Atiyah-MacDonald Notes

Useful tricks:

If \({\mathfrak{m}}\) is maximal and \(I\neq {\mathfrak{m}}\), then \(\left\langle{I, \mgm}\right\rangle = R\) is the entire ring.

Operations on ideals:

\(I+J = \left\{{i+j{~\mathrel{\Big\vert}~}i\in I, j\in J}\right\}\) is the smallest ideal containing \(I\) and \(J\).
\(\sum_k I_k = \left\{{\sum_k i_k {~\mathrel{\Big\vert}~}i_k\in I_k}\right\}\) where all but finitely many terms in each sum are zero.
\(IJ = \left\langle{\left\{{ij}\right\}}\right\rangle = \left\{{\sum i_k j_k {~\mathrel{\Big\vert}~}i_k \in I, j_k\in J}\right\}\) is the ideal generated by all elementary product.
\(I^n = \left\{{\prod_{k\leq n}x_k {~\mathrel{\Big\vert}~}x_k\in I}\right\}\).
The distributive law \(a(b+c) = ab + ac\) for ideals does not generally hold. Instead there is a modular law: \begin{align*} a(b+c) = (a \cap b) + (a \cap c) \qquad \text{if } b \subseteq a \text{ or } c \subseteq a .\end{align*}
In general, \(a \cap b = ab \iff a+b = \left\langle{1}\right\rangle\).

Show that if \(I, J{~\trianglelefteq~}{\mathbf{Z}}\) then \(I \cap J = IJ \iff\) their generators are coprime.

Show that TFAE:

\(R\) is a field
\(R\) is simple as an \(R{\hbox{-}}\)module
Every ring morphism \(R\to S\) with \(S\) nonzero is injective and an isomorphism onto its image

Show that maximal implies prime but not conversely.
Show that inverse images of prime ideals are prime, but this fails for maximal ideals.
Show that every non-unit is contained in a maximal ideal.
Show that if \(I{~\trianglelefteq~}R\) and \(R\setminus I \subseteq R^{\times}\) then \(R\) is local and \(I\) is its maximal ideal.
Let \(I{~\trianglelefteq~}R\coloneqq k[x_1, \cdots, x_{n}]\) and be the ideal \(I= xR\), the polynomials with zero constant term. Show that \(I\) is maximal, but is not principal for \(n>1\) and in fact requires at least \(n\) generators.
Show that every nonzero prime in a PID is maximal.

The category of algebras over a ring \(A\):

Link to Diagram

900 AM Notes