There are
~ 10²⁵ conducting electrons
in the wire. The mass of these electrons is
~ 10⁻⁵ kilograms.
The charge of these electrons is
~ 10⁶ coulombs.
We want to create a 1 ampere current in the wire.
The inductance of the wire is
L ~ 1 microhenry.
The voltage to increase the current I in the wire is
V = L dI / dt.
We put a voltage V of 1 microvolt over the wire for 1 second. After that time, the current is 1 ampere.
The Coulomb force of 1 microvolt / meter on the charge 10⁶ coulombs is
F ~ 1 newton.
The energy of the magnetic field after the operation is
1/2 L I² ~ 1 microjoule.
The "impulse" which the voltage exerted on the conducting electrons was
p = 1 newton second.
The collective velocity of the electrons is only
v = 1 micrometer / second.
It is as if the "inertial mass" of the electrons were a whopping
10⁶ kilograms.
The kinetic energy and the momentum calculated from the rest mass of the electrons is very small. The momentum is only
10⁻¹¹ newton seconds,
and the kinetic energy is
10⁻¹⁷ joules.
Radiation pressure at 4 K is negligible on an object moving 1 micrometer per second
Suppose that we have an object carrying those one million coulombs of charge and moving at v = 1 micrometer per second. That corresponds to a current of one ampere.
We want to calculate the frictional force that the reflection of black body radiation at 4 kelvins imposes on the object.
Let us assume that the area A of the object is one square meter. The power of black body radiation is
P = A σ T⁴,
where σ = 5.67 * 10⁻⁸ W/(m² K⁴) is the Stefan-Boltzmann constant and T is the temperature. We have
P = 1.4 * 10⁻⁵ W
at 4 K. The radiation pressure force by the power P is
P / c = 5 * 10⁻¹⁴ N.
The pressure is almost the same on the each side of the object, except for the Doppler shift caused by the tiny velocity v = 1 μm/s.
The effect of the Doppler shift is
4 v / c,
because the reflection adds a factor of two, and the effect is on both sides of the object.
We conclude that the frictional force on the object by black body radiation is
F ~ 4 v / c * P / c
= 7 * 10⁻²⁸ N.
We calculated above that, to create the magnetic field for a 1 ampere current in a one meter wire, we have to expend 1 newton second of impulse. The force F is negligible relative to that.
The friction from black body radiation is negligible at 4 K. The resistivity at a low temperature has to come from collisions with the lattice. Those collisions move a large amount of impulse from the lattice to the electrons.
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