Invertible module

A module $ M $ over a commutative ring $ A $ for which there exists an $ A $- module $ N $ such that $ M \otimes N $ is isomorphic to $ A $( as an isomorphism of $ A $- modules). A module $ M $ is invertible if and only if it is finitely generated, projective and has rank 1 over every prime ideal of $ A $. The classes of isomorphic invertible modules form the Picard group of the ring $ A $; the operation in this group is induced by the tensor product of modules, and the identity element is the class of the module $ A $. In the non-commutative case, an $ ( A , B ) $- bimodule, where $ A $ and $ B $ are associative rings, is called invertible if there exists a $ ( B , A ) $- bimodule $ N $ such that

$$ M \otimes _ {B} N \simeq A \ \ \textrm{ and } \ \ N \otimes _ {A} M \simeq B . $$

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Comments

The Picard group of a non-commutative ring is a useful invariant in the theory of orders and $ G $- modules, cf. [a1], [a2].

References