On the concept of determinant for the differential operators of Quantum Physics

Abstract

The concept of determinant for a linear operator in an infinite-dimensional space is addressed, by using the derivative of the operator's zeta-function (following Ray and Singer) and, eventually, through its zeta-function trace. A little play with operators as simple as I (I being the identity operator) and variations thereof, shows that the presence of a non-commutative anomaly (i.e., the fact that det (AB) ≠ det A det B), is unavoidable, even for commuting and, remarkably, also for almost constant operators. In the case of Dirac-type operators, similarly basic arguments lead to the conclusion ---contradicting common lore--- that in spite of being ( D +im) = ( D -im) (as follows from the symmetry condition of the D-spectrum), it turns out that these determinants may not be equal to ( D2 +m2), simply because [( D +im) ( D -im)] ≠ ( D +im) ( D -im). A proof of this fact is given, by way of a very simple example, using operators with an harmonic-oscillator spectrum and fulfilling the symmetry condition. This anomaly can be physically relevant if, in addition to a mass term (or instead of it), a chemical potential contribution is added to the Dirac operator.

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