Am I destroying or disrupting the foundation of physics by inquiring if it has overlooked the exclusion of mutual inductance from conservation?

Question

By attempting to ask this question ...

Has it ever been proven, or disproven, that a coincident set of mutual inductances are always conserved?

... at Quora, I got this first response ...

https://qr.ae/prI2DA

... suggesting to me that I must have violated something sacred and/or fundamental to inspire acts of destruction in the mind of my reader as being the only solution to my question.

Yet, all I wish to know concerns a hole in my awareness regarding conservability within the domain of multiple, interactive, mutual inductances? Because the manner in which Kirchhoff's Current Law is phrased, could suggest that anything outside of a circuit's nodal connections are outside of the Conservation of Energy.

Usually, regarding manmade laws, anything not explicitly prohibited is always allowed. So, I applied that standard to this situation to conclude that Conservation does not apply to mutual inductance of the type which I am suggesting (not the commonplace type of a normal transformer).

Answer 1

Before calculus was used for modeling physics observations , there were a number of "laws" that can now be defined within the mathematical theories . If you read the introduction to Kirchhoff's circuit laws in wikipedia you will see that these laws are mathematically explainable in the strict theory of Maxwell's equations.

Both of Kirchhoff's laws can be understood as corollaries of Maxwell's equations in the low-frequency limit. They are accurate for DC circuits, and for AC circuits at frequencies where the wavelengths of electromagnetic radiation are very large compared to the circuits.

Italic mine for emphasis.

As Maxwell's equation for electromagnetism have been validated at the classical level there is no need to bother about conservation of energy. Even in a complicated set up of circuits if one took the trouble one would get back to the conservation laws of Maxwell's equation.