Mathematics Asked by Perturbative on November 2, 2021
Suppose I have a finite-dimensional algebra $V$ of dimension $n$ over a field $mathbb{F}$. Then $V$ is an $n$-dimensional vector space and comes equipped with a bilinear product $phi : V times V to V$.
Suppose now that I have another finite-dimensional algebra $W$ of dimension $n$ over $mathbb{F}$ equipped with a bilinear product $psi: W times W to W$. Certainly, $V$ and $W$ are isomorphic as vector spaces but are they isomorphic as $mathbb{F}$-algebras? The question I’m really asking here is – Are all $n$-dimensional algebras over $mathbb{F}$ isomorphic to one another?
If the answer is yes, then this is my attempt at constructing such an isomorphism. Suppose I want to define an $mathbb{F}$-algebra isomorphism between $V$ and $W$.
To do this I’d need to define a map $f : V to W$ such that
If ${v_1, dots, v_n}$ and ${w_1, dots, w_n}$ are bases for $V$ and $W$ respectively then both $phi$ and $psi$ being bilinear maps are completely determined by their action on basis vectors $phi(v_i, v_j)$ and $psi(w_i, w_j)$ for $1 leq i, j, leq n$. It turns out that $$phi(v_i, v_j) = sum_{k=1}^n gamma_{i,j,k}v_k$$ and $$psi(v_i, v_j) = sum_{k=1}^n xi_{i,j,k}w_k$$ for some collection of scalars $gamma_{i,j,k}$ and $xi_{i,j,k}$ called structure coefficients. So then if both the $n^3$ collections of scalars $gamma_{i,j,k}$ and $xi_{i,j,k}$ are all non-zero then we can define $f : V to W$ by $$f(a_1v_1 + cdots + a_nv_n) = a_1 frac{xi_{i,j,1}}{gamma_{i,j,1}}w_1 + cdots + frac{xi_{i,j,n}}{gamma_{i,j,n}}w_n$$ and it will turn out that $f$ is the desired isomorphism of algebras as one can then check that $f(phi(v_i, v_j)) = psi(w_i, w_j) = psi(f(v_i), f(v_j))$ for all $i$ and $j$.
However what if it’s the case that for $phi$ some $gamma_{i, j, k}$ is zero and the corresponding $xi_{i, j, k}$ is non-zero? I don’t see any way to get an isomorphism in that case. Is it still possible to construct an isomorphism in that case?
Let $G$ and $H$ be finite groups of the same order, such that $G$ is abelian and $H$ is not.
Then the group rings $V = mathbb{F}G$ and $W = mathbb{F}H$ share the same dimension, but $V$ is commutative while $W$ is not.
Answered by mathmandan on November 2, 2021
There are several answers that point out why the statement of the question cannot be true, probably the simplest example being $Bbbk [x] / (x^2) notsimeq Bbbk times Bbbk$.
Classifying all finite-dimensional algebras of a given dimension is actually rather involved and very far from being just one algebra in each dimension.
Note that you can even come up with finite-dimensional noncommutative algebras. For example, from the quiver $$ bullet to bullet $$ you can build a noncommutative $3$-dimensional algebra with $Bbbk$-basis $e_1, e_2, alpha$, where
More generally, you can take the path algebra of any quiver and quotient by any two-sided ideal, which if you choose the ideal correctly will give a finite-dimensional algebra, which is usually non-commutative.
Finite-dimensional algebras can be studied via their categories of finite-dimensional modules (which in some cases can actually be described rather explicitly) and it turns out that the construction of finite-dimensional algebras via quivers gives all algebras up to Morita equivalence (i.e. using quivers you find the module categories of all finite-dimensional algebras).
Answered by Earthliŋ on November 2, 2021
In general, the answer is "no", even if one requires $V$ and $W$ to be fields.
For example, the rings $mathbb{Q}(sqrt{2})$ and $mathbb{Q}(sqrt{3})$ are two non-isomorphic fields that both have dimension $2$ over $mathbb{Q}$.
Answered by Geoffrey Trang on November 2, 2021
No. For example, $mathbf Q[sqrt n]$ are pairwise nonisomorphic (where $n$ ranges over squarefree integers distinct from $1$), but all have dimension $2$ over $mathbf Q$.
In general, if $K$ is not algebraically closed, then it admits a finite algebraic extension $Lsupsetneq K$, and then $L$ and $K^{[L:K]}$ have the same dimension and are not isomorphic.
Even if $K$ is algebraically closed, $K^4$, $M_{2times 2}(K)$ and $K[x]/(x^4)$ are non-isomorphic four-dimensional algebras over $K$.
Edit: as suggested in the comments, the counterexamples listed above are essentially all the counterexamples. More precisely, the answer is yes if you restrict yourself to finite-dimensional algebras over an algebraically closed field $k$ which are reduced (contain no nilpotents). In other words, the only such algebras are of the form $k^n$.
One can show that in this case, the algebra $A$ is semisimple (because it is Artinian and the Jacobson radical is zero), so by Wedderburn's theorem, it follows that it is a product of matrix rings over division algebras. Since there are no finite-dimensional division algebras over $k$ (because $k$ is algebraically closed), and no proper matrix ring is reduced (because it contains strictly upper triangular matrices, which are nilpotent), it follows that $Acong k^n$ for some $n$.
Answered by tomasz on November 2, 2021
Another very familiar example: $mathbb{C}neqmathbb{R}times mathbb{R}$. The complex numbers are a field, but $(1,0)(0,1)=(0,0)$ in $mathbb{R}times mathbb{R}$, so it has non-trivial zero-divisors.
Answered by tkf on November 2, 2021
They will not necessarily be isomorphic. Consider $V = mathbb F[x] / (x^n)$ and $W = mathbb F^n$ with componentwise multiplication.These are both $n$ dimensional $mathbb F$ algebras. However, $V$ contains a nilpotent element, $x$, whereas $W$ contains no nilpotent elements. Indeed, if we had an $mathbb F$-algebra homomorphism $f: V longrightarrow W$ then as $0 = f(x^n) = f(x)^n$, we'd need $f(x) = 0$ so any map between the two must have a nontrivial kernel.
Answered by paul blart math cop on November 2, 2021
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