The magnetic energy density is directly proportional to the strength of a magnetic field. This means that as the strength of the magnetic field increases, the magnetic energy density also increases.
The surface current density on a current sheet is directly proportional to the magnetic field it produces. This means that as the surface current density increases, the strength of the magnetic field also increases.
Neodymium is a type of rare earth magnet that is known for its strong magnetic properties. When neodymium magnets are used in a magnetic field, they can significantly increase the strength of the field due to their high magnetic flux density. This means that neodymium magnets can enhance the overall magnetic field strength when placed within it.
The phenomenon you are referring to is known as hysteresis. In hysteresis, the magnetic field in a material lags behind changes in the magnetic field strength, creating a loop-shaped relationship between the magnetic field and the magnetic flux density. This lag is due to the alignment of magnetic domains within the material.
Yes, magnetic fields can pass through gases. However, the strength and interaction of the magnetic field with the gas will depend on factors such as the type of gas, its density, and the strength of the magnetic field.
No, the density of a magnetic field cannot be sent parallel to infinity. The magnetic field strength decreases with distance from its source, meaning it will weaken as it spreads out from a source.
The surface current density on a current sheet is directly proportional to the magnetic field it produces. This means that as the surface current density increases, the strength of the magnetic field also increases.
Neodymium is a type of rare earth magnet that is known for its strong magnetic properties. When neodymium magnets are used in a magnetic field, they can significantly increase the strength of the field due to their high magnetic flux density. This means that neodymium magnets can enhance the overall magnetic field strength when placed within it.
they are directly proportional and are sometimes used interchangeably.. flux can be insolation , magnetic lines, electrostatic density, pressure... within a document they generally refer to the same entity if one is electric and one magnetic be careful to sort out which is witch
There is no straightforward answer to your question. A tesla is the unit of measurement for magnetic flux density, defined in terms of magnetic flux per unit area. Magnetic flux density is determined by the magnetic field strength of the magnetic circuit in question which is expressed in ampere (turns) per metre. Unfortunately, the relationship between magnetic field strength and flux density isn't straightforward, as it depends on the shape of the B/H curve for the magnetic circuit's material. So, as you can see, there are too many unknown variables to give you a straightforward answer.
In simple terms, if flux density increases, then field strength increases and vice versa. The flux density is equivalent to field strength times with a variable.
Magnetic field strength (H) is defined as the magnetomotive force per unit length, and is expressed in amperes per metre (often spoken as 'ampere turns per metre') in SI. An older, and far more descriptive term, is 'magnetomotive force gradient'.The 'closeness' or intensity of a magnetic field's flux lines, on the other hand is termed magnetic flux density(B), expressed in teslas in SI.There is a complex relationship between magnetic field strength and flux density, because of a property exhibited by ferromagnetic materials, called 'hysteresis'. In general, as the magnetic field strength applied to a sample of unmagnetised ferromagnetic material increases, the resulting flux density also increases (but not linearly) until saturation is reached, at which point any further increase in magnetic field strength will have no effect whatsoever on the flux density. If the magnetic field strength is then reduced, the flux density will also reduce (again, not linearly), but when the magnetic field strength reaches zero amperes, a certain amount of flux density remains.So to answer your question, you really need to study what's known as the B-H or magnetising curve for a sample of ferromagnetic material -this will show you exactly what the relationship between magnetic field strength and flux density for any give ferromagnetic material.
The relative density of lines in a magnetic field diagram indicates the strength of the magnetic field in that region. A higher density of lines represents a stronger magnetic field, while a lower density indicates a weaker field. The spacing between the lines also gives an idea of the field's intensity, with closer lines indicating stronger magnetic force.
The phenomenon you are referring to is known as hysteresis. In hysteresis, the magnetic field in a material lags behind changes in the magnetic field strength, creating a loop-shaped relationship between the magnetic field and the magnetic flux density. This lag is due to the alignment of magnetic domains within the material.
Yes, magnetic fields can pass through gases. However, the strength and interaction of the magnetic field with the gas will depend on factors such as the type of gas, its density, and the strength of the magnetic field.
No, the density of a magnetic field cannot be sent parallel to infinity. The magnetic field strength decreases with distance from its source, meaning it will weaken as it spreads out from a source.
The magnetic field used in machines is quantified in terms of its flux density (symbol: B), expressed in teslas. The flux density is established by the magnetic field strength (H), expressed in amperes per metre, set up in the field windings.As the magnetic field strength increases, the flux density increases until it reaches saturation. This is the point when the magnetic domains within the magnetic circuit are all aligned. At this point, any further increase in magnetic field strength will fail to increase the flux density.So saturation of the magnetic circuit limits the flux density of the field.
The unit of magnetism are: Weber for magnetic flux, Tesla for magnetic flux density and ampere per meter for magnetic field strength.