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Quasisymmetrically rigid self-similar carpets

Published online by Cambridge University Press:  22 October 2024

FENG RAO
Affiliation:
School of Mathematics Statistics, Hubei University of Science Technology, Xianning 437100, Hubei, China (e-mail: [email protected])
FAN WEN*
Affiliation:
Department of Mathematics, Jinan University, Guangzhou 510632, China
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Abstract

We define balanced self-similar quasi-round carpets and compare the carpet moduli of some path families relating to such a carpet. Then, using some known results on quasiconformal geometry of carpets, we prove that the group of quasisymmetric self-homeomorphisms of every balanced self-similar quasi-round carpet is finite. Furthermore, we prove that some balanced self-similar carpets in the unit square with strong geometric symmetry are quasisymmetrically rigid by using the quasisymmetry of weak tangents of carpets.

Type
Original Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1 Introduction

Bonk, Kleiner, and Merenkov established a nice quasiconformal geometry of carpets, by showing that quasisymmetric maps between carpets behave like conformal maps between regions [Reference Bonk1Reference Bonk and Merenkov5, Reference Merenkov10, Reference Merenkov11]. We shall state some results of this theory in §2.

Motivated by the quasisymmetric rigidity of the standard Sierpiński carpet given by Bonk and Merenkov [Reference Bonk and Merenkov4, Reference Bonk and Merenkov5], we study the following question.

Question 1.1. Which self-similar Sierpiński carpets are quasisymmetrically rigid?

We start with definitions and notation. A topological homeomorphism $f:(X,d_{X})\to (Y,d_{Y})$ of metric spaces is called quasisymmetric if there is a homeomorphism $\eta :[0,\infty )\rightarrow [0,\infty )$ such that

$$ \begin{align*}\frac{d_{Y}(f(x),f(y))}{d_{Y}(f(x),f(z))}\leq\eta\bigg(\frac{d_{X}(x,y)}{d_{X}(x,z)}\bigg)\quad \text{for all } x,y,z\in X, x\neq z.\end{align*} $$

In the case $Y=X$ , we say that f is a quasisymmetric self-homeomorphism of X. Denote by $\mbox {QS}(X)$ the collection of quasisymmetric self-homeomorphisms of X. It is well known that $\mbox {QS}(X)$ is a group (cf. [Reference Heinonen7, Reference Tukia and Väisälä13]). If $\mbox {QS}(X)=\mbox {ISO}(X)$ , we say that X is quasisymmetrically rigid. Hereafter, $\mbox {ISO}(X)$ is the group of all isometries of X onto itself.

Let $\mathbb {C}$ be the complex plane. For a subset E of $\mathbb {C}$ , we denote by $\mbox {cl}(E)$ , $\partial E$ , $\mbox {int}(E)$ , and $\mbox {diam}(E)$ its closure, boundary, interior, and diameter, respectively. A subset S of $\mathbb {C}$ is called a carpet if

$$ \begin{align*} S=D\setminus\bigcup_{j=1}^\infty D_j, \end{align*} $$

where D is a closed Jordan region and $D_j$ , $j\geq 1$ , are open Jordan regions satisfying:

  1. (1) $\mbox {cl}({D}_{j})$ , $j\geq 1$ , are pairwise disjoint subsets of $\mbox {int}(D)$ ;

  2. (2) $\lim _{j\to \infty }\mbox {diam}(D_j)=0$ ; and

  3. (3) $\mbox {int}(S)=\emptyset $ .

In this case, we also say that S is a D-carpet. The boundaries $\partial D$ , $\partial D_j$ , $j\geq 1$ , are called peripheral circles of S, among which $\partial D$ is called the outer peripheral circle of S and denoted by O. Denote the family of peripheral circles of S as

$$ \begin{align*} \mathcal{C}(S):=\{O\}\cup\{\partial D_j: j\geq 1\}. \end{align*} $$

The carpets have the following topological properties (cf. [Reference Bonk2, Reference Whyburn15]). They are all topologically equivalent. The group of topological self-homeomorphisms of an arbitrarily given carpet is uncountable. Any homeomorphism $h:S\to T$ of carpets S and T sends peripheral circles of S to peripheral circles of T.

We say that a carpet is quasi-round if its peripheral circles are uniform quasicircles. Here, a K-quasicircle is a topological circle in $\mathbb {C}$ satisfying

$$ \begin{align*}\mbox{diam}(\gamma_{xy})\wedge\mbox{diam}(C\setminus\gamma_{xy})\leq K|x-y|\end{align*} $$

for all $x,y\in C$ , where $\gamma _{xy}$ is a subarc of C of endpoints x and y. We say that the peripheral circles of a carpet are uniform quasicircles if they are K-quasicircles for some common constant $K\geq 1$ .

Definition 1.2. We say that a D-carpet is self-similar, if there is a family $\Phi $ consisting of finite contractive similarities of $\mathbb {C}$ such that

$$ \begin{align*}S=\bigcup_{\phi\in\Phi}\phi(S)\end{align*} $$

and that $\phi (\mbox {int}(D))$ , $\phi \in \Phi $ , are pairwise disjoint subsets of $\mbox {int}(D)$ . In this case, the family $\Phi $ is called an IFS of S.

Here, a map $\phi :\mathbb {C}\to \mathbb {C}$ is called a contractive similarity, if there is a constant $r\in (0,1)$ such that $|\phi (x)-\phi (y)|=r|x-y|$ for all $x,y\in \mathbb {C}$ . For a self-similar D-carpet with IFS $\Phi $ , we have assumed the open set condition for the open set $\mbox {int}(D)$ , so such a carpet is of Hausdorff dimension less than $2$ (cf. [Reference Falconer6]).

Let S be a self-similar D-carpet with IFS $\Phi $ . Then, the set

$$ \begin{align*}\mbox{int}(D)\setminus\bigcup_{\phi\in\Phi}\phi(D)\end{align*} $$

is open and its bounded components are Jordan domains whose boundaries are called the first generation peripheral circles of S. We denote by $\mathcal {C}_1(S)$ the family of such peripheral circles.

Definition 1.3. We say that a self-similar carpet is balanced if the family $\mathcal {C}_1(S)$ is finite and $\mathrm {mod}_S\Gamma (O, M;S)$ takes the same value for all $M\in \mathcal {C}_1(S)$ , where $\mathrm {mod}_S\Gamma (O,M;S)$ is the carpet modulus of the path family $\Gamma (O,M;S)$ .

The definition of carpet modulus will be given in §3. Clearly, every self-similar carpet S with $\#\mathcal {C}_1(S)=1$ is balanced. Let S be a self-similar quasi-round carpet with $\#\mathcal {C}_1(S)>1$ . If for every pair $M,C\in \mathcal {C}_1(S)$ there is an $h\in \mbox {QS}(S)$ such that $h(O)=O$ and $h(M)=C$ , then S is balanced. By this fact and geometric symmetry, we easily construct a lot of balanced self-similar quasi-round carpets. We illustrate six such carpets in Figure 1.

Figure 1 Examples of balanced self-similar quasi-round carpets.

The first main result of this paper is as follows.

Theorem 1.4. Let S be a balanced self-similar quasi-round carpet. Then, $\mathrm {QS}(S)$ is a finite group.

Theorem 1.4 generalizes the corresponding results of [Reference Bonk and Merenkov4, Reference Zeng and Su16]. The proof is still based on comparing the carpet moduli $\mbox {mod}_S\Gamma (O,M; S)$ and $\mbox {mod}_S\Gamma (C_1,C_2; S)$ , where $M\in \mathcal {C}_1(S)$ and $C_1,C_2\in \mathcal {C}(S)$ , with $C_1\neq C_2$ and $\{C_1,C_2\}\neq \{O,J\}$ for any $J\in \mathcal {C}_1(S)$ . At present, we do not know if the inequality

$$ \begin{align*}\mbox{mod}_S\Gamma(C_1,C_2; S)<\mbox{mod}_S\Gamma(O,M; S)\end{align*} $$

is always true, but we prove that it is true for enough of pairs $C_1,C_2$ in §4. By this discussion and quasiconformal geometry of carpets, we give a complete proof of Theorem 1.4 in §5.

Applying Theorem 1.4 and the quasisymmetry of weak tangents of carpets, we may prove that some self-similar carpets with strong geometric symmetry are quasisymmetrically rigid.

Let $Q:=\{z=x+iy:\ 0\leq x,y\leq 1\}$ be the unit square. Let $\gamma _0$ and $\gamma _1$ be the diagonals of $ Q $ passing through the vertices $0$ and $1$ , respectively. Let $\gamma _h$ and $\gamma _v$ be the horizontal and vertical median lines of $ Q $ . Let $R_0,R_1$ , $R_h$ , and $R_v$ be the reflections in $\gamma _0$ , $\gamma _1$ , $\gamma _h$ , and $\gamma _v$ . Let $r_{\pi /2}$ , $r_{\pi }$ , and $r_{3\pi /2}$ be the rotations of angles $\pi /2$ , $\pi $ , and $3\pi /2$ around the center of $ Q $ . Then,

$$ \begin{align*}\mathrm{ISO}( Q )=\{\mathrm{id}, r_{\pi/2}, r_{\pi}, r_{3\pi/2}, R_0,R_1,R_h, R_v\}.\end{align*} $$

Definition 1.5. We say that a self-similar $ Q $ -carpet S is symmetric if

$$ \begin{align*} \mathrm{ISO}(S)=\mathrm{ISO}( Q ). \end{align*} $$

A balanced self-similar Q-carpet is not necessarily symmetric. In Figure 1, the five self-similar Q-carpets are all balanced, but only the final two are symmetric.

It is clear that every symmetric self-similar $Q $ -carpet S with $\#\mathcal {C}_1(S)=4$ is balanced and quasi-round, so the group $\mathrm {QS}(S)$ is finite by Theorem 1.4. We obtain a sufficient condition for such a carpet to be quasisymmetrically rigid. In what follows, we say that a family of contractive similarities is homogeneous if their similarity ratios are equal to each other.

Theorem 1.6. Let S be a symmetric self-similar Q-carpet with $\#\mathcal {C}_1(S)=4$ . Suppose that there is a peripheral circle $C\in \mathcal {C}_1(S)$ and a point $z\in C\cap \gamma _0$ such that the family

$$ \begin{align*}\Phi_z:=\{\phi\in\Phi: z\in\phi( Q )\}\end{align*} $$

is homogeneous and of $\#\Phi _z=3$ . Then, S is quasisymmetrically rigid.

For example, the final two symmetric self-similar Q-carpets in Figure 1 satisfy the assumption condition of Theorem 1.6. Also, there are symmetric self-similar Q-carpets with $\#\mathcal {C}_1(S)=4$ , which do not satisfy this condition; see Figure 2.

Figure 2 Two carpets not satisfying the conditions of Theorem 1.6.

Theorem 1.6 improves the result of Zeng and Su [Reference Zeng and Su16]. We remark that a similar result can be formulated for symmetric self-similar T-carpets, where T is a closed solid equilateral triangle. For example, one may prove that the first carpet in Figure 1 is quasisymmetrically rigid. The quasisymmetric rigidity question of general balanced self-similar Q-carpets and T-carpets is still open.

2 Quasiconformal geometry of carpets

In this section, we state some results from quasiconformal geometry of carpets that will be used in proving Theorem 1.4.

See Bonk [Reference Bonk2]. Let S be a carpet and $\mathcal {C}(S)$ be the family of its peripheral circles. The family $\mathcal {C}(S)$ is said to be uniformly relatively separated if

$$ \begin{align*}\inf\bigg\{\frac{\mbox{dist}(C_1,C_2)}{\mbox{diam}(C_1)\wedge\mbox{diam}(C_2)}:\ C_1,C_2\in \mathcal{C}(S),\ C_1\neq C_2\bigg\}>0,\end{align*} $$

where $\mbox {dist}(C_1,C_2)=\min _{z\in C_1, w\in C_2}|z-w|$ is the Euclidean distance between $C_1$ and $C_2$ and $a\wedge b=\min \{a,b\}$ . We call S a Bonk–Sierpiński carpet if it is of measure zero and its peripheral circles are uniformly relatively separated uniform quasicircles. It is known that this class of carpets are quasisymmetrically invariant.

The following extension theorem is due to Bonk [Reference Bonk2].

Lemma 2.1. Let S be a quasi-round carpet in $\mathbb {C}$ . Then, every quasisymmetric embedding $f:S\to \mathbb {C}$ has a quasiconformal extension $F:\hat {\mathbb {C}}\to \hat {\mathbb {C}}$ .

The following three circle theorem is also due to Bonk [Reference Bonk2].

Lemma 2.2. Let S be a Bonk–Sierpiński carpet in $\mathbb {C}$ . Let $C_1,C_2,C_3$ be three distinct peripheral circles of S. If f is an orientation-preserving quasisymmetric self-homeomorphism of S such that $f(C_j)=C_j, j=1,2,3$ , then f is the identity.

The following rigidity theorems are due to Bonk and Merenkov [Reference Bonk and Merenkov4].

Lemma 2.3. Let S be a Bonk–Sierpiński carpet in $\mathbb {C}$ . Let $C_1,C_2$ be two distinct peripheral circles of S. Then, the group of all orientation-preserving quasisymmetric self-homeomorphisms of S that fix $C_1$ and $C_2$ setwise is a finite cyclic group.

Lemma 2.4. Let S be a Bonk–Sierpiński carpet in $\mathbb {C}$ . Let $C_1,C_2$ be two distinct peripheral circles of S and $p\in S$ . If f is an orientation-preserving quasisymmetric self-homeomorphism of S such that $f(C_{1})=C_1$ , $f(C_2)=C_2$ , and $f(p)=p$ , then f is the identity.

3 Carpet modulus

Let $ds$ and m be the Euclidean line element and the Lebesgue measure on $\mathbb {C}$ . An embedding $\gamma : (0,1)\to U$ will be called an open path in U, where U is a subset of $\mathbb {C}$ . Let $\Gamma $ be a family of paths in $\mathbb {C}$ . A Borel density $\rho : \mathbb {C}\to [0,\infty ]$ is called admissible for $\Gamma $ if

$$ \begin{align*}\int_{\gamma}\rho\,ds\geq 1\end{align*} $$

for each $\gamma \in \Gamma $ . The conformal modulus $\mbox {mod}(\Gamma )$ of $\Gamma $ is defined by

$$ \begin{align*} \mbox{mod}(\Gamma)=\inf_{\rho}\int_{\mathbb{C}}\rho^2\,dm, \end{align*} $$

where the infimum is taken over all admissible densities for $\Gamma $ . We say that an admissible density $\rho $ is extremal for $\mbox {mod}(\Gamma )$ , if it satisfies

$$ \begin{align*} \mbox{mod}(\Gamma)=\int_{\mathbb{C}}\rho^2\,dm. \end{align*} $$

The conformal modulus is invariant under conformal maps and quasi-invariant under quasiconformal maps (cf. [Reference Väisälä14]). For its various variants and applications, we refer to [Reference Bonk2, Reference Keith and Laakso8, Reference Mackay, Tyson and Wildrick9, Reference Schramm12].

Next, we recall the carpet modulus. Let S be a carpet and $\mathcal {C}(S)$ be the family of its peripheral circles. Let $\Gamma $ be a path family in $\mathbb {C}$ . A function $\rho :\mathcal {C}(S)\to [0,+\infty ]$ is called admissible for $(\Gamma , S)$ if there is a subfamily $\Gamma _{0}\subseteq \Gamma $ with $\mbox {mod}(\Gamma _{0})=0$ such that

$$ \begin{align*}\sum_{C\in \mathcal{C}(S), \gamma\cap C\neq\emptyset}\rho(C)\geq1\end{align*} $$

for every path $\gamma \in \Gamma \setminus \Gamma _{0}$ . The carpet modulus $\mbox {mod}_{S}\Gamma $ of $\Gamma $ with respect to S is defined by

$$ \begin{align*}\mbox{mod}_{S}\Gamma=\inf_{\rho}\sum_{C\in\mathcal{C}(S)}\rho(C)^{2},\end{align*} $$

where the infimum is taken over all admissible functions for $(\Gamma , S)$ . An admissible function $\rho $ is called extremal for $\mbox {mod}_{S}(\Gamma )$ if

$$ \begin{align*}\mbox{mod}_{S}\Gamma=\sum_{C\in\mathcal{C}(S)}\rho(C)^{2}.\end{align*} $$

By the definition, if $\mbox {mod}(\Gamma )=0$ , then $\mbox {mod}_S\Gamma =0$ .

The carpet modulus has been applied as a tool in the study of quasiconformal geometry of carpets in [Reference Bonk2, Reference Bonk and Merenkov4]. Among its properties, the following ones are useful in proving Theorem 1.4.

Lemma 3.1. Let S be a carpet and $\Gamma _{1}$ , $\Gamma _{2}$ be two path families in $\mathbb {C}$ . If each path in $\Gamma _{1}$ has a subpath belonging to $\Gamma _{2}$ , then

$$ \begin{align*}\mathrm{mod}_{S}\Gamma_{1}\leq \mathrm{mod}_{S}\Gamma_{2}.\end{align*} $$

The carpet modulus is invariant under quasiconformal maps.

Lemma 3.2. [Reference Bonk and Merenkov4, Lemma 2.1]

Let $S, T$ be two carpets and $\Gamma $ be a path family in $\mathbb {C}$ . If $f:\hat {\mathbb {C}}\rightarrow \hat {\mathbb {C}}$ is a quasiconformal map such that $f(S)=T$ , then

$$ \begin{align*}\mathrm{mod}_{T}f(\Gamma)=\mathrm{mod}_{S}\Gamma.\end{align*} $$

Let S be a carpet in $\mathbb {C}$ . Let $C_{1},C_{2}$ be two distinct peripheral circles of S. Let $\Omega _{1}$ and $\Omega _{2}$ be respectively the components of $\mathbb {C}\setminus S$ bounded by $C_{1}$ and $C_{2}$ . Let $\Gamma (C_{1},C_{2};S)$ be the family of paths $\gamma :(0,1)\to \mathbb {C}\setminus \mbox {cl}(\Omega _{1}\cup \Omega _{2})$ with

$$ \begin{align*}\lim_{t\to 0}\gamma(t)\in C_1\quad \mbox{and}\quad \lim_{t\to 1}\gamma(t)\in C_2.\end{align*} $$

Lemma 3.3. Let S be a quasi-round carpet in $\mathbb {C}$ . Let $C_{1},C_{2}$ be two distinct peripheral circles of S. If $f\in \mathrm {QS}(S)$ , then

$$ \begin{align*}\mathrm{mod}_S\Gamma(C_{1},C_{2};S)=\mathrm{mod}_{S}\Gamma(f(C_{1}),f(C_{2});S).\end{align*} $$

Proof. By Lemma 2.1, f has a quasiconformal extension $F:\hat {\mathbb {C}}\to \hat {\mathbb {C}}$ . Note that

$$ \begin{align*}f(C_{1}),f(C_{2})\in \mathcal{C}(S)\quad \mbox{and}\quad F(\Gamma(C_{1},C_{2};S))=\Gamma(f(C_{1}),f(C_{2});S).\end{align*} $$

We immediately get the desired equality by Lemma 3.2.

Lemma 3.4. [Reference Bonk and Merenkov4, Proposition 2.4]

Let S be a quasi-round carpet and $\Gamma $ be a path family in $\mathbb {C}$ with $\mathrm {mod}_{S}\Gamma <+\infty $ . Then, there is a unique extremal admissible function for $\mathrm {mod}_{S}\Gamma $ .

Lemma 3.5. [Reference Bonk and Merenkov4, Proposition 4.9]

Let S be a Bonk–Sierpiński carpet in $\mathbb {C}$ and let $C_1$ , $C_2$ be two distinct peripheral circles of S. Then, the carpet modulus $\mathrm {mod}_{S}\Gamma (C_{1},C_{2};S)$ is finite and positive. Moreover, if $\rho $ is an extremal admissible function for $\mathrm {mod}_{S}\Gamma (C_{1},C_{2};S)$ , we have $\rho (C_1)=\rho (C_2)=0$ and $\rho (C)>0$ for each $C\in \mathcal {C}(S)\setminus \{C_1,C_2\}$ .

4 Comparing carpet moduli

Let S be a self-similar quasi-round carpet with IFS $\{\phi _1, \phi _1,\ldots ,\phi _n\}$ . To prove Theorem 1.4, we are going to compare the carpet moduli $\mbox {mod}_S\Gamma (O,M; S)$ and $\mbox {mod}_S\Gamma (C_1,C_2; S)$ , where $M\in \mathcal {C}_1(S)$ and $C_1,C_2\in \mathcal {C}(S)$ .

We use notation from words. Let $A=\{1, 2,\ldots ,n\}$ be an alphabet. Let $A^k$ be the set of words of length k and $A^*$ the set of finite words over the alphabet A. By the convention, denote by $\varepsilon $ the empty word. For each finite word $w=w_1w_2\cdots w_k\in A^k$ , let

$$ \begin{align*}\phi_w:=\phi_{w_1}\circ \phi_{w_2}\circ\cdots\circ \phi_{w_k}\end{align*} $$

denote the composition of maps. If $w=\varepsilon $ , $\phi _\varepsilon $ is the identity on $\mathbb {C}$ . For simplicity, write $E_w$ for $\phi _w(E)$ if $w\in A^*$ and $E\subset \mathbb {C}$ . We say that $S_w$ is a copy of S.

Lemma 4.1. Every self-similar quasi-round D-carpet S with IFS $\{\phi _1, \ldots ,\phi _n\}$ is a Bonk–Sierpiński carpet and its peripheral circles can be given by

(1) $$ \begin{align} \mathcal{C}(S)=\{O\}\cup\{M_w:\ w\in A^*,\ M\in \mathcal{C}_1(S)\}. \end{align} $$

Proof. By the self-similarity of S,

$$ \begin{align*}S=D\setminus\bigcup_{w\in A^*}\bigcup_{M\in\mathcal{C}_1(S)}(G(M))_w,\end{align*} $$

where $G(M)$ is the bounded Jordan domain of boundary M. Thus, the peripheral circles of S are given by equation (1).

Let

$$ \begin{align*}\delta_1=\min_{M\in \mathcal{C}_1(S)}\frac{\mbox{dist}(O,M)}{\mbox{diam}(M)}\end{align*} $$

and

$$ \begin{align*}\delta_2=\min_{M,M'\in\mathcal{C}_1(S), M\neq M'}\frac{\mbox{dist}(M,M')}{\mbox{diam}(M)\wedge\mbox{diam}(M')}.\end{align*} $$

Let $\delta =\delta _1\wedge \delta _2$ . Then, $\delta>0$ . Moreover, if C and $C'$ are two distinct peripheral circles of S, we easily get by the self-similarity of S,

$$ \begin{align*}\frac{\mbox{dist}(C,C')}{\mbox{diam}(C)\wedge\mbox{diam}(C')}\geq\delta,\end{align*} $$

so $\mathcal {C}(S)$ is uniformly relatively separated.

Since S is of Lebesgue measure zero and its peripheral circles are uniform quasicircles, it then follows that S is a Bonk–Sierpiński carpet. The proof is completed.

Let S be a self-similar quasi-round D-carpet with IFS $\Phi =\{\phi _1,\phi _2, \ldots ,\phi _n\}$ .

Lemma 4.2. Suppose $M\in \mathcal {C}_1(S)$ , $w\in A^*$ , $w\neq \varepsilon $ . Then,

$$ \begin{align*}\mathrm{mod}_S\Gamma(O, M_w;S)<\mathrm{mod}_S\Gamma(O, M; S).\end{align*} $$

Proof. By Lemma 4.1, $S_w$ is a Bonk–Sierpiński carpet. Thus, by Lemmas 3.4 and 3.5, the carpet modulus $\mathrm {mod}_{S_w}\Gamma (O_w, M_w; S_w)$ has an extremal admissible function $\rho $ satisfying $\rho (O_w)=0$ . Define $\xi :\mathcal {C}(S)\to [0,+\infty ]$ by

$$ \begin{align*} \xi(C)= \begin{cases} \rho(C) & \mbox{if}\ C\in \mathcal{C}(S_w)\setminus\{O_w\},\\ 0 & \mbox{if}\ C\in \mathcal{C}(S)\setminus\mathcal{C}(S_w). \end{cases} \end{align*} $$

Note that every path in $\Gamma (O, M_w;S)$ has a subpath belonging to $\Gamma (O_w, M_w;S_w)$ . The admissibility of $\rho $ implies that $\xi $ is admissible for $\Gamma (O, M_w;S)$ . However, it is clear that $\xi $ takes zero on infinitely many peripheral circles of S. By Lemma 3.5, $\xi $ cannot be extremal for $\mathrm {mod}_S\Gamma (O, M_w;S)$ . It then follows that

$$ \begin{align*}\mathrm{mod}_S\Gamma(O, M_w;S)<\sum_{C\in\mathcal{C}(S)}\xi(C)^2=\sum_{C\in\mathcal{C}(S_w)}\rho(C)^2=\mathrm{mod}_{S_w}\Gamma(O_w, M_w;S_w),\end{align*} $$

which together with the scale invariance of the carpet modulus yields

$$ \begin{align*}\mathrm{mod}_S\Gamma(O, M_w;S)<\mathrm{mod}_S\Gamma(O, M; S).\end{align*} $$

This completes the proof.

Lemma 4.3. Let $v,w\in A^*$ , $v\neq w$ . If $\mbox {int}(D_v)\cap \mbox {int}(D_w)=\emptyset $ or $D_v\supset D_w$ , then

$$ \begin{align*} \mathrm{mod}_{S}\Gamma(I_v, M_w; S)<\mathrm{mod}_{S}\Gamma(O,M; S) \end{align*} $$

for each pair $I, M\in \mathcal {C}_1(S)$ .

Proof. It follows by the same argument as that of Lemma 4.2.

Lemma 4.4. Suppose in addition that S is balanced. If $v,w\in A^*$ , $v\neq w$ , then

$$ \begin{align*} \mathrm{mod}_{S}\Gamma(I_v, M_w;S)<\mathrm{mod}_{S}\Gamma(O,M;S) \end{align*} $$

for each pair $I, M\in \mathcal {C}_1(S)$ .

Proof. Since $\mbox {int}(D_w)\cap \mbox {int}(D_v)=\emptyset $ or $D_w\subset D_v$ or $D_v\subset D_w$ by the similarity of S, one has by Lemma 4.3 and the balance of S,

$$ \begin{align*} \mathrm{mod}_{S}\Gamma(I_v, M_w;S) &< \max\{\mathrm{mod}_{S}\Gamma(O,I;S),\ \mathrm{mod}_{S}\Gamma(O,M;S)\} \\ &= \mathrm{mod}_{S}\Gamma(O,M;S), \end{align*} $$

as desired.

5 Proof of Theorem 1.4

Let S be a balanced self-similar quasi-round carpet with IFS $\Phi =\{\phi _1, \ldots ,\phi _n\}$ . We are going to prove Theorem 1.4. Let $g\in \mbox {QS}(S)$ .

Claim 5.1. $g(O)\in \{O\}\cup \mathcal {C}_1(S)$ .

Proof of Claim 5.1

We argue by contradiction and assume that $g(O)\notin \{O\}\cup \mathcal {C}_1(S)$ . Since $g(O)$ is a peripheral circle of the carpet S, by Lemma 4.1, there is a peripheral circle $M\in \mathcal {C}_1(S)$ and a word $w\in A^*$ , $w\neq \varepsilon $ , such that $g(O)=M_w$ .

Let $J\in \mathcal {C}_1(S)$ be fixed. If $g(J)=O$ , one has by Lemmas 3.3 and 4.2,

$$ \begin{align*} \mbox{mod}_S\Gamma(O, J; S)=\mbox{mod}_S\Gamma(M_w, O;S) < \mbox{mod}_S\Gamma(M, O; S), \end{align*} $$

contradicting the balance of S. If $g(J)=I_v$ for some $I\in \mathcal {C}_1(S)$ and some $v\neq w$ , one has by Lemmas 3.3 and 4.4,

$$ \begin{align*} \mbox{mod}_S\Gamma(O, J; S) =\mbox{mod}_S\Gamma(M_w, I_v;S)<\mbox{mod}_S\Gamma(O,I;S), \end{align*} $$

which is also a contradiction. Thus, $g(J)=I_w$ for some $I\in \mathcal {C}_1(S)$ .

It then follows that

$$ \begin{align*} \{g(O)\}\cup\{g(J):J\in \mathcal{C}_1(S)\}\subset\{I_w:I\in \mathcal{C}_1(S)\}, \end{align*} $$

giving $\#\mathcal {C}_1(S)+1\leq \mathcal {C}_1(S)$ , which is a contradiction. The proof of Claim 5.1 is completed.

Claim 5.2. $g(M)\in \{O\}\cup \mathcal {C}_1(S)$ for each $M\in \mathcal {C}_1(S)$ .

Proof of Claim 5.2

We argue by contradiction and assume that there exists a peripheral circle $M\in \mathcal {C}_1(S)$ such that $g(M)\notin \{O\}\cup \mathcal {C}_1(S)$ . Then, there is a peripheral circle $I\in \mathcal {C}_1(S)$ and a word $w\in A^*$ , $w\neq \varepsilon $ such that $g(M)=I_w$ .

Since Claim 5.1 is proved, one has $g(O)=O$ or $g(O)\in \mathcal {C}_1(S)$ . If $g(O)=O$ , one has by Lemmas 3.3 and 4.2,

$$ \begin{align*}\mbox{mod}_{S}\Gamma(O,M;S)=\mbox{mod}_{S}\Gamma(O,I_w;S)<\mbox{mod}_{S}\Gamma(O,I;S),\end{align*} $$

which contradicts the balance of S. If $g(O)\in \mathcal {C}_1(S)$ , one has by Lemmas 3.3 and 4.4,

$$ \begin{align*}\mbox{mod}_{S}\Gamma(O,M;S)=\mbox{mod}_{S}\Gamma(g(O),I_w;S)<\mbox{mod}_{S}\Gamma(O,I;S),\end{align*} $$

which is also a contradiction. This proves Claim 5.2.

By Claims 5.1 and 5.2, we get

(2) $$ \begin{align} \{g(O)\}\cup\{g(M): M\in \mathcal{C}_1(S)\}=\{O\}\cup \mathcal{C}_1(S). \end{align} $$

Next, we show that the group $\mbox {QS}(S)$ is finite. Let G be the group of all orientation- preserving quasisymmetric self-homeomorphisms of S. It suffices to show that G is finite.

Case 1. $\#\mathcal {C}_1(S)=1$ , say $\mathcal {C}_1(S)=\{M\}$ . In this case, S has only one peripheral circle M of first generation. Let

$$ \begin{align*}G_0=\{g\in G: g(O)=O,\ g(M)=M\}\end{align*} $$

and

$$ \begin{align*}P=\{g\in G: g(O)=M,\ g(M)=O\}.\end{align*} $$

Since equation (2) is proved, one has $G=G_0\cup P$ . By Lemma 2.3, $G_0$ is a finite cyclic group. However, if $P\neq \emptyset $ , one has $P=gG_0$ for an arbitrarily given $g\in P$ . Thus, either $\#P=0$ or $\#P=\#G_0$ . It follows that G is finite.

Case 2. $\#\mathcal {C}_1(S)>1$ . In this case, let $M,M'\in \mathcal {C}_1(S)$ , $M\neq M'$ , be given. By equation (2), each $g\in G$ is a solution of an equation system of the form

$$ \begin{align*} g(O)=C_1,\ g(M)=C_2,\ g(M')=C_3, \end{align*} $$

where $C_1, C_2, C_3$ are three distinct peripheral circles in $\{O\}\cup \mathcal {C}_1(S)$ . Since there are only finitely many such equation systems and each of them has at most one solution in G by Lemma 2.2 (three circle theorem), we get that G is finite. The proof of Theorem 1.4 is completed.

By the proof of Theorem 1.4, we have the following result.

Corollary 5.3. Let S be a balanced self-similar quasi-round carpet and $g\in \mbox {QS}(S)$ . Then,

$$ \begin{align*} \{g(O)\}\cup\{g(M): M\in \mathcal{C}_1(S)\}=\{O\}\cup \mathcal{C}_1(S). \end{align*} $$

6 Proof of Theorem 1.6

Denote by $\gamma _0$ and $\gamma _1$ the diagonals of the unite square Q passing through the vertices $0$ and $1$ , respectively. Denote by $\gamma _h$ and $\gamma _v$ the horizontal and vertical median lines of Q. Denote by $R_0,R_1$ , $R_h$ , and $R_v$ the reflections in $\gamma _0$ , $\gamma _1$ , $\gamma _h$ , and $\gamma _v$ . Denote by $r_{\pi /2}$ , $r_{\pi }$ , and $r_{3\pi /2}$ the rotations of angles $\pi /2$ , $\pi $ , and $3\pi /2$ around the center of $ Q $ .

Let S be a symmetric self-similar Q-carpet with IFS $\Phi $ . Suppose that S satisfies the condition of Theorem 1.6. Let $M\in \mathcal {C}_1(S)$ be a peripheral circle such that $M\cap \gamma _0\neq \emptyset $ . Since S is symmetric and $\mathcal {C}_1(S)=4$ , we may write

$$ \begin{align*}\mathcal{C}_1(S)=\{M, C_1,C_2,C_3\},\end{align*} $$

where $C_1,C_2,C_3$ satisfy

$$ \begin{align*}C_1=r_{\pi/2}(M),\quad C_2=r_{\pi}(M),\quad \mbox{and}\quad C_3=r_{3\pi/2}(M).\end{align*} $$

It is clear that

$$ \begin{align*}R_0(M)=M,\quad R_0(C_2)=C_2,\quad C_1=R_v(M), \quad \mbox{and}\quad C_3=R_v(C_2).\end{align*} $$

By symmetry, $M\cap \gamma _0$ has exactly two points, so we may write

$$ \begin{align*}M\cap\gamma_0=\{u,v\}.\end{align*} $$

By the condition of Theorem 1.6, we may assume without loss of generality that

$$ \begin{align*}\Phi_u:=\{\phi\in\Phi: u\in\phi( Q )\}\end{align*} $$

is homogeneous and of $\#\Phi _u=3$ .

Lemma 6.1. If $f\in \mbox {QS}(S)$ , then $f(u)\neq 0$ .

Proof. Let $\psi $ be the contractive similarity in $\Phi $ with $0\in \psi (Q)$ and let c be its ratio. By the symmetry of S, if p is a vertex of Q and $\phi \in \Phi $ satisfying $p\in \phi (Q)$ , then the ratio of $\phi $ is equal to c. Let

$$ \begin{align*}W(S,0):=\{\infty\}\cup\bigcup_{n=0}^\infty c^{-n}S\end{align*} $$

be a weak tangent of S at $0$ .

Let

$$ \begin{align*}N(u)=\bigcup_{\phi\in\Phi_u}\phi(S).\end{align*} $$

Then, $N(u)$ is a relative neighborhood of u in S. Noticing that $\Phi _u$ is homogeneous and that u is a vertex of $\phi (Q)$ for each $\phi \in \Phi _u$ , one has by the self-similarity and the symmetry of S,

$$ \begin{align*}c^{-n}(N(u)-u)\subset c^{-n-1}(N(u)-u).\end{align*} $$

Let

$$ \begin{align*}W(S,u):=\{\infty\}\cup\bigcup_{n=0}^\infty c^{-n}(N(u)-u)\end{align*} $$

be a weak tangent of S at u. By the homogeneity of $\Phi _u$ , we see that $W(S,u)$ is similar to

$$ \begin{align*}W(S,0)\cup e^{-i\pi/2}W(S,0)\cup e^{i\pi/2}W(S,0).\end{align*} $$

Arguing as that of [Reference Bonk and Merenkov4, Lemma 7.3], we see that there is no quasisymmetric homeomorphism $g:W(S,u)\to W(S,0)$ such that $g(0)=0$ and $g(\infty )=\infty $ .

Now, let $f\in \mbox {QS}(S)$ . If $f(u)=0$ , then, by the argument of [Reference Bonk and Merenkov4, Lemma 7.2], there is a quasisymmetric homeomorphism $g:W(S,u)\to W(S,0)$ such that $g(0)=0$ and $g(\infty )=\infty $ , which is a contradiction. Thus, $f(u)\neq 0$ .

By Lemma 6.1 and the symmetry of S, if $f\in \mbox {QS}(S)$ , then $f(u)$ cannot be any vertex of Q.

Lemma 6.2. If $f{\kern-1pt}\in{\kern-1pt} \mbox {QS}(S)$ is orientation-preserving such that $f(O){\kern-1pt}={\kern-1pt}O$ and $f(M){\kern-1pt}={\kern-1pt}M$ , then f is the identity on S.

Proof. Suppose that $f\in \mbox {QS}(S)$ satisfies the condition of Lemma 6.2. Then, by Corollary 5.3, we have

$$ \begin{align*}f(C_1)\in\{C_1,C_2,C_3\}.\end{align*} $$

If $f(C_1)=C_1$ , one has $f=\mathrm {id}$ by the three circle theorem.

If $f(C_1)=C_2$ , one has

$$ \begin{align*}f(C_2)\in\{C_1,C_3\}.\end{align*} $$

In the case $f(C_2)=C_1$ , one has $f(C_3)=C_3$ , so $f=\text {id}$ by the three circle theorem, which is a contradiction. In the case $f(C_2)=C_3$ , the equalities $f(O)=O$ , $f(C_1)=C_2$ , and $f(C_2)=C_3$ imply

$$ \begin{align*}f(O)=r_{\pi/2}(O),\quad f(C_1)=r_{\pi/2}(C_1),\quad \mbox{and}\quad f(C_2)= r_{\pi/2}(C_2),\end{align*} $$

so $f=r_{\pi /2}$ by the three circle theorem, which contradicts $f(M)=M$ . Thus, the case $f(C_1)=C_2$ is impossible.

Similarly, the case $f(C_1)=C_3$ is impossible. This completes the proof.

By Lemma 6.2 and the symmetry of S, if $f\in \mbox {QS}(S)$ is orientation-preserving such that $f(O)=O$ and $f(C)=C$ for some $C\in \mathcal {C}_1(S)$ , then $f=\text {id}$ .

Lemma 6.3. There is no $f\in \mbox {QS}(S)$ satisfying

(3) $$ \begin{align} f(O)=M \quad \mbox{and}\quad f(M)=O. \end{align} $$

Proof. We argue by contradiction and assume that there is a map $f\in \mbox {QS}(S)$ satisfying equation (3). Then, $f^{-1}\circ R_0\circ f\circ R_0\in \mbox {QS}(S)$ is orientation-preserving and satisfies

$$ \begin{align*}f^{-1}\circ R_0\circ f\circ R_0(O)=O \quad \mbox{and}\quad f^{-1}\circ R_0\circ f\circ R_0(M)=M.\end{align*} $$

By Lemma 6.2, we get $f^{-1}\circ R_0\circ f\circ R_0=\text {id}$ , so $f\circ R_0=R_0\circ f$ , so $f(u)=R_0(f(u))$ , so $f(u)\in O\cap \gamma _0$ , and so $f(u)=0$ or $1+i$ , which contradicts Lemma 6.1. The proof is completed.

Lemma 6.4. There is no $f\in \mbox {QS}(S)$ satisfying $f(O)=M$ .

Proof. We argue by contradiction and assume that there is a map $f\in \mbox {QS}(S)$ such that $f(O)=M$ . Since Corollary 5.3 and Lemma 6.3 are proved, we only need consider the case $f(M)\in \{C_1, C_2, C_3\}$ . By the symmetry of S, we may assume without loss of generality that $f(M)=C_1$ . Then, by Corollary 5.3, there are three possible cases:

$$ \begin{align*}f(C_1)=O,\ f(C_2)=O,\ f(C_3)=O.\end{align*} $$

Case 1. $f(C_1)=O$ . In this case, one has

$$ \begin{align*}f\circ R_v(M)=f(C_1)=O\quad \mbox{and}\quad f\circ R_v(O)=f(O)=M,\end{align*} $$

which contradicts Lemma 6.3.

Case 2. $f(C_2)=O$ . In this case, one has

$$ \begin{align*}f\circ R_1(M)=O\quad \mbox{and}\quad f\circ R_1(O)=M,\end{align*} $$

which contradicts Lemma 6.3.

Case 3. $f(C_3)=O$ . In this case, one has

$$ \begin{align*}f\circ R_h(M)=O\quad \mbox{and}\quad f\circ R_h(O)=M,\end{align*} $$

which contradicts Lemma 6.3.

Thus, $f(O)=M$ is impossible. This completes the proof.

Lemma 6.5. $\mbox {QS}(S)=\mbox {ISO}(S)$ .

Proof. It suffices to show $\mbox {QS}(S)\subseteq \mbox {ISO}(S)$ . Let $f\in \mbox {QS}(S)$ be orientation-preserving. By Lemma 6.4, $f(O)\neq M$ . Since S is symmetric, we further have

$$ \begin{align*}f(O)\not\in \{M, C_1,C_2, C_3\}.\end{align*} $$

It then follows from Corollary 5.3 that $f(O)=O$ .

If $f(M)=M$ , one has $f=\text {id}$ by Lemma 6.2, so $f\in \mbox {ISO}(S)$ .

If $f(M)=C_1$ , one has

$$ \begin{align*}f\circ r_{3\pi/2}(C_1)=C_1\quad \mbox{and}\quad f\circ r_{3\pi/2}(O)=O,\end{align*} $$

so $f\circ r_{3\pi /2}=\text {id}$ by Lemma 6.2, so $f\in \mbox {ISO}(S)$ .

If $f(M)=C_2$ , one has

$$ \begin{align*}f\circ r_{\pi}(C_2)=C_2\quad \mbox{and}\quad f\circ r_{\pi}(O)=O,\end{align*} $$

so $f\circ r_{\pi }=\text {id}$ by Lemma 6.2, so $f\in \mbox {ISO}(S)$ .

If $f(M)=C_3$ , one has

$$ \begin{align*}f\circ r_{\pi/2}(C_3)=C_3\quad \mbox{and}\quad f\circ r_{\pi/2}(O)=O,\end{align*} $$

so $f\circ r_{\pi /2}=\text {id}$ by Lemma 6.2, so $f\in \mbox {ISO}(S)$ .

Therefore, $f\in \mbox {ISO}(S)$ if $f\in \mbox {QS}(S)$ is orientation-preserving. Now, let $f\in \mbox {QS}(S)$ be orientation-reversing. Then, $f\circ R_0\in \mbox {QS}(S)$ is orientation-preserving, so $f\circ R_0\in \mbox {ISO}(S)$ , and so $f\in \mbox {ISO}(S)$ .

Now the proof of Theorem 1.6 is completed.

Acknowledgements

The authors appreciate the referee for their helpful suggestions.

References

Bonk, M.. Quasiconformal geometry of fractals. Proceedings of the International Congress of Mathematicians. Volume II. Ed. M. Sanz-Solé, J. Soria, J. L. Varona and J. Verdera. European Mathematical Society, Zürich, 2006, pp. 13491373.Google Scholar
Bonk, M.. Uniformization of Sierpiński carpets in the plane. Invent. Math. 186 (2011), 559665.CrossRefGoogle Scholar
Bonk, M., Kleiner, B. and Merenkov, S.. Rigidity of Schottky sets. Amer. J. Math. 131 (2009), 409443.CrossRefGoogle Scholar
Bonk, M. and Merenkov, S.. Quasisymmetric rigidity of square Sierpiński carpets. Ann. of Math. (2) 177 (2013), 591643.CrossRefGoogle Scholar
Bonk, M. and Merenkov, S.. Square Sierpiński carpets and lattès maps. Math. Z. 12 (2020), 296.Google Scholar
Falconer, K.. Fractal Geometry: Mathematical Foundations and Applications. John Wiley and Sons, Hoboken, NJ, 1990.Google Scholar
Heinonen, J.. Lectures on Analysis on Metric Spaces (Universitext). Springer-Verlag, New York, 2001.CrossRefGoogle Scholar
Keith, S. and Laakso, T.. Conformal Assouad dimension and modulus. Geom. Funct. Anal. 14 (2004), 12781321.CrossRefGoogle Scholar
Mackay, J., Tyson, J. T. and Wildrick, K.. Modulus and Poincaré inequalities on non-self-similar Sierpiński carpets. Geom. Funct. Anal. 23 (2013), 9851034.CrossRefGoogle Scholar
Merenkov, S.. A Sierpiński carpet with the co-Hopfian property. Invent. Math. 180 (2010), 361388.CrossRefGoogle Scholar
Merenkov, S.. Planar relative Schottky sets and quasisymmetric maps. Proc. Lond. Math. Soc. (3) 104 (2012), 455485.CrossRefGoogle Scholar
Schramm, O.. Transboundary extremal length. J. Anal. Math. 66 (1995), 307329.CrossRefGoogle Scholar
Tukia, P. and Väisälä, J.. Quasisymmetric embeddings of metric spaces. Ann. Acad. Sci. Fenn. Ser. A I Math. 5 (1980), 97114.CrossRefGoogle Scholar
Väisälä, J.. Lectures on $n$ -Dimensional Quasiconformal Mappings. Springer-Verlag, New York, 1971.Google Scholar
Whyburn, G. T.. Topological characterization of the Sierpiński curve. Fund. Math. 45 (1958), 320324.CrossRefGoogle Scholar
Zeng, J. S. and Su, W. X.. Quasisymmetric rigidity of Sierpiński carpets ${F}_{n,p}$ . Ergod. Th. & Dynam. Sys. 35 (2015), 16581680.CrossRefGoogle Scholar
Figure 0

Figure 1 Examples of balanced self-similar quasi-round carpets.

Figure 1

Figure 2 Two carpets not satisfying the conditions of Theorem 1.6.