Find the smallest non-commutative ring with unity. (By smallest it means it has the least cardinal.)
I tried rings of size 4 and I found no such ring.
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pardis
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Rumor has it that ${0}$ is a perfectly-defined commutative ring with unity XD – Hui Yu Dec 25 '13 at 16:28
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It's easy finding one with 16 elements. – egreg Dec 25 '13 at 16:33
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1@HuiYu but I nees a non commutative ring. – pardis Dec 25 '13 at 16:36
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By Wedderburn's little theorem, it must have zero divisors. I don't know how much that helps. – Ben Millwood Dec 25 '13 at 17:16
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2The smallest one is of cardinality $8$. – mathematics2x2life Dec 25 '13 at 23:01
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1What type of rings do you know that are not commutative? Thinking linear algebra might help. Now, how can you be sure you are dealing with only finitely many elements in your ring? – Chris Leary Jan 18 '14 at 20:46
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Let $M$ be a noncommutative monoid of order 3. Then the monoid ring $\mathbb{F}_2[M]$ with 8 elements is a minimal example. – Smiley1000 Apr 13 '24 at 10:13
4 Answers
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In an earlier version of this post I caused an accident by giving a wrong answer. Thanks to those who pointed out the error! Here is a little update:
The ring $M_2(\Bbb F_2)$ of $2 \times 2$-matrices with entries in $\Bbb F_2$ is a non-commutative ring with 16 elements, because $$\begin{pmatrix} 1 & 0 \\ 0 & 0\end{pmatrix}\begin{pmatrix} 0 & 1 \\ 0 & 0\end{pmatrix} = \begin{pmatrix} 0 & 1 \\ 0 & 0\end{pmatrix} \neq \begin{pmatrix} 0 & 0 \\ 0 & 0\end{pmatrix} = \begin{pmatrix} 0 & 1 \\ 0 & 0\end{pmatrix}\begin{pmatrix} 1 & 0 \\ 0 & 0\end{pmatrix}$$ It has a subring of order $8$, namely the upper triangular matrices which are non-commutative by the example above.
We show that $8$ is minimal:
Let $R$ be a finite ring with unity with $n$ elements.
We need two preliminaries:
1.) If the additive group is cyclic, then $R$ is commutative.
Proof: If the additive group of $R$ is cyclic, we can choose $1$ as a generator: If we have $0 = 1+\dots+1 = m \cdot 1$ for some $m\in \Bbb N$, then $0=(m\cdot 1) \cdot g = m\cdot(1\cdot g)=m\cdot g$ so the additive order of $1$ is maximal. Thus, the multiplication table of $R$ is determined by $1 \cdot 1 = 1$, showing $R \cong \Bbb Z/n \Bbb Z$ and $R$ is commutative.
2.) All rings of order $4$ are commutative. Proof: As a general result, all rings with order equal to a squared prime are commutative: Ring of order $p^2$ is commutative.
Thus any ring of order $1,2,3,5,6,7$ is ruled out by 1.) using the Sylow-theorems and $4$ is ruled out by 2.).
So $8$ is the minimal cardinality a non-commutative ring can have.
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2Could you explain why in the proof of 2), you say $R^{\times}$ is a group of order $n-1$? This would be true if all nonzero elements are units. But how do we know this a priori? (I am assuming that $R^{\times}$ stands for the group of units of $R$) – Prism Dec 25 '13 at 22:39
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There is a ring of order $8$. See. http://math.stackexchange.com/questions/618332/noncommutative-ring-with-eigth-elements-and-with-unity . – studying Dec 25 '13 at 22:55
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1This is incorrect, there is a subgroup even of $M_2(\mathbb{F}_2)$ which has smaller cardinality and is also a noncommutative ring with unity. Take the subring of upper triangular matrices of $M_2(\mathbb{F}_2)$. – mathematics2x2life Dec 25 '13 at 22:56
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I would only delete it if you cannot circumvent the error in the proof (which is the assumption of inverses in the ring). If it can be fixed, then the answer is fine then you just need to see if the ring has any subrings (which would be smaller) giving you the correct answer. – mathematics2x2life Dec 25 '13 at 23:03
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Well it is easy to show that 4 has no solution... So if we are sure about that example, the proof works. However, would you mind giving the proof? I really don't want to have any credits for it. – benh Dec 25 '13 at 23:05
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1If I were you, I would just delete your original text, making a note to the OP about the original error. Then you need only keep your first point about the additivity of $+$ to for $R$ to be commutative. This eliminates cases of order $1,2,3,4,5,6,7$. Finding the case of order $8$ and showing that it is the smallest is as simple as running through the construction of $M_2(\mathbb{F}_2)$, which has order $16$ and then explaining how to find the subring of upper triangular matrices of this ring and showing it has order $8$. Then your solution is correct and the ring is as it need be. – mathematics2x2life Dec 25 '13 at 23:41
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The proof of 1) is incomplete (it seems to assume that $1$ is a generator, why not another element?). – Martin Brandenburg Jan 18 '14 at 20:14
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@MartinBrandenburg Yes, you are right. Thank you for the note! I have added a proof that $1$ can indeed be chosen as a generator. – benh Jan 18 '14 at 20:37
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@benh How would 1) eliminate rings of order 6? There is a non-cyclic group of order 6. – P-addict Jan 31 '22 at 07:23
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When one thinks of a noncommutative ring with unity (at least I), tend to think of how I can create such a ring with $M_n(R)$, the ring of $n \times n$ matrices over the ring $R$. The smallest such ring you can create is $R=M_2(\mathbb{F}_2)$. Of course, $|R|=16$. Now it is a matter if you can find a even smaller ring than this. Of course, the subring of upper/lower triangular matrices of $R$ is a subring of order $8$ which is a noncommutative ring with unity. This is indeed the smallest such rings.
In fact, there is a noncommutative ring with unity of order $p^3$ for all primes $p$. See this paper for this and many other interesting/useful constructions.
Smiley1000
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mathematics2x2life
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Let $M$ be a noncommutative monoid of order 3. Then the monoid ring $\mathbb{F}_p[M]$ with $p^3$ elements is an example. – Smiley1000 Apr 13 '24 at 12:40
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Here is another approach: Let $R$ be a non-zero ring with identity detone its center by $Z(R)$. It can be easily proved that: If $\frac {R}{Z(R)}$ is a cyclic group (with additive structure) then $R$ is a commutative ring.
Now since $0,1 \in Z(R)$ then for any ring $R$ with $|R|< 8$ we have $|\frac{R}{Z(R)}| \leq 3$ which implies that $R$ is commutative (since any group of order $1,2$ or $3$ is cyclic) Therefore the smallest non-commutative with identity must have at least $8$ elements and there are such rings of course as it is mentioned in other solutions. The thing I would like to add is that there is no other example other than the ring of upper triangular matrices over $\Bbb{Z}_2$ scince we have the following theorem:
Let $p$ be a prime number and let $R$ be a non-commutative ring with identity and suppose $|R| = p^3$ then $R$ is isomorphic to the ring of upper triangular matrices over $\Bbb{Z}_p$.
Also I would like to add that in a similar way we can show that the smallest non-commutative ring (not necessary with identity) has order $4$. As an example consider $R = \{ \begin{pmatrix}a & b \\ 0 & 0 \end{pmatrix} \; | \; a, b \in \Bbb{Z}_2\}$.
Robert M
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As others have noted, the upper triangular $2\times 2$ matrices with entries in $\mathbb{F}_2$ is a smaller ring. Here is one way to see that it is the smallest: cyclicity of the additive group, as remarked above, rules out the orders $1,2,3,5,6,7$.
As for $4$, it is not hard to see that any ring with unity of order $p^2$ is commutative: either it is cyclic or the additive subgroup generated by $1$ is of order $p$; hence there is an element $x$ that is not in this subgroup, whence $R$ must be a quotient of $\mathbb{Z}/p[t]$ via $t\mapsto x$ since the $x$ element necessarily commutes with all elements of the additive subgroup $\langle 1\rangle$.
The Phenotype
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