Open problems in non-commutative algebra

Open problems in noncommutative algebra.

Everybody is invited to add, correct or edit (please try to provide references or attributions).

• Kurosh problem for division algebras.
• The Kolchin-Plotkin problem: Let ${\displaystyle D}$ be a division ring. Can any unipotent subgroup ${\displaystyle G\le G{L}_n(D)}$ be simultaneously triangularized?
  • True for algebras over a field of characteristic zero, or characteristic sufficiently large compared to ${\displaystyle n}$ (Mochizuki). Even under these assumptions, the problem is still open for unipotent submonoids.
  • True for algebras over a field of characteristic 2 (Derakhshan-Wigner; by Sizer, nilpotency implies triangularizability)
• Is there a finitely generated infinite dimensional algebra over a field, which is a division algebra? (Latyshev; Ikeda - an equivalent formulation in terms of maximal left ideals in free algebras)
• Is it true that every division algebra is either locally PI or contains a noncommutative free subalgebra? (Makar-Limanov; Stafford)
• Let ${\displaystyle D}$ be a division algebra over a field ${\displaystyle F}$, which does not contain a noncommutative free subalgebra. Is it possible that ${\displaystyle D{\otimes }_{F}K}$ contains a noncommutative free subalgebra (for some field extension ${\displaystyle K/F}$)? (Makar-Limanov. When 'division algebra' is replaced by 'nil algebra', an example exists by Smoktunowicz)
• Let ${\displaystyle D}$ be a division algebra algebraic over a central subfield ${\displaystyle F}$. Must ${\displaystyle M_n(D)}$ be algebraic over ${\displaystyle F}$?
• Is it true that a division ring that is finitely generated over its center and left algebraic over some subfield is finite-dimensional over its center? (Bell, Drensky, Sharifi - here)
• Let ${\displaystyle k}$ be an algebraically closed field and let ${\displaystyle A}$ be a finitely generated Noetherian ${\displaystyle k}$-algebra, which is a domain that does not satisfy a polynomial identity. Is it possible for the quotient division algebra of ${\displaystyle A}$ to be left algebraic over some subfield? (Bell, Drensky, Sharifi - here)
• If a division ring ${\displaystyle D}$ is left algebraic over a subfield ${\displaystyle K}$ must ${\displaystyle D}$ also be right algebraic over ${\displaystyle K}$? (Bell, Drensky, Sharifi - here. The authors believe this problem was already posed before.)
• Suppose that ${\displaystyle D_1\twoheadrightarrow D_2}$ are Ore domains. If ${\displaystyle Q(D_2)}$ contains a free subalgebra, does ${\displaystyle Q(D_1)}$ contain a free subalgebra? (Greenfeld)
• Is there a finitely generated infinite dimensional Lie algebra whose universal enveloping algebra localized at its center is a division algebra? (After Shestakov-Zelmanov, who gave a specific candidate)

• Jacobson's conjecture: In a left and right Noetherian ring, is the intersection of all powers of the Jacobson radical zero? (Jacobson, 1956. Counterexamples for one sided Noetherian rings found by Herstein and Jategaonkar.)
• Herstein's conjecture: If ${\displaystyle R}$ is a left Noetherian ring, and ${\displaystyle L\subseteq K\le R}$ are left ideals such that ${\displaystyle K}$ is nil over ${\displaystyle L}$, then ${\displaystyle K}$ is nilpotent over ${\displaystyle L}$.
  • True for PI-rings, or for rings Artinian on one side (and not necessarily Noetherian on the other), by Herstein
  • If ${\displaystyle L}$ is a two-sided ideal then an affirmative answer follows from Levitski's theorem
• When does the Jacobson radical of a two-sided Noetherian ring ${\displaystyle R}$ satisfy the Artin-Rees property? In particular, does this occur if either ${\displaystyle R/J(R)}$ is Artinian or ${\displaystyle R}$ is prime? (Goodearl-Warfield)
• Can every right ideal in a simple Noetherian ring be generated by two elements?
  • Holds for the Weyl algebras (Stafford)
• Let ${\displaystyle R}$ be a finitely generated Noetherian algebra over a field ${\displaystyle F}$ of characteristic zero and le ${\displaystyle K/F}$ be a field extension. Must ${\displaystyle R{\otimes }_{F}K}$ be Noetherian?
  • True for PI-algebras (arbitrary characteristic; by Small)
  • True for ${\displaystyle \mathbb{Z}}$-graded algebras with finite dimensional homogeneous components (de Jong)
  • Counterexample in positive characteristic exist (Resco-Small) and in characteristic zero (Passman-Small, '23). It is open if a finitely presented example exists (Goodearl-Warfield)
  • True for countably generated algebras over uncountable algebraically closed fields (Bell)
  • There exist examples in arbitrary characteristic which are graded, Noetherian but non-Noetherian after an extension of the base field with a Noetherian commutative ring (Rogalski, "Generic noncommutative surfaces", Adv. Math. 2005)

• Must an affine Noetherian algebra be finitely presented? (Bergman, GK dim of factor rings; repeated by McConnell-Stafford. For PI algebras: Bell, 2004)
  • False for non-PI rings (Resco-Small, in characteristic p>0). To the best of our knowledge, this is still open for algebras over a field of characteristic zero (good candidate: the algebra from the aforementioned Passman-Small paper).
  • True for graded algebras (Lewin, Theorem 17)
  • True for PI algebras (Belov)

• Does a two-sided Noetherian ring satisfy DCC(primes)? Does every prime have finite height? Does every non-minimal prime contain a prime of height one? (Goodearl-Warfield)
  • True for PI-rings
• In a two-sided Noetherian ring, are all chains of ideals countable? In a finitely generated module over a Noetherian ring, are all chains of submodules countable? (Goodearl-Warfield)
  • True for commutative rings (Bass); false for one-sided Noetherian rings (Jategaonkar)
• In a two-sided Noetherian ring ${\displaystyle R}$, is the classical Krull dimension of ${\displaystyle R[x]}$ equal to the classical Krull dimension of ${\displaystyle R}$ plus one?
  • Well known for commutative rings

• If ${\displaystyle R}$ is a two-sided Noetherian ring of finite global dimension and ${\displaystyle R/J(R)}$ is simple Artinian, is ${\displaystyle R}$ prime? (Goodearl-Warfield)
• If ${\displaystyle R}$ is a two-sided Noetherian ring of finite global dimension and ${\displaystyle R/J(R)}$ is a division ring, is ${\displaystyle R}$ a domain? (Goodearl-Warfield)
• Is the Krull dimension of ${\displaystyle R}$ bounded from above by its global dimension, for any two-sided Noetherian ring of finite global dimension? (Goodearl-Warfield)
  • For commutative rings, equality holds. Not true for one-sided Noetherian rings (Jategaonkar's example)

• Is the right global dimension of a two-sided Noetherian ring equal to the supremum of the projective dimensions of simple right modules? (Goodearl-Warfield)
  • True for commutative rings, or for rings finite module over their Noetherian centers. False for one-sided Noetherian rings (by Fields)
• If all simple right modules of a two-sided Noetherian ring have finite projective dimension, do all f.g. right modules have finite projective dinension? (Goodearl-Warfield)
  • True for commutative rings (Bass and Murthy) and module finite algebras over commutative Noetherian rings.

• Do the right and left Krull dimensions of a two-sided Noetherian ring coincide? Of any Noetherian bimodule? (Goodearl-Warfield)

• Is the GK-dimension exact for finitely generated over (affine) Noetherian algebras?
  • True if there is a filtration such that the associated graded is Noetherian (McConnell-Robson, 3.11)
  • True for affine Noetherian PI-algebras (Lenagan)
  • False for non-Noetherian algebras (even PI; Bergman)

• Is there an infinite dimensional Lie algebra ${\displaystyle L}$ whose universal enveloping algebra is Noetherian? (Sierra-Walton: the universal enveloping algebra of the Witt algebra is not Noetherian; hence for ${\displaystyle \mathbb{Z}}$-graded simple Lie algebras of polynomial growth. For a group algebra counterpart of this question, see here.)
• Conjecture: the universal enveloping algebras of the Witt (and positive Witt) algebras satisfy ACC(ideals) (Petukhov-Sierra)
• Does the universal enveloping algebra of a loop algebra satisfy ACC(ideals)? (Sierra, Seattle '22)

• Does there exist a simple nil algebra over an uncountable field?
  • An example over a countable field exists, solving a question of Kaplansky (Smoktunowicz)
• Is there a finitely generated graded-nil ring (i.e. every homogeneous element is nilpotent), generated in degree 1, which contains a noncommutative free subalgebra? (Bell-Greenfeld. Examples not generated in degree 1 exist)
• Is there a graded, f.g. in degree 1 algebra all of whose homogeneous components satisfy the identity ${\displaystyle x^n=0}$ for some ${\displaystyle n}$?
  • Without the generation in degree 1 assumption -- examples exist

• Does there exist an infinite dimensional finitely presented nil algebra? (Attributed to Ufnarovskii, repeated by many others)
• Is there a nil, non-nilpotent algebra whose adjoint group is finitely generated? (Amberg, Kazarin, Sysak)

• Köthe conjecture
• Let ${\displaystyle R}$ be a finitely generated nil algebra. Is ${\displaystyle gr(R)}$ Jacobson radical? (Riley, 2001)
  • True over uncountable fields (Alon Regev)
  • ${\displaystyle gr(R)}$ need not be nil even if ${\displaystyle R}$ is (Smoktunowicz)
• Suppose ${\displaystyle R}$ is a nil ${\displaystyle F}$-algebra and ${\displaystyle K/F}$ is a finite field extension. Must ${\displaystyle R{\otimes }_{F}K}$ be nil? Moreover, is this question equivalent to the Köthe conjecture? (Smoktunowicz)
• Let ${\displaystyle R}$ be a ring and deonte by ${\displaystyle N}$ the sum of nil ideals of ${\displaystyle R}$, and by ${\displaystyle \tilde{N}}$the sum of left nil ideals. Does ${\displaystyle N=0}$ imply ${\displaystyle {\displaystyle \bigcap _{i=1}^{\mathrm{\infty }}}{\tilde{N}}^i=0}$? Does ${\displaystyle {\displaystyle \bigcap _{i=1}^{\mathrm{\infty }}}{\tilde{N}}^i=0}$ imply ${\displaystyle N=\tilde{N}}$? (Rowen, 1989. Note that the conjunction of these questions implies an affirmative answer to the Köthe conjecture.)

• Let ${\displaystyle F}$ be a field of characteristic zero and let ${\displaystyle R}$ be an ${\displaystyle F}$-algebra and ${\displaystyle \delta :R\to R}$ a locally nilpotent derivation. Is ${\displaystyle J(R[X;\delta ])=I[X]}$ for some nil ideal ${\displaystyle I◃R}$?(Smoktunowicz, here)
  • True for fields of positive characteristic (Smoktunowicz)
• Let ${\displaystyle R}$ be an algebra without non-zero nil ideals, and let ${\displaystyle \delta :R\to R}$ be a derivation. Must ${\displaystyle R[X;\delta ]}$ be semiprimitive? (Smoktunowicz, here)

• Does the universal enveloping algebra of the Witt algebra satisfy ACC(primes)? (Iyudu-Sierra: it does satisfy ACC(completely primes).)
• Is it true in any ring ${\displaystyle R}$ that for any pair of primes ${\displaystyle P⊊Q◃R}$ there exist primes: ${\displaystyle P\subseteq P^{\prime }⊊Q^{\prime }\subseteq Q}$ such that there is no intermediate prime between ${\displaystyle P^{\prime }⊊Q^{\prime }}$? (See here for some background and examples. True for PI-rings.)
• Characterize partially ordered sets which can be realized as ${\displaystyle Spec(R)}$ for some (not necessarily commutative) ring ${\displaystyle R}$. (See here for some background and examples.) Is the ordered set ${\displaystyle ([0,1],\le )}$ isomorphic to some ${\displaystyle (Spec(R),\subseteq )}$?

• Does DME hold for (complex) affine Noetherian Hopf algebras of finite GK-dimension? (Bell, Seattle '22)
• Does DME hold for (complex) affine Noetherian twisted homogeneous coordinate rings? (Bell, Seattle '22)
• Does DME hold for (complex) affine prime Noetherian algebras of GK-dimension at most 3? (Bell, Seattle '22)

• Kurosh problem for simple algebras: Is there a finitely generated, infinite dimensional algebraic simple algebra? (Attributed by Smoktunowicz to Small)
• Is there an idempotent ring ${\displaystyle R}$ (not necessarily unital) which is not generated by one element as a bimodule over itself, namely, ${\displaystyle R\ne RaR}$ for any ${\displaystyle a\in R}$? (Monod, Ozawa, Thom)
  • True for semigroup algebras (Bergman/Smoktunowicz)
• Let ${\displaystyle R}$ be a principal ideal domain; if the units together with ${\displaystyle 0}$ form a field ${\displaystyle k}$, is ${\displaystyle R}$ necessarily a polynomial ring over ${\displaystyle k}$? (A. Hausknecht, appears in Cohn's book)
• Is the notion of left integral extension transitive? (If every element of a ring ${\displaystyle B}$ is left integral over a subring ${\displaystyle A}$, then ${\displaystyle B}$ is called left integral over ${\displaystyle A}$. Appears in Cohn's book.)
• Which commutative rings occur as centers of Sylvester domains? Is the center of a Sylvester domain necessarily integrally closed? (Appears in Cohn's book)
• An ${\displaystyle O}$-ring is a unital ring in which every element other than the identity is a left and right zero divisor (example: a product of copies of the field with two elements). Is there a noncommutative ${\displaystyle O}$-ring?
  • An ${\displaystyle O}$-ring must be semiprime, but if it is prime, it is just ${\displaystyle \mathbb{Z}/2\mathbb{Z}}$. The question is equivalent to the question of whether any homomorphic image of an ${\displaystyle O}$-ring is again an ${\displaystyle O}$-ring. For resources and details, see here.
• Is there a finitely generated ring ${\displaystyle R}$ such that ${\displaystyle R\cong R\times R}$? (D. Osin, 2020, here. The group-theoretic counterpart has an affirmative answer, by Jones.)
• Is it true that every nilpotent matrix over a simple ring with unity can be presented as a commutator? (See here.)
• Is there a simple ring in which not every sum of commutators is a single commutator? In which not every sum of commutators is a sum of less than ${\displaystyle n}$ commutators, for given (or for all) ${\displaystyle n}$? (A positive answer to the latter would yield a counterexample to Question 6 here.)
• Is every prime ring an essential subring of a primitive ring? (Rowen, 1977, here. True by Goodearl's theorem for rings with a trivial center.)

• Let ${\displaystyle R}$ be a free ${\displaystyle k}$-algebra and ${\displaystyle \hat{R}}$ its completion by power series. Given ${\displaystyle \alpha \in k}$, denote by ${\displaystyle C,C^{\prime }}$ its centralizers in ${\displaystyle R}$,${\displaystyle \hat{R}}$ respectively. Is ${\displaystyle C^{\prime }}$ the closure of ${\displaystyle C}$ in ${\displaystyle \hat{R}}$? (Bergman)
• Is every retract of a free algebra free? (A retract is a subring, which is also a homomorphic image of the containing ring under a homomorphism fixing the former. Attributed to Clark in Cohn's book)
• Is any endomorphism of a free algebra, carrying any primitive element to a primitive element necessarily an automorphism? (A primitive element is an element participating in a free basis. See here)
• Is the intersection of two retracts of a free algebra ${\displaystyle R}$ again a retract of ${\displaystyle R}$? (See here. Bergman proved the analogous result for free groups.)
• Let ${\displaystyle R}$ be a free algebra and ${\displaystyle \hat{R}}$ its power series completion. If an element of ${\displaystyle R}$ is a square in ${\displaystyle \hat{R}}$, is it associated (in ${\displaystyle \hat{R}}$) to the square of an element of ${\displaystyle R}$? (Two elements are associated if each one of them is a left and right product of the other by invertible elements. Bergman, appears in Cohn's book)
• Let ${\displaystyle R}$ be an algebra such that ${\displaystyle M_n(R)}$ contains a (noncommutative) free subalgebra. Must ${\displaystyle R}$ contain a free subalgebra? Same question for graded algebras. Seems unclear even for monomial algebras (Greenfeld)

• Must a central division algebra of prime degree be cyclic?
• See this paper for a specialized list of problems on crossed product, exponent, the Brauer group, Brauer dimension and more.

• Is there an asymptotic characterization of growth functions of finitely generated algebras?
  • There exists a characterization using discrete derivatives here (Bell-Zelmanov)
• Characterize growth rates of Lie algebras. Is any increasing exponentially bounded function equivalent to the growth of some finitely generated Lie algebra?
• Characterize growth rates of Hopf algebras (proposed by J. J. Zhang in Banff, 2022).

• Is the growth function of any algebra equivalent to the growth function of some primitive algebra? Or a nil algebra? (Zelmanov. Impossible if one restricts to graded primitive algebras.)

• Is there a finitely generated nil algebra with polynomially bounded growth over an arbitrary field?
  • Examples over countable fields exist, of GK-dim at most 3 (finite GK-dim by Lenagan-Smoktunowicz, and bound improved to 3 by Lenagan-Smoktunowicz-Young)
• Is there a finitely generated (even: graded, Noetherian, Artin-Schelter regular) domain of non-integral GK-dimension?
• Is there a finitely generated domain whose growth function is super-polynomial but asymptotically slower than ${\displaystyle \exp (\sqrt{n})}$?
  • For an example with growth ${\displaystyle \exp (\sqrt{n})}$, consider the universal enveloping algebra of any finitely generated Lie algebra of linear growth, by M. Smith.

• Is there an affine graded Noetherian algebra of super-polynomial growth? (Stephenson-Zhang, who proved it must be subexponential)

• Is the GK-dimension of the associated graded algebra of every Jacobi algebra with respect to the descending filtration of powers of the Jacobson radical, an integer? Brown--Wemyss, 2025

• Let ${\displaystyle R}$ be a finitely generated prime Noetherian algebra of GK-dimension 2. Must ${\displaystyle R}$ be either primitive or PI? (Braun, Small)
• Let ${\displaystyle R}$ be a finitely generated prime algebra of quadratic growth. Must ${\displaystyle R}$ have bounded degrees of matrix images?
  • The answer is positive for monomial algebras; negative if growth restriction is relaxed to having GK-dim = 2 (Bell-Smoktunowicz). Unknown for finitely generated prime Noetherian algebras of GK-dim 2.
• Let ${\displaystyle R}$ be a finitely generated prime semiprimitive algebra of GK-dimension 2 (or: quadratic growth). Must ${\displaystyle R}$ be either primitive or PI? (Smoktunowicz, Vishne)
  • True for monomial algebras, without growth restrictions (Okn'inski)
• Let ${\displaystyle R}$ be a finitely generated algebra of quadratic growth. Must ${\displaystyle R}$ have finite classical Krull dimension?
  • False true for algebras of GK-dimension 2 (Bell)
  • True for graded algebras generated in degree 1, having quadratic growth (Greenfeld-Smoktunowicz-Leroy-Ziembowski)
  • False for graded (even monomial) algebras of GK-dimension 2 (Greenfeld)
• Is there a graded just infinite (also called projectively simple) algebra without a finitely generated module of GK-dimension 1? (Reichstein-Rogalski-Zhang. By Small-Zelmanov there exist graded, just infinite algebras without point modules). Related question: can a finitely generated infinite-dimensional nil graded algebra have a finitely generated infinite-dimensional module of finite width?
• Is there a non-PI finitely generated domain of GK-dimension 2 (or: less than 3) over a finite field? (Smoktunowicz)
• Conjecture: A non-PI, finitely generated domain of quadratic growth over an algebraically closed field of characteristic zero, which has a non-zero locally nilpotent derivation is Noetherian (Bell-Smoktunowicz, here).

• Let ${\displaystyle R}$ be a connected, nonnegatively graded algebra (resp. Hopf algebra) over a field. Suppose either that ${\displaystyle R}$ is finitely presented or that ${\displaystyle gl.dim(R)<\mathrm{\infty }}$. Is it true that ${\displaystyle R}$ must have either subexponential or polynomial growth, or else contain a free subalgebra (resp. Hopf subalgebra) on two homogeneous generators? (Anick)
  • Finitely presented connected graded algebras with sufficiently sparse relators contain a free subalgebra (Smoktunowicz)
• Suppose ${\displaystyle R}$ is a connected graded algebra with polynomial growth and with ${\displaystyle gl.dim(R)=d<\mathrm{\infty }}$. Then the Hilbert series of ${\displaystyle R}$ is given by ${\displaystyle {\displaystyle \prod _{i=1}^d}\frac{1}{1-z^{e_i}}}$ for some positive integers ${\displaystyle e_1,\dots ,e_d}$ (Anick).
  • Holds for commutative algebras, enveloping algebras, monomial algebras and Noetherian PI-algebras. For details, see here.

• Classify noncommutative projective surfaces (Artin's proposed classification). Related problems: [1]
• Let ${\displaystyle A}$ be a connected graded finitely generated complex domain of GK-dimension 3 and suppose that ${\displaystyle A}$ has a nonzero locally nilpotent derivation. Then ${\displaystyle Q_{gr}(A)\cong D[t,t^{-1};\sigma ]}$ for some division algebra ${\displaystyle D}$ and ${\displaystyle \sigma \in Aut(D)}$. Can one describe the class of division algebras ${\displaystyle D}$ (or pairs ${\displaystyle (D,\sigma )}$) which can occur under these hypotheses? (Bell-Smoktunowicz, here)

• Dixmier's conjecture
  • Stably equivalent to the Jacobian conjecture (Tsuchimoto; Belov-Kontsevich)
• The weak Gelfand-Kirillov conjecture: is the quotient division algebra of the universal enveloping algebra of an algebraic, finite-dimensional (complex) Lie algebra isomorphic, up to scalar extension, to the quotient division algebra of a Weyl algebr over a field of rational functions?
  • True, even without scalar extension, for solvable Lie algebras and semisimple of type ${\displaystyle A_n}$
  • Without scalar extension (original Gelfand-Kirillov conjecture) - false, by Alev-Ooms-Van den Bergh.
• Let ${\displaystyle k}$ be an algebraically closed field of characteristic 0 and let ${\displaystyle A}$ be a finitely generated ${\displaystyle k}$-algebra that is a domain of quadratic growth that is birationally isomorphic to a ring of differential operators on an affine curve over ${\displaystyle k}$. Does there exist a finitely generated subalgebra ${\displaystyle B\subseteq Q(A)}$ of quadratic growth that contains ${\displaystyle A}$ and has the property that the Weyl algebra is a subalgebra of ${\displaystyle B}$? (Bell-Smoktunowicz, here)
  • True if ${\displaystyle A}$ is a (non-PI) finitely generated domain having a non-zero locally nilpotent derivation (Bell-Smoktunowicz)
• Can one classify all pairs ${\displaystyle (X,Y)}$ of smooth affine complex curves such that the ring of differential operators ${\displaystyle D(X)}$ is isomorphic to a subalgebra of the quotient division ring of ${\displaystyle D(Y)}$? Conjecture: in such a case, the genus of ${\displaystyle X}$ is less than or equal to the genus of ${\displaystyle Y}$. (Bell-Smoktunowicz, here)
  • If ${\displaystyle X}$ is a smooth curve over an algebraically closed field of characteristic zero, then the quotient division ring of ${\displaystyle D(X)}$ always contains a copy of the Weyl algebra.

• Must a Noetherian PI-algebra over a field be representable? (Anan'in proved for affine Noetherian PI-algebras. In the non-affine case, seems to be open even for left and right Noetherian PI-algebras, and for Artinian PI-algebras.)
• Is every algebra over a field, that is a finitely generated module over its center, weakly representable (namely embeddable into a matrix ring over a commutative ring)? (Rowen, Small, J. Alg. 2015)
• Is every finitely presented PI-algebra over a field representable?
  • No (Irving)
• Suppose a commutative ring ${\displaystyle C}$ contains a field and ${\displaystyle M}$ is a finitely generated ${\displaystyle C}$-module. Is ${\displaystyle En{d}_{C}M}$ weakly representable? (Bergman, Isr. J. Math. 1970)

• Kaplansky's conjectures
  • A counterexample to the unit conjecture was announced by Giles Gardam (Feb '21)
• Let ${\displaystyle G}$ be a right-ordered group. Does its group algebra over a field ${\displaystyle F[G]}$ embed into a division ring?
• Let ${\displaystyle G}$ be a group. Is ${\displaystyle \mathbb{Q}[G]}$ semiprimitive?
  • ${\displaystyle ℂ[G]}$ is semiprimitive. For many refinements and variations on this question, as well as partial known results, see here (Passman).
• Let ${\displaystyle G}$ be a group whose group algebra ${\displaystyle F[G]}$ over some field is Noetherian. Does it follow that ${\displaystyle G}$ is virtually polycyclic?
  • The converse is well known. It is known that if the group algebra is Noetherian, then the underlying group is at least amenable. See discussion here.
  • Ivanov gave an example of a Noetherian group whose group ring over an arbitrary ring is not Noetherian, solving a question of P. Hall. See here.

• Let ${\displaystyle F}$ be a field and let ${\displaystyle f,g,h,u\in F[x]}$ be irreducible polynomials of degree 2. The algebra:

${\displaystyle D=F⟨a,b,c,d⟩/⟨f(a),g(b),h(c),u(d),a+b+c+d⟩}$ has quadratic growth (in fact, ${\displaystyle 2n+1}$ monomials of degree ${\displaystyle n}$). Is ${\displaystyle D}$ a domain? (Bergman, the diamond lemma paper.) Note that if true, this might give an example of a non-PI domain of GK-dimension 2 over a finite field.

• See the Dniester "notebook".

• Let ${\displaystyle A}$ be a simple Poisson algebra. To which extent does the Lie algebra ${\displaystyle \{A,A\}}$ determine ${\displaystyle A}$?