Abstract
In this article, we will examine new fundamental aspects of "emergence" and "information" using novel approaches to quantum mechanics which originated from the group around Aharonov. The two-state vector formalism provides a complete description of pre- and post-selected quantum systems and has uncovered a host of new quantum phenomena which were previously hidden. The most important feature is that any weak coupling to a pre- and post-selected system is effectively a coupling to a "weak value" which is given by a simple expression depending on the two-state vector. In particular, weak values, are the outcomes of so called "weak measurements" which have recently become a very powerful tool for ultra-sensitive measurements. Using weak values, we will show how to separate a particle from its properties, not unlike the Cheshire cat story: "Well! I've often seen a cat without a grin," thought Alice; "but a grin without a cat! It's the most curious thing I ever saw in all my life!" Next, we address the question whether the physics on different scales "emerges" from quantum mechanics or whether the laws of physics at those scales are fundamental. We show that the classical limit of quantum mechanics is a far more complicated issue; it is in fact dramatically more involved and it requires a complete revision of all our intuitions. The revised intuitions can then serve as a guide to finding novel quantum effects. Next we show that novel experimental aspects of contextuality can be demonstrated with weak measurements and these suggest new restrictions on hidden variable approaches. Next we emphasize that the most important implication of the Aharonov-Bohm effect is the existence of non-local interactions which do not violate causality. Finally, we review some generalizations of quantum mechanics and their implications for "emergence" and "information." First, we review an alternative approach to quantum evolution in which each moment of time is viewed as a new "universe" and time evolution is given by correlations between different moments. Next, we present a new solution to the measurement problem involving future boundary conditions placed on the universe as a whole. Finally, we introduce another fundamental approach to quantum evolution which allows for tremendous richness in the types of allowable Hamiltonians.
Highlights
The conference’s title “Emergent Quantum Mechanics” (EmQM) was defined as “...a possible deeper-level theory that interconnects three fields of knowledge: emergence, the quantum, and information.” In this article, we will examine this from a number of novel approaches originating from the group around Aharonov
We will show how to separate a particle from its properties, not unlike the Cheshire cat story: “Well! I’ve often seen a cat without a grin,” thought Alice; “but a grin without a cat! It’s the most curious thing I ever saw in all my life!” we address the question whether the physics on different scales “emerges” from quantum mechanics or whether the laws of physics at those scales are fundamental
We show that the classical limit of quantum mechanics is a far more complicated issue; it is dramatically more involved and it requires a complete revision of all our intuitions
Summary
The conference’s title “Emergent Quantum Mechanics” (EmQM) was defined as “...a possible deeper-level theory that interconnects three fields of knowledge: emergence, the quantum, and information.” In this article, we will examine this from a number of novel approaches originating from the group around Aharonov. A positive spin was placed on QM’s non-trivial relationship between initial and final conditions by Aharonov, Bergmann and Lebowitz (ABL) [1] who showed that the new information obtained from subsequent measurements were relevant for the past of every quantum-system and not just the future This inspired ABL to re-formulate QM in terms of Pre- and Post-Selected ensembles (PPS). Since the particle is free, the spin is conserved in time and for any t ∈ [tin, tfin], an ideal-measurement of either σx or σy, yields +1 for this pre- and post-selection This by itself, two non-commuting observables known with certainty, is a most surprising property which no pre-selected-only-ensemble could possess.
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