Prime avoidance lemma: Difference between revisions

Latest revision as of 16:32, 12 May 2008

This article is about the statement of a simple but indispensable lemma in commutative algebra
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Statement

Let $R$ be a commutative unital ring. Let $I_{1},I_{2},\ldots ,I_{n}$ and $J$ be ideals of $R$ , such that $J\subset \bigcup _{j}I_{j}$ . Then, if $R$ contains an infinite field or if at most two of the $I_{j}$ s are not prime, then $J$ is contained in one of the $I_{j}$ s.

Graded version

If $R$ is graded, and $J$ is generated by homogeneous elements of positive degree, then it suffices to assume that the homogeneous elements of $J$ are contained in $\bigcup _{j}I_{j}$ . However, we need to add the further assumption that all the $I_{j}$ s are prime.

Importance

The prime avoidance lemma is useful for establishing dichotomies; in particular, if $J$ is an ideal which is not cintained in any of the $I_{j}$ s, then $J$ has an element which is contained in none of the $I_{j}$ s.

Proof

If the ring contains an infinite field

In this case, the proof boils down to two observations:

Any ideal of the ring is also a vector space over the infinite field
A vector space over an infinite field cannot be expressed as a union of finitely many proper subspaces

If at most two of the ideals are not prime

The proof in this case proceeds by induction. The crucial ingredients to the proof are:

If two of the three elements $a,b,a+b$ belong to an ideal, so does the third (the fact that ideals are additive subgroups)
If, for a product $a_{1}a_{2}\ldots a_{r}$ , any $a_{i}$ belongs to an ideal, so does the product
If a product $a_{1}a_{2}\ldots a_{r}$ belongs to a prime ideal, then one of the $a_{i}$ s also belongs to that prime ideal

We now describe the proof by induction. The case $n=1$ requires no proof; the case $n=2$ follows from observation 1 (in other words, we only need to use that both are additive subgroups). Namely, suppose $J$ is not a subset of either $I_{1}$ or $I_{2}$ . Pick $x_{1}\in J\setminus I_{2}$ and $x_{2}\in J\setminus I_{1}$ . Clearly, $x_{1}\in I_{1},x_{2}\in I_{2}$ . Then $x_{1}+x_{2}$ is in $J$ , hence it must be inside $I_{1}$ or $I_{2}$ . This contradicts observation 1. Further information: Union of two subgroups is not a subgroup

For $n>2$ , we use induction. Suppose, without loss of generality, that $I_{n}$ is a prime ideal. Also assume without loss of generality that $J$ is not contained in the union of any proper subcollection of $I_{1},I_{2},\ldots ,I_{n}$ (otherwise, induction applies). Thus, we can pick $x_{i}\in J\setminus \bigcup _{j\neq i}I_{j}$ for each $i$ . Clearly $x_{i}\in I_{i}$ .

We now consider the element:

$x_{1}x_{2}\ldots x_{n-1}+x_{n}$

This is in $J$ , hence it must be in one of the $I_{i}$ s. We consider two cases:

The sum is in $I_{n}$ : Then, by observation 1, $x_{1}x_{2}\ldots x_{n-1}\in I_{n}$ . By observation 3, $x_{j}\in I_{n}$ for some $1\leq j\leq n-1$ , a contradiction.
The sum is in $I_{j}$ for some $1\leq j\leq n-1$ : Observation 2 tells us that $x_{1}x_{2}\ldots x_{n-1}\in I_{j}$ , so observation 1 yields $x_{n}\in I_{j}$ , a contradiction

In the graded case

In this case, the proof is the same, except that we can now get started on the proof only after raising $x_{1}x_{2}\ldots x_{n-1}$ and $x_{n}$ to positive powers so that the new terms have equal degrees, and can be added. In this case, we need all the $I_{j}$ s to be prime to ensure that even after taking powers, the elements $x_{i}$ still avoid the ideals $I_{j}$ , for $j\neq i$ .

@@ Line 1: / Line 1: @@
+{{indispensable lemma}}
 ==Statement==
@@ Line 5: / Line 7: @@
 ===Graded version===
-If <math>R</math> is [[graded ring|graded]], and <math>J</math> is generated by homogeneous elements of positive degree, then it suffices to assume that the homogeneous elements of <math>J</math> are contained in <math>\bigcup_j I_j</math>.
+If <math>R</math> is [[graded ring|graded]], and <math>J</math> is generated by homogeneous elements of positive degree, then it suffices to assume that the homogeneous elements of <math>J</math> are contained in <math>\bigcup_j I_j</math>. However, we need to add the further assumption that ''all'' the <math>I_j</math>s are prime.
 ==Importance==
 The prime avoidance lemma is useful for establishing dichotomies; in particular, if <math>J</math> is an ideal which is not cintained in any of the <math>I_j</math>s, then <math>J</math> has an element which is contained in ''none'' of the <math>I_j</math>s.
+==Proof==
+===If the ring contains an infinite field===
+In this case, the proof boils down to two observations:
+* Any ideal of the ring is also a vector space over the infinite field
+* A vector space over an infinite field cannot be expressed as a union of finitely many proper subspaces
+===If at most two of the ideals are not prime===
+The proof in  this case proceeds by induction. The crucial ingredients to the proof are:
+# If two of the three elements <math>a,b,a+b</math> belong to an ideal, so does the third (the fact that ideals are additive subgroups)
+# If, for a product <math>a_1a_2\ldots a_r</math>, any <math>a_i</math> belongs to an ideal, so does the product
+# If a product <math>a_1a_2 \ldots a_r</math> belongs to a [[prime ideal]], then one of the <math>a_i</math>s also belongs to that prime ideal
+We now describe the proof by induction. The case <math>n=1</math> requires no proof; the case <math>n=2</math> follows from observation 1 (in other words, we only need to use that both are additive subgroups). Namely, suppose <math>J</math> is not a subset of either <math>I_1</math> or <math>I_2</math>. Pick <math>x_1 \in J \setminus I_2</math> and <math>x_2 \in J \setminus I_1</math>. Clearly, <math>x_1 \in I_1, x_2 \in I_2</math>. Then <math>x_1 + x_2</math> is in <math>J</math>, hence it must be inside <math>I_1</math> or <math>I_2</math>. This contradicts observation 1. {{further|[[gp:Union of two subgroups is not a subgroup|Union of two subgroups is not a subgroup]]}}
+For <math>n > 2</math>, we use induction. Suppose, without loss of generality, that <math>I_n</math> is a [[prime ideal]]. Also assume without loss of generality that <math>J</math> is not contained in the union of any proper subcollection of <math>I_1, I_2, \ldots, I_n</math> (otherwise, induction applies). Thus, we can pick <math>x_i \in J \setminus \bigcup_{j \ne i} I_j</math> for each <math>i</math>. Clearly <math>x_i \in I_i</math>.
+We now consider the element:
+<math>x_1x_2 \ldots x_{n-1} + x_n</math>
+This is in <math>J</math>, hence it must be in one of the <math>I_i</math>s. We consider two cases:
+* The sum is in <math>I_n</math>: Then, by observation 1, <math>x_1x_2 \ldots x_{n-1} \in I_n</math>. By observation 3, <math>x_j \in I_n</math> for some <math>1 \le j \le n-1</math>, a contradiction.
+* The sum is in <math>I_j</math> for some <math>1 \le j \le n-1</math>: Observation 2 tells us that <math>x_1x_2\ldots x_{n-1} \in I_j</math>, so observation 1 yields <math>x_n \in I_j</math>, a contradiction
+===In the graded case===
+In this case, the proof is the same, except that we can now get started on the proof only after raising <math>x_1x_2\ldots x_{n-1}</math> and <math>x_n</math> to positive powers so that the new terms have equal degrees, and can be added. In this case, we need ''all'' the <math>I_j</math>s to be prime to ensure that even after taking powers, the elements <math>x_i</math> still ''avoid'' the ideals <math>I_j</math>, for <math>j \ne i</math>.