Abstract
We examine the origin of the Newton–Schrödinger equations (NSEs) that play an important role in alternative quantum theories (AQT), macroscopic quantum mechanics and gravity-induced decoherence. We show that NSEs for individual particles do not follow from general relativity (GR) plus quantum field theory (QFT). Contrary to what is commonly assumed, the NSEs are not the weak-field (WF), non-relativistic (NR) limit of the semi-classical Einstein equation (SCE) (this nomenclature is preferred over the ‘Moller–Rosenfeld equation’) based on GR+QFT. The wave-function in the NSEs makes sense only as that for a mean field describing a system of N particles as , not that of a single or finite many particles. From GR+QFT the gravitational self-interaction leads to mass renormalization, not to a non-linear term in the evolution equations of some AQTs. The WF-NR limit of the gravitational interaction in GR+QFT involves no dynamics. To see the contrast, we give a derivation of the equation (i) governing the many-body wave function from GR+QFT and (ii) for the non-relativistic limit of quantum electrodynamics. They have the same structure, being linear, and very different from NSEs. Adding to this our earlier consideration that for gravitational decoherence the master equations based on GR+QFT lead to decoherence in the energy basis and not in the position basis, despite some AQTs desiring it for the ‘collapse of the wave function’, we conclude that the origins and consequences of NSEs are very different, and should be clearly demarcated from those of the SCE equation, the only legitimate representative of semiclassical gravity, based on GR+QFT.
Highlights
Introduction and summaryThe Newton–Schrödinger equations (NSE) play a prominent role in alternative quantum theories (AQT) [1,2,3,4,5], emergent quantum mechanics [6], macroscopic quantum mechanics [7,8,9,10], gravitational decoherence [11, 12] and semiclassical gravity [15, 18,19,20]3
The class of theories built upon these equations, the latest being an application of the many-particle NSE derived in [4, 5] to macroscopic quantum mechanics, have drawn increasing attention of experimentalists who often use them as the conceptual framework and technical platform for understanding the interaction of quantum matter with classical gravity and to compare their prospective laboratory results [23,24,25,26]
In this paper we examine the structure of NSE in relation to general relativity (GR) and quantum field theory (QFT), the two well-tested theories governing the dynamics of classical spacetimes and quantum matter
Summary
The Newton–Schrödinger equations (NSE) play a prominent role in alternative quantum theories (AQT) [1,2,3,4,5], emergent quantum mechanics [6], macroscopic quantum mechanics [7,8,9,10], gravitational decoherence [11, 12] (such as invoked in the Diosi–Penrose models) and semiclassical gravity [15, 18,19,20]3. In the Hartree approximation, χ (r) is not the wave-function of a single particle, but a collective variable that describes a system of N particles under a mean field approximation5 This shows what could go wrong if one stays at the restricted level of particle wavefunctions (rather than the more basic and accurate level of QFT) in exploring the interaction of quantum matter with classical gravity. A coupling of gravity and matter through the single-particle wave functions in quantum mechanics is like treating them implicitly as classical fields This mars their probabilistic role in quantum theory. Like all nonlinear modifications to Schrödingers equation, it is not clear how to interpret such wave-functions when considering probabilities in statistical ensembles Subtle differences, such as the one between a quantum mechanical versus a QFT treatment of quantum matter in the presence of gravity, result in markedly varied consequences. The equations obtained in both cases have the same structure, ostensibly linear, and very different from NSEs
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