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Let $K_1,\dotsc,K_n$ be finite fields and let $V$ be the variety of rings, generated by the $K_i$ (rings aren't necessarily unital). I want to figure out what $V$ looks like. By a theorem of Tarski, elements of $V$ are the quotients of subrings of direct products of (possibly infinite) families of the $K_i$. But what are these rings exactly?

One thing we can figure out are the possible characteristics of the elements of $V$. Since taking subrings and quotients decreases the characteristic and the characteristic of the product is the least common multiple of the characteristics of the factors, any ring in $V$ has a characteristic which is a squarefree integer, whose prime factors are among the characteristics of the $K_i$. On the other hand, not every such ring lives in $V$. For example, the multiplicative semigroup of any ring in $V$ must have finite exponent (since this is true for the products of the $K_i$), which means that things like polynomial rings over $K_i$ can't appear in $V$.

I tried looking at the simplest case where $V$ is generated by $\mathbb{Z}_2$, but I can't really picture what's going on. I have a feeling that in this case $V$ will be the class of Boolean rings, but I'm not even sure how to show this.

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    @ArturoMagidin Indeed, I was following Burris & Sankappanavar's attribution to Tarski. I agree that the result isn't very complicated.2012-05-27

2 Answers 2

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The following result should prove helpful, excerpted from Stanley Burris and John Lawrence, Term rewrite rules for finite fields (1991).

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    This was very useful. Tha$n$ks!2012-05-27
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Let $p$ be a prime. I claim that $V = \langle \mathbb{F}_p \rangle$ consists of those rings satisfying the identity $x^p =x$ for all elements $x$. For $p=2$ we recover boolean rings. [I have to admit that I only consider unital rings]

It is clear that every ring in $\langle \mathbb{F}_p \rangle$ satisfies the identity $x^p=x$. Now assume that $R$ is such a ring. By a Theorem of Herstein, $R$ is commutative. Clearly $x^2=0 \Rightarrow x=0$. This implies more generally, that $x^n=0 \Rightarrow x=0$ by an induction on $n$. Thus, $R$ is reduced, which means that the canonical map $R \to \prod_{\mathfrak{p}} R/\mathfrak{p}$, where the product ranges over all prime ideals of $R$, is injective. Now each $R/\mathfrak{p}$ is an integral domain satisfying the identity. One then sees that it has to be a field, actually of at most $p$ elements. Thus it has to be $\mathbb{F}_p$. This proves $R \in \langle \mathbb{F}_p \rangle$.

For $\langle \mathbb{F}_{p^d} \rangle$ similar arguments can be used, but it gets more complicated. Let me know if you are interested ...

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    This result is very cool! You shoulkd probably add "...consists of those *commutative* rings satisfying...". Why does a field that satisfies $x^p\!=\!x$ contain *at most* $p$ elements? *Exactly* $p$ elements? Could you please (when you find time - no hurry) prove the characterization of $\langle \mathbb{F}_{p^d}\rangle$? What rings does the variety $\langle \mathbb{Z}_n\rangle$ contain?2012-06-03