Flux density is important because it quantifies the amount of a physical quantity (such as energy, particles, or field lines) passing through a unit area per unit time. It helps in understanding the strength and distribution of various fields, like magnetic or electric fields, in physics and engineering. Flux density is a crucial parameter in many scientific and engineering applications, such as electromagnetic devices, material characterization, and energy transfer.
Flux is related to the speed of change in a physical quantity through the concept of flux density. Flux density is the amount of flux passing through a unit area per unit time. The faster the change in the physical quantity, the higher the flux density.
The quantity symbol for electric flux density is D.
When flux density increases, the force experienced by a current-carrying conductor due to a magnetic field (sideways force in this case) will also increase. This is because the force is directly proportional to the magnetic flux density and the current in the conductor.
Scalar
Sources of error when obtaining Earth's magnetic flux density in an experiment can include external magnetic interference from nearby sources, imperfect calibration of instruments leading to inaccurate measurements, and variations in the Earth's magnetic field itself over time and location. It is also important to consider any errors introduced during data recording and analysis.
In case of electrostatics, flux density = electric field intensity and in case of magnetism, flux density = magnetic field induction
Flux is related to the speed of change in a physical quantity through the concept of flux density. Flux density is the amount of flux passing through a unit area per unit time. The faster the change in the physical quantity, the higher the flux density.
The quantity symbol for electric flux density is D.
once flux density is known multiply to it the area perpendicular to the flux lines . the product is the total flux passing through the area. If field strength is known , get the flux density by pultiplying to it the permeability of the medium. then flux can be obtained as above. from : govind Kunkolienker kunkolienker@yahoo.com
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.
Tesla.
"Magnetic flux density" is also known as the magnetic field,The SI unit for this is the Tesla, written as T.CommentMagnetic flux density is not "also known as the magnetic field". It describes the intensity of a magnetic field.
Your question is unclear, but flux density is a function of the cross-sectional area of the magnetic circuit in which the magnetic flux is established.Flux density (symbol: B) is defined as 'the flux per unit area'. If the flux is measured in webers (pronounced 'vay-bers') and the cross-sectional area is measured in square metres, then the flux density is measured in teslas(symbol: T) which is a special name given to a weber per square metre.
1yards = ? meters
Something that which produces a magnetic fieldThe magnetic field that surrounds a magnet is made up of magnetic flux (symbol, the Greek letter 'phi'), usually represented as lines in field diagrams. The SI unit for measuring magnetic flux is the weber (pronounced 'vay-ber'). The intensity of this flux (the closeness of the lines in diagrams) is called the flux density (symbol: B). Flux density is greatest in the areas nearest a magnet's poles. Flux Density is defined as 'flux per unit area', and is measured in webers per square metre which, in SI, is given the special name, the 'tesla'.
Gaussmeter
Magnetic flux density.