Dehn function explained

Dehn function should not be confused with Dehn invariant.

In the mathematical subject of geometric group theory, a Dehn function, named after Max Dehn, is an optimal function associated to a finite group presentation which bounds the area of a relation in that group (that is a freely reduced word in the generators representing the identity element of the group) in terms of the length of that relation (see pp. 79 - 80 in). The growth type of the Dehn function is a quasi-isometry invariant of a finitely presented group. The Dehn function of a finitely presented group is also closely connected with non-deterministic algorithmic complexity of the word problem in groups. In particular, a finitely presented group has solvable word problem if and only if the Dehn function for a finite presentation of this group is recursive (see Theorem 2.1 in). The notion of a Dehn function is motivated by isoperimetric problems in geometry, such as the classic isoperimetric inequality for the Euclidean plane and, more generally, the notion of a filling area function that estimates the area of a minimal surface in a Riemannian manifold in terms of the length of the boundary curve of that surface.

History

The idea of an isoperimetric function for a finitely presented group goes back to the work of Max Dehn in 1910s. Dehn proved that the word problem for the standard presentation of the fundamental group of a closed oriented surface of genus at least two is solvable by what is now called Dehn's algorithm. A direct consequence of this fact is that for this presentation the Dehn function satisfies Dehn(n) ≤ n. This result was extended in 1960s by Martin Greendlinger to finitely presented groups satisfying the C'(1/6) small cancellation condition.[1] The formal notion of an isoperimetric function and a Dehn function as it is used today appeared in late 1980s  - early 1990s together with the introduction and development of the theory of word-hyperbolic groups. In his 1987 monograph "Hyperbolic groups"[2] Gromov proved that a finitely presented group is word-hyperbolic if and only if it satisfies a linear isoperimetric inequality, that is, if and only if the Dehn function of this group is equivalent to the function f(n) = n. Gromov's proof was in large part informed by analogy with filling area functions for compact Riemannian manifolds where the area of a minimal surface bounding a null-homotopic closed curve is bounded in terms of the length of that curve.

The study of isoperimetric and Dehn functions quickly developed into a separate major theme in geometric group theory, especially since the growth types of these functions are natural quasi-isometry invariants of finitely presented groups. One of the major results in the subject was obtained by Sapir, Birget and Rips who showed[3] that most "reasonable" time complexity functions of Turing machines can be realized, up to natural equivalence, as Dehn functions of finitely presented groups.

Formal definition

Let

G=\langleX|R\rangle    (*)

be a finite group presentation where the X is a finite alphabet and where R ⊆ F(X) is a finite set of cyclically reduced words.

Area of a relation

Let w ∈ F(X) be a relation in G, that is, a freely reduced word such that w = 1 in G. Note that this is equivalent to saying that w belongs to the normal closure of R in F(X), that is, there exists a representation of w as

w=u1r1u

-1
1

umrmu

-1
m

inF(X),

   (♠)

where m ≥ 0 and where ri ∈ R± 1 for i = 1, ..., m.

For w ∈ F(X) satisfying w = 1 in G, the area of w with respect to (∗), denoted Area(w), is the smallest m ≥ 0 such that there exists a representation (♠) for w as the product in F(X) of m conjugates of elements of R± 1.

A freely reduced word w ∈ F(X) satisfies w = 1 in G if and only if the loop labeled by w in the presentation complex for G corresponding to (∗) is null-homotopic. This fact can be used to show that Area(w) is the smallest number of 2-cells in a van Kampen diagram over (∗) with boundary cycle labelled by w.

Isoperimetric function

An isoperimetric function for a finite presentation (∗) is a monotone non-decreasing function

f:N\to[0,infty)

such that whenever w ∈ F(X) is a freely reduced word satisfying w = 1 in G, then

Area(w) ≤ f(|w|),where |w| is the length of the word w.

Dehn function

Then the Dehn function of a finite presentation (∗) is defined as

{\rmDehn}(n)=max\{{\rmArea}(w):w=1inG,|w|\len,wfreelyreduced.\}

Equivalently, Dehn(n) is the smallest isoperimetric function for (∗), that is, Dehn(n) is an isoperimetric function for (∗) and for any other isoperimetric function f(n) we have

Dehn(n) ≤ f(n)for every n ≥ 0.

Growth types of functions

Because the exact Dehn function usually depends on the presentation, one usually studies its asymptotic growth type as n tends to infinity, which only depends on the group.

For two monotone-nondecreasing functions

f,g:N\to[0,infty)

one says that f is dominated by g if there exists C ≥1 such that

f(n)\leCg(Cn+C)+Cn+C

for every integer n ≥ 0. Say that f ≈ g if f is dominated by g and g is dominated by f. Then ≈ is an equivalence relation and Dehn functions and isoperimetric functions are usually studied up to this equivalence relation. Thus for any a,b > 1 we have an ≈ bn. Similarly, if f(n) is a polynomial of degree d (where d ≥ 1 is a real number) with non-negative coefficients, then f(n) ≈ nd. Also, 1 ≈ n.

If a finite group presentation admits an isoperimetric function f(n) that is equivalent to a linear (respectively, quadratic, cubic, polynomial, exponential, etc.) function in n, the presentation is said to satisfy a linear (respectively, quadratic, cubic, polynomial, exponential, etc.) isoperimetric inequality.

Basic properties

In particular, this implies that solvability of the word problem is a quasi-isometry invariant for finitely presented groups.

Examples

G=\langlea1,a2,b1,b2|[a1,b1][a2,b2]=1\rangle

satisfies Dehn(n) ≤ n and Dehn(n) ≈ n.

Zk

has Dehn(n) ≈ n2.[6]

B(1,2)=\langlea,b|b-1ab=a2\rangle

has Dehn(n) ≈ 2n (see [7]).

H3=\langlea,b,t|[a,t]=[b,t]=1,[a,b]=t2\rangle

satisfies a cubic but no quadratic isoperimetric inequality.

H2k+1=\langlea1,b1,...,ak,bk,t|[ai,bi]=t,[ai,t]=[bi,t]=1,i=1,...,k,[ai,bj]=1,i\nej\rangle

,

where k ≥ 2, satisfy quadratic isoperimetric inequalities.[8]

G=\langlea,t|(t-1a-1t)a(t-1at)=a2\rangle

has a Dehn function growing faster than any fixed iterated tower of exponentials. Specifically, for this group

Dehn(n) ≈ exp(exp(exp(...(exp(1))...)))

where the number of exponentials is equal to the integral part of log2(n) (see [4] [10]).

Known results

[2,infty)

.[15]

Fk\rtimes\phiZ

of φ satisfies a quadratic isoperimetric inequality.[27]

O\left(\sqrt[4]{f(n)}\right)

by a Turing machine then f(n) is equivalent to the Dehn function of a finitely presented group.

Generalizations

See also

Further reading

External links

Notes and References

  1. Martin Greendlinger, Dehn's algorithm for the word problem. Communications on Pure and Applied Mathematics, vol. 13 (1960), pp. 67 - 83.
  2. M. Gromov, Hyperbolic Groups in: "Essays in Group Theory" (G. M. Gersten, ed.), MSRI Publ. 8, 1987, pp. 75 - 263. .
  3. M. Sapir, J.-C. Birget, E. Rips. Isoperimetric and isodiametric functions of groups. Annals of Mathematics (2), vol 156 (2002), no. 2, pp. 345 - 466.
  4. S. M. Gersten, Isoperimetric and isodiametric functions of finite presentations. Geometric group theory, Vol. 1 (Sussex, 1991), pp. 79 - 96, London Math. Soc. Lecture Note Ser., 181, Cambridge University Press, Cambridge, 1993.
  5. Juan M. Alonso, Inégalités isopérimétriques et quasi-isométries. Comptes Rendus de l'Académie des Sciences, Série I, vol. 311 (1990), no. 12, pp. 761 - 764.
  6. Martin R. Bridson. The geometry of the word problem. Invitations to geometry and topology, pp. 29 - 91, Oxford Graduate Texts in Mathematics, 7, Oxford University Press, Oxford, 2002. .
  7. S. M. Gersten, Dehn functions and l1-norms of finite presentations. Algorithms and classification in combinatorial group theory (Berkeley, CA, 1989), pp. 195 - 224,Math. Sci. Res. Inst. Publ., 23, Springer, New York, 1992. .
  8. D. Allcock, An isoperimetric inequality for the Heisenberg groups. Geometric and Functional Analysis, vol. 8 (1998), no. 2, pp. 219 - 233.
  9. V. S. Guba, The Dehn function of Richard Thompson's group F is quadratic. Inventiones Mathematicae, vol. 163 (2006), no. 2, pp. 313 - 342.
  10. A. N. Platonov, An isoparametric function of the Baumslag-Gersten group. (in Russian.) Vestnik Moskov. Univ. Ser. I Mat. Mekh. 2004, no. 3, pp. 12 - 17; translation in: Moscow University Mathematics Bulletin, vol. 59 (2004), no. 3, pp. 12 - 17 (2005).
  11. A. Yu. Olʹshanskii. Hyperbolicity of groups with subquadratic isoperimetric inequality. International Journal of Algebra and Computation, vol. 1 (1991), no. 3, pp. 281 - 289.
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  16. M. Gromov, Asymptotic invariants of infinite groups, in: "Geometric Group Theory", Vol. 2 (Sussex, 1991), London Mathematical Society Lecture Note Series, 182, Cambridge University Press, Cambridge, 1993, pp. 1 - 295.
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  19. M. R. Bridson and A. Haefliger, Metric spaces of non-positive curvature. Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences], vol. 319. Springer-Verlag, Berlin, 1999. ; Remark 1.7, p. 444.
  20. E. Leuzinger. On polyhedral retracts and compactifications of locally symmetric spaces. Differential Geometry and its Applications, vol. 20 (2004), pp. 293 - 318.
  21. Robert Young, The Dehn function of SL(n;Z). Annals of Mathematics (2), vol. 177 (2013) no.3, pp. 969 - 1027.
  22. E. Leuzinger and R. Young, Filling functions of arithmetic groups. Annals of Mathematics, vol. 193 (2021), pp. 733 - 792.
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  24. [Allen Hatcher]
  25. Martin R. Bridson and Karen Vogtmann, On the geometry of the automorphism group of a free group. Bulletin of the London Mathematical Society, vol. 27 (1995), no. 6, pp. 544 - 552.
  26. Michael Handel and Lee Mosher, Lipschitz retraction and distortion for subgroups of Out(Fn). Geometry & Topology, vol. 17 (2013), no. 3, pp. 1535 - 1579.
  27. Martin R. Bridson and Daniel Groves. The quadratic isoperimetric inequality for mapping tori of free-group automorphisms. Memoirs of the American Mathematical Society, vol 203 (2010), no. 955.
  28. J.-C. Birget, A. Yu. Ol'shanskii, E. Rips, M. Sapir. Isoperimetric functions of groups and computational complexity of the word problem. Annals of Mathematics (2), vol 156 (2002), no. 2, pp. 467 - 518.
  29. S. M. Gersten, The double exponential theorem for isodiametric and isoperimetric functions. International Journal of Algebra and Computation, vol. 1 (1991), no. 3, pp. 321 - 327.
  30. S. M. Gersten and T. Riley, Filling length in finitely presentable groups. Dedicated to John Stallings on the occasion of his 65th birthday. Geometriae Dedicata, vol. 92 (2002), pp. 41 - 58.
  31. J. M. Alonso, X. Wang and S. J. Pride, Higher-dimensional isoperimetric (or Dehn) functions of groups. Journal of Group Theory, vol. 2 (1999), no. 1, pp. 81 - 112.
  32. M. Gromov, Asymptotic invariants of infinite groups, in: "Geometric Group Theory", Vol. 2 (Sussex, 1991), London Mathematical Society Lecture Note Series, 182, Cambridge University Press, Cambridge, 1993, pp. 1 - 295.
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