This question was asked in my assignment on algebraic geometry and I need help in it.
Let A be a commutative ring. A multiplicatively closed subset S in A is called saturated if for all $a,b \in A$, $ab\in S$ implies that $a\in S$ and $b\in S$. Define $\bar{S} =${$ a\in A| \exists b\in A$ with $ab \in S$} to be saturation of S.
(a) Let A' be an ideal in A and let $S_{A'}=1+ A' = ${$1+a' | a\in A'$}. Then prove that S is multiplicatevely closed set in A.
I have done it.
(b) What is the saturation $\bar{S}_{A'}$ of the multiplicatively closed set $S_{A'}$?
Work: I think $S_{A'} = ${$a' \in A' | \exists b \in A' $ such that $a'b\in S_{A'} $}.
So, Saturated set is all $a'\in S_{A'}$ such that $ \exists b\in S_{A'}$ such that a'b =1+a'' $a'' \in S_{A'}$ . I don't think any further simplification is possible.
Am I right?
(c)Prove that $A'S_{A'}^{-1} A\subseteq M_{S_{A'}^{-1} A}$= Jacobson radical of $S_{A'}^{-1} A$.
I have to show that $A'S_{A'}^{-1} A $ is contained in every maximal ideal of $S_{A'}^{-1} A$.
Let there exists a maximal ideal M which doesn't contains $A'S_{A'}^{-1} A $. What would be the contradiction?
Kindly help.
Thanks!