Retrieving the Baby: Reichenbach's Principle, Bell Locality, and Selection Bias

TL;DR

This paper reexamines Bell's theorem, revealing that apparent violations of locality may be due to selection bias rather than true nonlocality, impacting interpretations of quantum correlations.

Contribution

It identifies selection bias as a key factor in Bell correlations, challenging the assumption that they necessarily imply nonlocality, and connects causal discovery principles to quantum phenomena.

Findings

Selection bias explains Bell correlations without nonlocality.

Bell's Factorizability may be violated due to collider bias.

Implications for causal modeling and quantum theory interpretations.

Abstract

In his late piece 'La nouvelle cuisine' (Bell 1990), John Bell describes the steps from an intuitive, informal principle of locality to a mathematical rule called Factorizability. This rule stipulates that when possible past causes are held fixed, the joint probabilities of outcomes of spacelike separated measurements, conditional on measurement settings, be the product of the local conditional probabilities individually. Bell shows that Factorizability conflicts with predictions of QM, predictions since confirmed in many experiments. However, Bell warns his readers that the steps leading to Factorizability should 'be viewed with the utmost suspicion'. He says that 'it is precisely in cleaning up intuitive ideas for mathematics that one is likely to throw the baby out with the bathwater' (1990, 239). Bell's suspicions were well-founded, for he himself misses an important baby. Here we retrieve and identify it: it is selection bias. We explain how failure of Factorizability may be regarded as a selection artefact, requiring no violation of locality in the intuitive, conceptual sense with which Bell begins his analysis. The argument begins with a central principle of causal discovery, Reichenbach's Principle of Common Cause (PCC). It is well known that correlations due to selection bias are not subject to PCC. Several writers have proposed that EPR-Bell correlations are also an exception to PCC, but it has not been noticed that they fall under this well-known exclusion. The point is relevant not only to the status of Bell nonlocality, but also for statistics and causal modeling. For these fields, the news is that selection effects play a ubiquitous role in quantum phenomena, in a form akin to collider bias.