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Here are two questions about finitely generated and finitely presented groups (FP):

  1. Is there an example of an FP group that does not admit a homomorphism to $\operatorname{GL}(n,C)$ with trivial kernel for any $n$?

The second question is modified according to the suggestion of Greg below.

  1. For which $n$ given two subgroups of $\operatorname{GL}(n,C)$ generated by explicit lists of matrices, together with finite lists of relations and the promise that they are sufficient, is there an algorithm to determine if they are isomorphic as groups?"

In both cases we don't impose any conidtion on the group (apart from being FP), in particular it need not be discrete in $\operatorname{GL}(n,C)$.

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Here is a more complete picture to go with David's and Richard's answers.

It is a theorem of Malcev that a finitely presented group $G$ is residually linear if and only if it is residually finite. The proof is very intuitive: The equations for a matrix representation of $G$ are algebraic, so there is an algebraic solution if there is any solution. Then you can reduce the field of the solution to a finite field, as long as you avoid all primes that occur in the denominators of the matrices.

The same proof shows that $G$ has no non-trivial linear representations if and only if it has no subgroups of finite index. So Higman's group has this property.

A refined question is to find a finitely presented group which is residually finite, but nonetheless isn't "linear" in the sense of having a single faithful finite-dimensional representation. It seems that the automorphism group of a finitely generated free group, $\text{Aut}(F_n)$, is an example. Nielsen found a finite presentation for this group, it is also known to be residually finite, yet Formanek and Procesi showed that it is not linear when $n \ge 3$. More recently, Druţu and Sapir found an example with two generators and one relator.

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  • $\begingroup$ Greg, thank you for the answer and for the comment to the second part of my question! I guess, I should modify it. I was having in mind the following: It is said that 3-dimensional manifolds are algorithmically recognisible, while 4-manfiolds not, beacause for FPFG groups there is no algorithm to recognise them. So maybe I should reformulate the question like this: Is there an algorithm that recognise linear FPRG groups (i.e. decides for any two such groups if they are isomorphic)? Will this question make more sense? If yes, I will reformulated it like this. $\endgroup$ Dec 23, 2009 at 20:11
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    $\begingroup$ Provided you are given the faithful linear representations, not just a promise that they exist, the question could be okay. I.e., "Given two subgroups of GL(n,Q) generated by explicit lists of matrices, together with lists of relations and the promise that they are sufficient, is there an algorithm to determine if they are isomorphic as groups?" Note that for closed hyperbolic 3-manifolds, Mostow rigidity is available, which gives much more information than just linearity. $\endgroup$ Dec 23, 2009 at 20:19
  • $\begingroup$ Greg, may I ask you one more thing? Is there any good exposition, that decribes the result "$G$ is residually linear if and only if it is residually finite". I like a lot the idea of the proof that you have descirbed, but also want to see it written in more detailes. $\endgroup$ Dec 23, 2009 at 23:00
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    $\begingroup$ A proof of Malcev's theorem is in a book by Merzlyakov "Рациональные группы" (in Russian, the title translates as "Rational groups"). I do not think there is English translation, so probably Malcev's original paper is the most accessible reference. $\endgroup$ Dec 24, 2009 at 4:43
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    $\begingroup$ This Malcev's theorem is explained (nicely, in context of subsequent developments) at least in two places: B.A.F. Wehrfritz, Infinite Linear Groups, Springer, 1973 and A.E. Zalesskii, Linear groups, Russ. Math. Surv. 36 (1981), N5, 63-128. $\endgroup$ Dec 28, 2009 at 12:59
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The following counterexample is due to Higman; I learned about it from Terry Tao's blog.

Consider the group with generators $a$, $b$, $c$ and $d$, and relations $ab=b^2a$, $bc=c^2 b$, $cd=d^2c$ and $da=a^2d$. This group is infinite (in fact, the subgroup generated by $a$ and $c$ is free), but it has no nontrivial map to $GL_{n}(\mathbb{C})$.

See Terry's post, especially Remark 2, for a very nice exposition of this fact.

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Another nice example is the Baumslag-Solitar group $\langle a,b \ | \ ab^2a^{-1} = b^3 \rangle$, which isn't hopfian, and so isn't residually finite, and so can't be linear.

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I just wanted to make a comment on Mal'cev's theorem (if I could leave this as a comment, I would).

Mal'cev's paper is a great exposition of the theorem, as well as a lot of other related material, all written in a basic yet enlightening style.

Also, if you know a little commutative algebra (as in the Nullstellensatz, the one given in Eisenbud pg. 132), there is quick and easy proof of Mal'cev's theorem. I could sketch it if necessary, but I am right now in the process of LaTeX-ing it, so I'll probably just come back and post a link.

Steve

EDIT - a sketch of the argument: Mal'cev's theorem says a finitely generated linear group is residually finite. So let $X\subset GL(n,F)$ be a finite subset of the general linear group over some field $F$, and $G=\langle X \rangle$. First, make $X$ symmetric, so that if $x\in X$ then also $x^{-1}\in X$. Each $x\in X$ is an $n\times n$ matrix, so we can assemble all entries from all elements of $X$, getting a finite subset of $F$. Let $R$ denote the subring of $F$ generated by this subset (along with $1$). Then $R$ is a Jacobson ring, and since it's a subring of $F$, it's Jacobson radical is $0$. Now $G$ is a subgroup of $GL(n,R)$; let $g\in G$ be a non-identity element, so that $g-I_n\neq 0$, where $I_n$ is the identity matrix. Thus $g-I_n$ has a non-zero element, and thus there is some maximal ideal $m\subset R$ not containing this non-zero element. The matrix ring homomorphism $M_n(R)\rightarrow M_n(R/m)$ (reducing everything mod $m$) induces a group homomorphism $G\rightarrow GL(n,R/m)$, where $g$ is not in the kernel. But $R/m$ is finite (by the Nullstellensatz), so $GL(n,R/m)$ is a finite group.

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  • $\begingroup$ Steve thanks for the answer. Sure I will be very curious to see the proof, so once you have it, please do leave a link! $\endgroup$ Feb 5, 2010 at 9:30
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You can combine the Bridson--Miller paper that Agol mentions with recent work of Haglund and Wise (specifically, their GAFA paper Special cube complexes) to show that the algorithmic problem in part (2) of the question is not always solvable. Haglund and Wise's version of the Rips Construction takes as input any finitely presented group Q and outputs a short exact sequence

$1 \to K \to G \to Q \to 1$

where K is finitely generated (and infinite) and G is a torsion-free, word-hyperbolic subgroup of GL(n,Z). Taking Q to be a non-abelian free group, the resulting G will work as input for the Bridson--Miller result.

So you don't need to prove that mapping class groups are linear!

Remarks

  • It's not clear how small you can take n to be. It will be fairly large in this construction.
  • In forthcoming work of Bridson and yours truly in a similar vein, we show that the hypotheses of part (2) are actually quite difficult to achieve. We produce a sequence of finite sets of integer matrices that each generate a finitely presentable group, but such that there is no algorithm to compute a presentation for these groups.
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This paper shows that the answer to 2) is false in the category of finitely presented residually finite groups. As Greg points out, this is different from the category of finitely presented linear groups though.

Addendum: In a paper of Bridson and Miller (which I found from Igor's link to Miller's survey), they show that the isomorphism problem for subgroups of $\Gamma\times\Gamma\times F$ is undecidable, where $\Gamma$ is a particular hyperbolic group (which is free-by-finitely generated) and $F$ is free. As mentioned in the paper, Mosher constructed surface-by-free hyperbolic groups, which therefore could work as $\Gamma$. These groups embed in the mapping class group of the once-punctured surface, so if mapping class groups of once-punctured surfaces are linear, this would answer 2). However, the only mapping class groups known to be linear are the punctured sphere/braid groups and the genus 2 mapping class group.

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  • $\begingroup$ I can't say that I made a conscious distinction. In any case your reference is good. $\endgroup$ Dec 24, 2009 at 2:53
  • $\begingroup$ Very interesting! This summer in CRIM I heard from somebody (maybe Benson Farb) that while it is unknown that mapping class group is linear, all the possible corrolaries that hold for linear groups also holds for this group. So your answer shows that proving that mapping class group is linear will have some applications :)! $\endgroup$ Dec 24, 2009 at 12:39
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    $\begingroup$ There are some highly non-trivial consequences of linearity that are "only just" known for mapping class groups. I'm thinking of the "equationally Noetherian" property, which says that every variety over a group G can be defined using only finitely many equations. This is an immediate consequence of Hilbert's Basis Theorem for linear groups; for mapping class groups, it's a consequence of highly non-trivial forthcoming work of Daniel Groves. $\endgroup$
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    Dec 26, 2009 at 23:45
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    $\begingroup$ Mosher constructed hyperbolic surface-by-free groups, and I think the existence of a hyperbolic free-by-surface group is open. (This could be a matter of the two of us having differing terminology.) $\endgroup$ Sep 28, 2010 at 1:19
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This survey by Chuck Miller discusses among other things the isomorphism problem for linear groups (and for other classes of groups as well). The flow chart on page 31 states that for finitely generated linear groups the isomorphism problem is generally unsolvable, while it seems that for finitely presented linear groups the isomorphism problem is open.

Incidentally, finitely presented groups are by definition finitely generated (they have finite presentation), so I think FGFP is just FP.

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  • $\begingroup$ Igor, thanks a lot for the reference!! $\endgroup$ Dec 24, 2009 at 11:42
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    $\begingroup$ The link to ms.unimelb.edu.au is broken, but a snapshot is saved on the Wayback Machine. The full citation is as follows: Miller, Charles F. III, Decision problems for groups – survey and reflections, Algorithms and classification in combinatorial group theory, Lect. Workshop, Berkeley/CA (USA) 1989, Publ., Math. Sci. Res. Inst. 23, 1–59 (1992). Zbl 0752.20014. $\endgroup$ May 1, 2023 at 20:39
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Excuse me guys, but I think it is true that the permutation groups $S_m$ will not admit a faithful representation in dimension $n$ if $m>>n$? I can certainly see this for $m>2n$ atleast. So this will give countably many examples of finitely presented groups not admitting injective homomorphism to $GL(n,C)$ as Dmitri wanted in his question (1). My claim can be seen by either an elementary combinatorial calculation on the involution on the respective spaces or by classification of irreducible representation of $S_n$(that they are either the identity, sign or the standard ones). We don't have to invoke any high powered theorem to do this IMHO. Cheers!

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  • $\begingroup$ Maharana, thanks for your answer! Well, when I formulated the question I was meaning, "FGFP groups that don't admit a injective homomorphism fo $GL(n,C)$ for ANY n". In this case to consturct an example you surelly need infinite groups. I will modify now the question, so that there is no ambiguity. $\endgroup$ Dec 25, 2009 at 12:28

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