Is dimagnetism created with liquid nitrogen to cause a object such as a frog that isn't?

1 ANSWERS

1. 
   

   A salt or metal is diamagnetic, when it non-aligns with an applied magnetic field and weakly repels it.
   
   If the magnetisation of a material is given by: -
   
   M = χB/μ0
   
   Where 'B' is the field and 'μ0' is the magnetic permeability of free space with 'χ' as the magnetic susceptibility. Such that: -
   
   χ = μ0N{(m²/3kT) -((e²/6m(e)).Zr(0)²)}
   
   For superconductors, perfect diamagnetism occurs. It is this Meissner effect that is exploited to levitate small 'cold' objects above a magnet!
   
   [From Wikipedia, the free encyclopedia] 'The Meissner effect (also known as the Meissner-Ochsenfeld effect) is the expulsion of a magnetic field from a superconductor. Walther Meissner and Robert Ochsenfeld discovered the phenomenon in 1933 by measuring the flux distribution outside of tin and lead specimens as they were cooled below their transition temperature in the presence of a magnetic field. They found that below the superconducting transition temperature the specimens became perfectly diamagnetic, cancelling all flux inside. The experiment demonstrated for the first time that superconductors were more than just perfect conductors and provided a uniquely defining property of the superconducting state.
   
   In a weak applied field a superconductor expels all magnetic flux. Although the magnetic field is completely expelled from the interior of the superconductor, there is not a sharp transition at the edges of a sample, but rather a rapid decay of field into the sample over a distance, the penetration depth. Each superconducting material has its own characteristic penetration depth. When the temperature of a superconductor in a weak magnetic field is cooled below the transition temperature, surface currents arise that generate a magnetic field which yields zero net magnetic field within the superconductor. These currents do not decay in time, thus establishing that perfect diamagnetism implies zero electrical resistance. Called persistent currents, they only flow within a depth equal to the penetration depth, whose theory was given in the London equations by the brothers Fritz and Heinz London.
   
   Superconductors in the Meissner state exhibit perfect diamagnetism, or superdiamagnetism, such that their magnetic susceptibility, = −2. Diamagnetism is defined as the generation of a spontaneous magnetization of a material which directly opposes the direction of an applied field. Because the spontaneous generation of magnetic energy violates the conservation of energy law, perfect diamagnetism is a function of the efficiency of acquisition of a magnetic energy by material moving toward a magnetic field. For perfect diamagnetism, the velocity toward the magnetic field and the rate of change of magnetic field intensity has no influence on the amount of magnetic energy the material acquires. However, the fundamental origins of the diamagnetism in superconductors and normal materials are very different. In superconductors the diamagnetism arises from the persistent screening currents which flow to oppose the applied field; in normal materials diamagnetism arises as a direct result of an orbital rotation of electrons about the nuclei of an atom induced electromagnetically by the application of an applied field.
   
   The discovery of the Meissner effect led to the phenomenological theory of superconductivity by F. and H. London in 1935. This theory explained resistanceless transport and the Meissner effect, and allowed the first theoretical predictions for superconductivity to be made. However, this theory only explained experimental observations - it did not allow the microscopic origins of the superconducting properties to be identified. Nevertheless, it became a requirement on all microscopic theories to be able to reproduce this effect. This was done successfully by the BCS theory in 1957.'

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