On coproducts in varieties, quasivarieties and prevarieties

Abstract

If the free algebra F on one generator in a variety V of algebras (in the sense of universal algebra) has a subalgebra free on two generators, must it also have a subalgebra free on three generators? In general, no; but yes if F generates the variety V. Generalizing the argument, it is shown that if we are given an algebra and subalgebras, A0⊃eq ... ⊃eq An, in a prevariety (SP-closed class of algebras) P such that An generates P, and also subalgebras Bi⊂eq Ai-1 (0<i≤ n) such that for each i>0 the subalgebra of Ai-1 generated by Ai and Bi is their coproduct in P, then the subalgebra of A generated by B1, ..., Bn is the coproduct in P of these algebras. Some further results on coproducts are noted: If P satisfies the amalgamation property, one has the stronger "transitivity" statement: if A has a finite family of subalgebras (Bi)i∈ I such that the subalgebra of A generated by the Bi is their coproduct, and each Bi has a finite family of subalgebras (Cij)j∈ Ji with the same property, then the subalgebra of A generated by all the Cij is their coproduct. For P a residually small prevariety or an arbitrary quasivariety, relationships are proved between the least number of algebras needed to generate P as a prevariety or quasivariety, and behavior of the coproduct operation in P. It is shown by example that for B a subgroup of the group S = Sym() of all permutations of an infinite set , the group S need not have a subgroup isomorphic over B to the coproduct with amalgamation S B S. But under weak additional hypotheses on B, the question remains open.