Linearly disjoint

In mathematics, algebras A, B over a field k inside some field extension ${\displaystyle \mathrm{\Omega }}$ of k are said to be linearly disjoint over k if the following equivalent conditions are met:

• (i) The map ${\displaystyle A{\otimes }_{k}B\to AB}$ induced by ${\displaystyle (x,y)\mapsto xy}$ is injective.
• (ii) Any k-basis of A remains linearly independent over B.
• (iii) If ${\displaystyle u_i,v_j}$ are k-bases for A, B, then the products ${\displaystyle u_i{v}_j}$ are linearly independent over k.

Note that, since every subalgebra of ${\displaystyle \mathrm{\Omega }}$ is a domain, (i) implies ${\displaystyle A{\otimes }_{k}B}$ is a domain (in particular reduced). Conversely if A and B are fields and either A or B is an algebraic extension of k and ${\displaystyle A{\otimes }_{k}B}$ is a domain then it is a field and A and B are linearly disjoint. However, there are examples where ${\displaystyle A{\otimes }_{k}B}$ is a domain but A and B are not linearly disjoint: for example, A = B = k(t), the field of rational functions over k.

One also has: A, B are linearly disjoint over k if and only if subfields of ${\displaystyle \mathrm{\Omega }}$ generated by ${\displaystyle A,B}$, resp. are linearly disjoint over k. (cf. Tensor product of fields)

Suppose A, B are linearly disjoint over k. If ${\displaystyle A^{\prime }\subset A}$, ${\displaystyle B^{\prime }\subset B}$ are subalgebras, then ${\displaystyle A^{\prime }}$ and ${\displaystyle B^{\prime }}$ are linearly disjoint over k. Conversely, if any finitely generated subalgebras of algebras A, B are linearly disjoint, then A, B are linearly disjoint (since the condition involves only finite sets of elements.)

• Tensor product of fields

• P.M. Cohn (2003). Basic algebra

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