Fixed magnetic fields, such as the field around a piece of magnetic metal or around a planet such as the earth have no effect on what is called "electromagnetic" or "wave" radiation, which includes, radio waves, microwaves, infrared, visible, and ultraviolet light, x-rays, and gamma rays (named in order of increasing energy and frequency.)
A charged particle is accelerated in magnetic field if it has a velocity. F = Q v x B, where v x B is cross-product of speed and magnetic flux vectors. According to Newton F = ma where you can find the acceleration if you know the mass.
These are gamma rays and X-rays.
Magnetic flux density = mu x magnetizing intensity. ie B = mu H. mu is known as magnetic permeability of the medium. If it is just air or vacuum, then mu is mu0 ie permeability of free space whose value is 4pi x 10 -7 H/m. If it is other than air or vacuum then the permeability will be mur mu0 where mur is known as relative permeability. If mur is less than one then the magnetic material will be dia magnetic. If mur is slightly greater than one then magnetic material is para magnetic. If mur is very much greater than one then magnetic material is ferro magnetic.
- Magnetic field strength is the intensity of a magnetic field at a given location. Historically, a distinction is made between magnetic field strength H, measured in ampere/meter, and magnetic flux density B, measured in tesla. Magnetic field strength is defined as the mechanical force (newton) on a wire of unit length (m) with unit electric current(A). The unit of the magnetic field, therefore, is newton/ (ampere x meter), which is called tesla. The magnetic field may be visualized by magnetic field lines. The field strength then corresponds to the density of the field lines. The total number of magnetic field lines penetrating an area is called magnetic flux. The unit of the magnetic flux is tesla x m2 = weber. The older units for the magnetic flux, maxwell = 10-8 weber, and for the magnetic flux density, gauss = maxwell / cm2 = 10-4 tesla, are not to be used any more. Magnetic flux density diminishes with increasing distance from a straight current-carrying wire or a straight line connecting a pair of magnetic poles around which the magnetic field is stable. At a given location in the vicinity of a current-carrying wire, the magnetic flux density is directly proportional to the current in amperes. If a ferromagnetic object such as a piece of iron is brought into a magnetic field, the "magnetic force" exerted on that object is directly proportional to the gradient of the magnetic field strength where the object is located. ------------------------------------------------------------------- B=μH Magnetic field in Solenoid B=μnI where n is turns/m So H=nI --------------------------------------------
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M. K. Booker has written: 'Evaluation of creep and relaxation data for Hastelloy alloy X sheet' -- subject(s): Heat resistant alloys, Deformations (Mechanics)
Hastelloy C276 is a nickel-molybdenum-chromium superalloy known for its corrosion resistance in a wide range of environments. A494 CW-12MW, on the other hand, is a cast superalloy with higher nickel and molybdenum content designed for high-temperature applications such as in power generation or petrochemical industries. CW-12MW offers excellent resistance to both oxidation and corrosion at elevated temperatures compared to Hastelloy C276.
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That they have neither a negative or positive charge
Magnetic deflection sensitivity of a cathode ray oscilloscope (CRO) is defined as the amount of deflection of electron spot produced when a magnetic flux density of 1 Wb/m2 is applied. SM = (e / m )1\2 x 1\ (2V0) 1\2 x l x L
Fixed magnetic fields, such as the field around a piece of magnetic metal or around a planet such as the earth have no effect on what is called "electromagnetic" or "wave" radiation, which includes, radio waves, microwaves, infrared, visible, and ultraviolet light, x-rays, and gamma rays (named in order of increasing energy and frequency.)
A charged particle is accelerated in magnetic field if it has a velocity. F = Q v x B, where v x B is cross-product of speed and magnetic flux vectors. According to Newton F = ma where you can find the acceleration if you know the mass.
These are gamma rays and X-rays.
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AMS5798 (Hastelloy) is the registered trademark name of Haynes International, Inc. You should contact them to obtain this information.