Neutrinos passing through everything at a high volume and rate can have "magnetic moments" allowing them to have an effect on chemical reactions and even thinking. Forget the tin foil hats neutrinos pass right through them.

Magnetically sensitive reactions almost always involve radicals, i.e., molecules that have an odd number of electrons and consequently an unpaired electron spin that may be found in one of 2 spin states: ↑ or ↓. A radical pair is a short-lived reaction intermediate

 comprising 2 radicals formed in tandem whose unpaired electron spins may be either antiparallel (↑↓, a singlet state, S) or parallel (↑↑, a triplet state, T). As each electron spin has an associated magnetic moment, the interconversion and chemical fates of the S and T states can be influenced by internal and external magnetic fields.

In chemical terms, the minimum requirement for a radical pair reaction to be sensitive to an external magnetic field is that at least one of the S and T states undergoes a reaction that is not open to the other, usually as a consequence of the imperative to conserve spin angular momentum. Fig. 1

shows what is probably the simplest reaction scheme possessing the essential chemical features required to form the basis of a magnetic compass. Imagining for now that the radicals are completely immobile, the individual reaction steps are as follows. ~Wiki

Read about the Gerber Matrix Theory