The Thermodynamic Limit of Quantum Statistical Mechanics & Interpretation of Quantum Field Theory

Question

The philosopher of physics Laura Reutsche argues in her book Interpreting Quantum Theories (review/summary here: http://philsci-archive.pitt.edu/9493/1/ruetsche-review.pdf ) that a "pristine" interpretation (1-1 correspondence between theory and reality) is impossible in quantum field theory, and all that exist are "adulterated" interpretations dependent on particular applications and contexts. Can anyone who thinks this is wrong explain why?

Thanks.

(I realize this is more a a philosophy of physics question, but I'm asking it here b/c Reutsche's book (with C*-Algebras, even a tiny bit of non-commutative geometry, and Hans Halvorson's comment that it is "perhaps the most sophisticated engagement that with mathematical physics that we have ever seen in a "philosophical" monograph") is way too mathematically advanced for most philosophers to understand.)

Answer 1

It seems to me that the main argument given in the book is: while irreducible representations of CCR are all unitarily equivalent in finite dimensional QM, this is no more true in infinite dimensional QM. This leads, roughly speaking, to the necessity of choosing a specific Hilbert space (with a specific realization of the CCR) depending on the system considered. The concrete physical examples are related to spontaneous symmetry breaking effects, and choice of the Fock space vacuum.

If I should point out something that does not appear clear to me (however I have only read the linked review, not the original book) is that:

• The non-unicity of CCR in infinite dimensional QM is true. I am not sure whether it is possible to infer the impossibility of a "pristine" interpretation of QFT from this, mainly because interacting quantum field theories (the only physically meaningful ones) are poorly understood from a mathematical point of view, and we are not able (hopefully not yet able) to define the Hilbert spaces of most physically relevant interacting QFTs. So it is not clear whether it is possible to write two inequivalent theories of QFT that produce different results, mainly because we cannot even construct one!

However, from a more general perspective, I think you may find interesting this (recent) discussion on the unicity of an eventual theory of everything (TOE).