Consider a simplified classical physics scenario of a hydrogen atom where the electron orbits the proton at a fixed circular orbit of a constant radius. What is the magnetic moment of the electron orbiting a proton? Now this hydrogen atom is placed into the constant magnetic field B oriented perpendicular to the plane of rotation of the electron. Assuming that the radius of rotation did not change, how did the magnetic moment of the configuration change? Does this situation correspond to a diamagnetic, ferromagnetic, or a paramagnetic behavior?
Consider a simplified classical physics scenario of a hydrogen atom where the electron orbits the proton at a fixed circular orbit of a constant radius. What is the magnetic moment of the electron orbiting a proton? Now this hydrogen atom is placed into the constant magnetic field B oriented perpendicular to the plane of rotation of the electron. Assuming that the radius of rotation did not change, how did the magnetic moment of the configuration change? Does this situation correspond to a diamagnetic, ferromagnetic, or a paramagnetic behavior?
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Transcribed Image Text:Consider a simplified classical physics scenario of a hydrogen atom where the electron orbits the proton at
a fixed circular orbit of a constant radius. What is the magnetic moment of the electron orbiting a proton?
Now this hydrogen atom is placed into the constant magnetic field B oriented perpendicular to the plane
of rotation of the electron. Assuming that the radius of rotation did not change, how did the magnetic
moment of the configuration change? Does this situation correspond to a diamagnetic, ferromagnetic, or a
paramagnetic behavior?
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