Tunneling time problem: At the intersection of quantum mechanics, classical probability theory and special relativity

Abstract

After the review by Hauge and Stovneng the old question of "How long does it take to tunnel through the barrier?" has not still lost its relevance. As before, there is no clear answer to this question even for the one-dimensional completed scattering (OCS). In this paper we show that this seemingly simple question stands alongside with such fundamental problems of quantum mechanics (QM) as the Schrodinger's-cat and and EPR-Bohm paradoxes. Their common feature is that the states of a scattered particle, a radioactive atom and electron EPR-pair represent pure micro-cat states. It is widely accepted that the EPR-Bohm paradox implies the non-existence of local hidden variables (LHVs), the cat paradox represents a macro-objectification problem and the tunneling time is an observer-dependent quantity whose definitions must be 'operational'. At the same time, according to the probabilistic approach (Accardi, Khrennikov, Philipp, Hess et al.) to Bell's inequality that underlies the EPR-Bohm experiments, its experimental violation means simply that it contains probability distributions associated with mutually incompatible statistical data. We argue that this approach must be extended onto micro-cat states because they describe, too, mutually incompatible statistical data. The current practice to interpret the squared modulus of a micro-cat state as the probability density should be recognized as erroneous. It is this practice that makes QM incompatible with classical physical theories and, thereby, makes the micro-world 'unspeakable'. The known 'operational' tunneling-time concepts, elaborated in line with this practice, are logically inconsistent. We argue that the TTP and the cat paradox must be solved at the level of single electrons and atoms, without resorting to environment and measurement contexts. We present a new model of the OCS and solve the TTP on its basis.