The notion of common cause closedness of a classical, Kolmogorovian probability space with respect to a causal independence relation between the random events is defined, and propositions are presented that characterize common cause closedness for specific probability spaces. It is proved in particular that no probability space with a finite number of random events can contain common causes of all the correlations it predicts; however, it is demonstrated that probability spaces even with a finite number of random events can be common cause closed with respect to a causal independence relation that is stronger than logical independence. Furthermore it is shown that infinite, atomless probability spaces are always common cause closed in the strongest possible sense. Open problems concerning common cause closedness are formulated and the results are interpreted from the perspective of Reichenbach's Common Cause Principle.
The problem and informal review of resultsLet T be a theory formal part of which contains classical probability theory (S, p), where S is a Boolean algebra of sets representing random events (with Boolean operations ∪, ∩, ⊥) and where p is a probability measure possessing the standard properties. Typically, T predicts correlations between certain elements of S: if A, B ∈ S, then the quantity According to a classical tradition in philosophy of science, articulated especially by H. Reichenbach [16] and more recently by W. Salmon [19], correlations are always results of causal relations. This is the content of what became called Reichenbach's Common Cause Principle (RCCP). The principle asserts that if Corr(A, B) > 0 then either the events A, B stand in a direct causal relation responsible for the correlation, or there exists a third event C causally affecting both A and B, and it is this third event, the so-called (Reichenbachian) common cause, which brings about the correlation by being related to A, B in a specific way (see Definition 2). So formulated, Reichenbach's Common Cause Principle is a metaphysical claim about the causal structure of the World, its status has been investigated extensively in the literature, especially by Butterfield [2]; Cartwright [3]; Placek [9,10]; Salmon [17,18,19]; Sober [20,21,22] Van Fraassen [29,30,31].
Corr(A, B) . = p(A ∩ B) − p(A)p(B)Assuming that RCCP is valid, one is led to the question of whether our theories predicting probabilistic correlations can be causally rich enough to contain also the causes of the 1 correlations. The aim of the present paper is to formulate precisely and to investigate this question.According to RCCP, causal richness of a theory T would manifest in T 's being causally closed in the sense of being capable to explain the correlations by containing a common cause of every correlation between causally independent events A, B. More explicitly, if T is a theory containing probability theory (S, p) and if R ind (A, B) is a causal independence relation on S, then we call T common cause closed with respect to R ind , if for every p...
