing up and down in the water with the wave you are actually seeing a physical form of frequency in action. If you were to count the number of times the cork bobbed up every second you will have the number that is know as frequency in cycles per second. If you want you can count the bobs in a minute you will then have the number that is the frequency in cycles per minute. The same thing happens with sound. When a guitarist hits the string the string oscillates or vibrates at so many cycles or vibrations per second. So the string oscillates at a specific frequency that you hear as sound. This is also true for light but with light you see colours rather than hear sounds. The same is also true for electricity, electric fields and magnetic fields.
Fringing Fields
Leakage flux particularly associated with edge effects in a magnetic circuit.
Froth flotation
A method of cleaning fine coal
Lines of magnetic flux per square centimeter, cgs unit of flux density, equivalent to lines per square inch in the English system, and Webers per square meter or Tesla in the SI system.
An instrument that measures the instantaneous value of magnetic induction, B. Its principle of operation is usually based on one of the following: the Hall effect, nuclear magnetic resonance (NMR), or the rotating coil principle.

Objects vibrating in nature usually have a main natural frequency. This natural fundamental frequency has associated with it a series of other frequencies, which are multiples of it. These frequencies are called Harmonic Frequencies. If the fundamental frequency is say 200 cycles per second (referred to as 200 Hertz or 200 Hz) then the 2nd Harmonic is 400 Hz, 3rd Harmonic is 600 Hz and so on as shown below.

Objects vibrating in nature usually have a main natural frequency and a series of other harmonic natural frequencies which are multiples of it

For sound we have that:

  1. A harmonic is one of a series of sonic components of a sound.
  2. A sounding pitch comprises a fundamental, and a number of harmonics above that fundamental, the totality being called a harmonic spectrum.
  3. The make-up of a spectrum (which harmonics are present, and in what proportion) produces the timbre, or tone color, of an instrument or voice.
  4. Harmonics can be produced separately on an instrument.

Hysteresis Loop
A closed curve obtained for a material by plotting corresponding values of magnetic induction, B, (on the abscissa) against magnetising force, H, (on the ordinate).
Induction, B
The magnetic flux per unit area of a section normal to the direction of flux. Measured in Gauss, in the cgs system of units.
Chronic sleeplessness
Intrinsic Coercive Force, Hci
Measured in Oersteds in the cgs system, this is a measure of the materialís inherent ability to resist demagnetisation. It is the demagnetisation force corresponding to zero intrinsic induction in the magnetic material after saturation. Practical consequences of high Hci values are seen in greater temperature stability for a given class of material, and greater stability in dynamic operating conditions.
Intrinsic Induction, Bi
The contribution of the magnetic material to the total magnetic induction, B. It is the vector difference between the magnetic induction in the material and the magnetic induction that would exist in a vacuum under the same field strength, H. This relationship is expressed as: Bi = B-H.
Irreversible Loss
Defined as the partial demagnetisation of a magnet caused by external fields or other factors. These losses are only recoverable by re-magnetisation. Magnets can be stabilized to prevent the variation of performance caused by irreversible losses.
Isotropic Magnet
A magnet material whose magnetic properties are the same in any direction, and which can therefore be magnetised in any direction without loss of magnetic characteristics.
A piece of soft iron that is placed on or between the poles of a magnet, decreasing the reluctance of the air gap and thereby reducing the flux leakage from the magnet.
Knee of the Demagnetisation Curve
The point at which the B-H curve ceases to be linear. All magnet materials, even if their second quadrant curves are straight line at room temperature, develop a knee at some temperature. Alnico 5 exhibits a knee at room temperature. If the operating point of a magnet falls below the knee, small changes in H produce large changes in B, and the magnet will not be able to recover its original flux output without re-magnetisation.
Lactic acid
Generated in milk by fermentation of lactose, building up of large amounts in muscle leads to fatigue and can cause cramps
Leakage Flux
That portion of the magnetic flux that is lost through leakage in the magnetic circuit due to saturation or air-gaps, and is therefore unable to be used.
Length of air-gap, Lg
The length of the path of the central flux line in the air-gap.
Strong fibrous tissue bands connecting the bones of the body
Load Line
A line drawn from the origin of the Demagnetisation Curve with a slope of -B/H, the intersection of which with the B-H curve represents the operating point of the magnet. Also see Permeance Coefficient.
Lupus erythematosus
Chronic autoimmune disease in which the immune system treats the body as a foreign substance and produces antibodies to fight it
Magnetic Circuit
An assembly consisting of some or all of the following: permanent magnets, ferromagnetic conduction elements, air gaps, electrical currents.
Magnetic Flux
The total magnetic induction over a given area. When the magnetic induction, B, is uniformly distributed over an area A, Magnetic Flux = BA.
Magnetic Flux Density, B
The magnetic flux per unit area of a section normal to the direction of flux. Also known as magnetic induction. Measured in Gauss, in the cgs system of units.
Magnetic Induction, B
The magnetic flux per unit area of a section normal to the direction of flux. Measured in Gauss, in the cgs system of units.
Magnetising Force, H
The magnetomotive force per unit length at any point in a magnetic circuit. Measured in Oersteds in the cgs system.
A magnetic ore of iron
Magnetomotive Force, F
Analogous to voltage in electrical circuits, this is the magnetic potential difference between any two points.
Capable of being hammered or extended by beating
Maximum Energy Product, BHmax
The point on the Demagnetisation Curve where the product of B and H is a maximum and the required volume of magnet material required to project a given energy into its surroundings is a minimum. Measured in Mega Gauss Oersteds, MGOe.
Multiple sclerosis
A progressive autoimmune disease in which the body attacks it’s own central nervous system, gradually destroying the white fatty substance that surrounds nerve fibers, thereby damaging sites in the brain and spinal cord
Natural Frequency

As an example, strings of differing thickness, tension or length will make a different sound when they vibrate. This is because the different strings vibrate at a different rate or frequency. Each different string will vibrate at its own natural frequency. Typically a long fat string will have a low Natural Frequency and a short thin string will have a higher Natural Frequency. Hence an instrument designed to make low deep sounds is typically large as is the Bass. So this instrument is designed to have a low Natural Frequency.

This is also true for light but with light you see different colours rather than hear different sounds.

So what I am getting at is that everything has a Natural Frequency. Including trees, poles, buildings, electrical components and body parts.

Natural Frequency Response
Everything will respond in a different way to a variety of frequencies. This is its Natural Frequency Response. Sitting in the bath you may see that if you move your hand back and forward to generate a wave in the water you will find that one rate of movement (at the Natural Frequency) will make one large wave that will spill water out of the tub. Moving your hand faster or slower will not achieve the same result or response. This range of responses is the Natural Frequency Response of the bath of water with you in it.
Synthetic rubber
North Pole
That pole of a magnet which, when freely suspended, would point to the north magnetic pole of the earth. The definition of polarity can be a confusing issue, and it is often best to clarify by using "north seeking pole" instead of "north pole" in specifications.
Oersted, Oe
A cgs unit of measure used to describe magnetising force. The English system equivalent is Ampere Turns per Inch, and the SI systemís is Ampere Turns per Meter.
Orientation Direction
The direction in which an anisotropic magnet should be magnetised in order to achieve optimum magnetic properties. Also known as the "axis", "easy axis", or "angle of inclination".
Degenerative disease characterised by inflammation of the joints between bones
Bone condition characterised by a decrease in mass, resulting in bones that are more porous and more easily fractured than normal bones
Electrical device designed to stimulate regular beating of the heart, using electrodes implanted in the body
Paramagnetic Material
A material having a permeability slightly greater than 1.
The kneecap
The outside
The inverse of reluctance, analogous to conductance in electrical circuits.
Permeance Coefficient,Pc
Ratio of the magnetic induction, Bd, to its self demagnetising force, Hd. Pc = Bd / Hd. This is also known as the "load line", "slope of the operating line", or operating point of the magnet, and is useful in estimating the flux output of the magnet in various conditions. As a first order approximation, Bd / Hd = Lm / Lg, where Lm is the length of the magnet, and Lg is the length of an air gap that the magnet is subjected to. Pc is therefore a function of the geometry of the magnetic circuit.
Velvet-like fabric
Pole Pieces
Ferromagnetic materials placed on magnetic poles used to shape and alter the effect of lines of flux.
Repetitive strain injury
Relative Permeability
The ratio of permeability of a medium to that of a vacuum. In the cgs system, the permeability is equal to 1 in a vacuum by definition. The permeability of air is also for all practical purposes equal to 1 in the cgs system.
Reluctance, R
Analogous to resistance in an electrical circuit, reluctance is related to the magnetomotive force, F, and the magnetic flux by the equation R = F/(Magnetic Flux), paralleling Ohm's Law where F is the magnetomotive force (in cgs units).
Remanence, Bd
The magnetic induction that remains in a magnetic circuit after the removal of an applied magnetising force. If there is an air gap in the circuit, the remanence will be less than the residual induction, Br.
Residual Induction, Br
This is the point at which the hysteresis loop crosses the B axis at zero magnetising force, and represents the maximum flux output from the given magnet material. By definition, this point occurs at zero air gap, and therefore cannot be seen in practical use of magnet materials.

Let us suppose you get two guitars and tune them exactly the same, that is, make each corresponding string on each guitar vibrate at exactly the same frequency. You then bring the two guitars close together and strike one of the strings. You will find that the corresponding string on the other guitar will begin to vibrate. This phenomenon is called Resonance. It is when some vibration or frequency matches the Natural Frequency of a nearby object the object begins to vibrate at the same rate as a result of that vibration. Hence we have that Resonance is the result of influence from a distant vibrating source that happens to match the Natural frequency of the object being influenced. The concept of resonance is true for all vibrating fields be they physical or electromagnetic. This principle is used every day with electromagnetic signals when you tune your radio onto your favorite radio station.

Getting back to the sound example we can look at your eardrum and the cochlea inside your ear. The eardrum transfers the sound vibration to your cochlea, which changes these vibrations into electrical impulses, which go to your brain so you hear the sound. The cochlea can do this because it is made up of thousands of hair like strings, which are all of a different length hence they resonate at different rates of frequency. So we can say that each hair has a different frequency response so a different hair will vibrate at a different resonant frequency to a different sound. Each hair sends a different signal to the brain hence you hear the different sounds. Sorry about the quick lesson in biology but I'm trying to get to the idea of influence at a distance and how some things react to each other because they have some feature or characteristic in common.

Return Path
Conduction elements in a magnetic circuit which provide a low reluctance path for the magnetic flux.
Reversible Temperature Coefficient
A measure of the reversible changes in flux caused by temperature variations.
Lower back between the lumbar vertebrae and the coccyx
The condition under which all elementary magnetic moments have become oriented in one direction. A ferromagnetic material is saturated when an increase in the applied magnetising force produces no increase in induction. Saturation flux densities for steels are in the range of 16,000 to 20,000 Gauss.
Pain travelling the length of the sciatic nerve, the longest in the human body runs from the lower back through the pelvic region and down back of the leg
Also known as curvature of the spine, a progressive lateral (side to side) curvature of the backbone
Search Coil
A coil conductor, usually of known area and number of turns that is used with a fluxmeter to measure the change of flux linkage with the coil.
Viral infection of nerve ganglia, accompanied by severe pain
South Pole
That pole of a magnet which, when freely suspended, would point opposite to the north magnetic pole of the earth. See North Pole definition.
Stretchable poly plastic
Sudden involuntary contracting of muscles
Ductless organ lying to left of stomach
Exposure of a magnet to demagnetising influences expected to be encountered in use in order to prevent irreversible losses during actual operation. Demagnetising influences can be caused by high or low temperatures, or by external magnetic fields.
Inflammation of a synovial membrane (pertaining to fluid in the joints and tendons)
Temperature Coefficient
A factor, which describes the change in a magnetic property with change in temperature. Expressed as percent change per unit of temperature.
Tough fibrous cord attaching muscle to bone
Damaging of the tendons
The equipment in which flocculation is carried out
Chest region
Trunk of human body
To lie underneath
Removed foul air from and supplied with fresh air
The practical unit of magnetic flux. It is the amount of magnetic flux which, when linked at a uniform rate with a single-turn electric circuit during an interval of 1 second, will induce in this circuit an electromotive force of 1 volt. Wb = V s = m2 kg/s2 A.