Proposition 5.15 from Atiyah-Macdonald how the previous lemma helps in concluding the coefficients are integral over the ideal

Question

In chapter 5 of Atiyah Macdonald

Lemma 5.14: Let $C$ is the integral closure of $A$ in $B$. Then the integral closure of ideal $\mathfrak{a}$ in $B$ is the $r(\mathfrak{a}^e)$ where $\mathfrak{a}^e$ is the extension of $\mathfrak{a}$ in $C$

Proposition 5.15: Let $A \subseteq B$ be integral domains, $A$ integrally closed, and let $x \in B$ be integral over an ideal $\mathfrak{a}$ of $A$. Then $x$ is algebraic over the field of fractions $K$ of $A$, and if its minimal polynomial over $K$ is $t^n + a_1 t^{n-1} + \cdots+ a_n$, then $a_1, \dots, a_n$ lie in $r(\mathfrak{a})$ (the radical of $\mathfrak{a}$).

Now in the proof of proposition lemma $x$ is algebraic over $K$. Let $L$ contain all the roots $x_1,\dots,x_n$ of the minimal polynomial of $x$. Each $x_i$ satisfies the same polynomial of integral dependence as $x$ does. So each $x_i$ is integral over $\mathfrak{a}$. The coefficients of the minimal polynomial are polynomials of $x_i$ over $K$.

Then how does Lemma 5.14 implies that the coefficients are integral over $\mathfrak{a}$

Answer 1

1. The elements of $B$ which are integral over an ideal $\alpha\subset A$ form an ideal.
2. $x\in L$ is integral over $\alpha$ iff $x\in r\left(\alpha^e\right)=r\left\langle{\sum a_iy_i \mid a_i\in \alpha,y_i\in L}\right\rangle$ by 5.14.
3. Ideals are closed under$\dots$
4. $a_i'$s are polynomials in$\dots$