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Uniform spectral gap and orthogeodesic counting for strong convergence of Kleinian groups

Published online by Cambridge University Press:  04 August 2023

Beibei Liu
Affiliation:
Department of Mathematics, The Ohio State University, Columbus, OH 43210, USA; E-mail: bbliumath@gmail.com
Franco Vargas Pallete
Affiliation:
Department of Mathematics, Yale University, 10 Hillhouse Ave., New Haven, CT 06511, USA; E-mail: franco.vargaspallete@yale.edu

Abstract

We show convergence of small eigenvalues for geometrically finite hyperbolic n-manifolds under strong limits. For a class of convergent convex sets in a strongly convergent sequence of Kleinian groups, we use the spectral gap of the limit manifold and the exponentially mixing property of the geodesic flow along the strongly convergent sequence to find asymptotically uniform counting formulas for the number of orthogeodesics between the convex sets. In particular, this provides asymptotically uniform counting formulas (with respect to length) for orthogeodesics between converging Margulis tubes, geodesic loops based at converging basepoints, and primitive closed geodesics.

Type
Dynamics
Creative Commons
Creative Common License - CCCreative Common License - BY
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Copyright
© The Author(s), 2023. Published by Cambridge University Press

1 Introduction

The critical exponent of a discrete isometry subgroup of the hyperbolic space $\mathbb {H}^{n}$ is an important numerical invariant which relates the dynamical properties of the group action to the measure theory and the spectrum of operators on the quotient manifold via the celebrated work of Patterson and Sullivan [Reference PattersonPat76, Reference SullivanSul79, Reference SullivanSul84]. More explicitly, this invariant was shown to be equal to the Hausdorff dimension of the limit set for any geometrically finite discrete isometry subgroup $\Gamma $ [Reference SullivanSul79, Reference SullivanSul84], and is related to the bottom spectrum $\lambda _{0}$ of the negative Laplace operator for any nonelementary complete hyperbolic manifold [Reference SullivanSul87]. A natural line of inquiry is to ask whether this quantitative invariant can be uniformly controlled for a sequence of hyperbolic manifolds $(M_k=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ , for example, sequences of quasi-Fuchsian manifolds in Bers’s model for the Teichmüller space of a surface S. It turns out that the critical exponent of $\Gamma _{k}$ , the Hausdorff dimension of the limit set, and the bottom of the spectrum $\lambda _{0}(\mathbb {H}^{n}/ \Gamma _{k})$ , converge to the ones of the limit group $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ under the assumption that $\Gamma $ is geometrically finite and $\delta (\Gamma )>(n-1)/2$ for strongly convergent sequences of hyperbolic manifolds $(M_k)_{k\in \mathbb N}$ [Reference Canary and TaylorCT99, Reference McMullenMcM99]. See Section 2.5 for the definition of strong convergence.

Besides the bottom spectrum of the quotient manifold, there are finitely many small eigenvalues of the negative Laplace operator in the interval $[\lambda _{0}, (n-1)^{2}/4]$ , where $(n-1)^{2}/4$ is the bottom spectrum of the hyperbolic space $\mathbb {H}^{n}$ [Reference Lax and PhillipsLP82]. It is natural to ask whether these small eigenvalues converge to the ones of $\Gamma $ , respectively. We prove the convergence of small eigenvalues for strongly convergent sequences of hyperbolic manifolds $(M_k=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ . In particular, we give a uniform bound on the Lax-Phillips spectral gap $s_1$ defined by $s_1:=\min \lbrace \lambda _1(M), (n-1)^2/4\rbrace - \lambda _0(M)$ , where $\lambda _{1}(M)$ is the smallest eigenvalue of the negative Laplacian in $(\lambda _{0}(M), \infty )$ .

Theorem 1.1. Suppose that $(M_k=\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})/ \Gamma _k)_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which converges strongly to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ . The set of small eigenvalues in $[\lambda _{0}(M_k), (n-1)^{2}/4]$ converges to the small eigenvalues of the limit manifold M, counting multiplicities. In particular, the sequence of Lax-Phillips spectral gaps of $(M_k)_{k\in \mathbb N}$ converges to that of the limit manifold M.

Remark 1.2. We explain what the convergence of the set of small eigenvalues means in Section 3, and leave the precise statement in Theorem 3.3. The statement of Theorem 1.1 for small eigenvalues holds for negatively pinched manifolds, and the details are discussed in Section 3. The statement referring to Lax-Phillips spectral gap is done in Theorem 3.4 for Kleinian groups. It could be possible that the set of small eigenvalues is equal to the singleton $\lbrace (n-1)^2/4\rbrace $ (or the empty set by considering pinched negative manifolds), but it won’t affect the statement of the theorem.

Sequences of hyperbolic manifolds with uniform spectral gap are interesting to study, as the uniform spectral gap sometimes controls the dynamical properties of the geodesic flow of the manifold. For instance, following [Reference Edwards and OhEO21], uniform spectral gaps of hyperbolic manifolds imply uniform exponential mixings of geodesic flows. In the same paper, they provided another family of hyperbolic manifolds with uniform spectral gaps, coming from congruence subgroups of certain arithmetic lattice of $\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ .

The exponentially mixing geodesic flow can be used to find good estimates for error in asymptotic approximations of counting functions, such as the estimates available for orthogeodesic counting (as done in [Reference Parkkonen and PaulinPP17]). Namely, given $D^-,D^+$ (locally) convex sets (or equivalently, $\pi _1(M)$ precisely invariant convex sets in the universal covering) in M, one can estimate $\mathcal {N}_{D^-,D^+}(t)$ , the number of orthogeodesics between $D^-$ and $D^+$ of length less than $t>0$ , by

$$\begin{align*}\mathcal{N}_{D^-,D^+}(t) \approx Ae^{\delta t}(1+O(e^{-\kappa t})) ,\end{align*}$$

where $A,\delta ,\kappa $ and $O(.)$ depend on the geometric/dynamical features of $M, D^-, D^+$ , with exponential decay of correlations among these features. We consider the following two interesting cases in this paper:

  1. 1. $D^{\pm }$ are connected components in the thin part of M, that is, Margulis tubes or cusps.

  2. 2. $D^{+}=D^{-}$ is an embedded ball at a given point $x\in M$ . That is, the lifts of $D^{\pm }$ are sufficiently small balls of lifts of x in $\mathbb {H}^{n}$ .

The uniform orthogeodesic counting formula for strongly convergent sequences in case (1) can be used in the study of the renormalized volume. Given a hyperbolic manifold M, the renormalized volume is a function on the deformation space of M whose gradient flow has been of interest (see [Reference Bridgeman, Brock and BrombergBBB19], [Reference Bridgeman, Bromberg and Vargas PalleteBBP21]). In [Reference Bridgeman, Bromberg and Vargas PalleteBBP21], it is shown that for M acylindrical, the gradient flow of the renormalized volume converges to the unique critical point. This involves discarding strong limits with pinched rank- $1$ cusps by the use of the Gardiner formula. For such a method to work, one needs a uniform control of contributing terms in the Gardiner formula, which would be provided by uniform orthogeodesic counting. The uniform orthogeodesic counting formula for case (2) gives a uniform asymptotic counting result with uniform error term for geodesic loops based on a given point in M. Motivated by these applications, we show that the parameters $A,\delta ,\kappa $ , and $O(.)$ are uniform for strongly convergent sequences, and such parameters can be taken arbitrarily close to the corresponding parameters of the geometrically finite limit.

Theorem 1.3. Let $(M_{k}=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ be a sequence of hyperbolic manifolds which strongly converges to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/\Gamma $ with $\delta (\Gamma )>(n-1)/2$ .

  1. 1. Suppose that $D^{\pm }_{k}$ are connected components in the thin part of $M_k$ , and $(D^{\pm }_{k})_{k\in \mathbb N}$ converge strongly to connected components $D^{\pm }$ in the thin part of M. Then there is a uniform counting formula for orthogeodesics between $D^{-}_{k}$ to $D^{+}_{k}$ for the sequence $(M_k)_{k\in \mathbb {N}}$ .

  2. 2. Suppose that $(x_k\in M_k)_{k\in \mathbb {N}}$ is a sequence of points converging to the point $x\in M$ . Then there is a uniform counting formula for geodesic loops based at $x_k$ for the sequence $(M_k)_{k\in \mathbb {N}}$ .

Remark 1.4. We in fact prove the result for strongly convergent sequences of well-positioned convex sets in a strongly convergent sequence of hyperbolic manifolds (Theorem 5.3). We refer readers to Section 2.5 for the definitions of well-positioned and strong convergence of convex sets in hyperbolic manifolds.

The counting of primitive closed geodesics follows from the counting of geodesic loops in manifolds with negatively pinched curvatures [Reference RoblinRob03, Chapter 5]. Hence, we obtain the following asymptotic counting of primitive closed geodesics along sequences of strongly convergent hyperbolic manifolds.

Corollary 1.5. Suppose that $(M_{k}=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which strongly converges to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ with $\delta (\Gamma )>(n-1)/2$ . Then we can count the number of primitive closed geodesics with length less than $\ell $ in $M_k$ , denoted by $\#\mathcal {G}_{M_k}(\ell )$ , uniformly, in the sense that

$$\begin{align*}\#\mathcal{G}_{M_k}(\ell) \approx \frac{e^{\delta(\Gamma_k)\ell}}{\delta(\Gamma_k)\ell} \end{align*}$$

up to a multiplicative error uniformly close to 1 along the sequence as $\ell $ gets larger and $\lim _k \delta (\Gamma _k) = \delta (\Gamma )$ .

The proof of Theorem 1.3 involves the uniformity of the exponential mixing and the convergence of certain measures for strongly convergent sequences. These measures refer to the classical Patterson-Sullivan measures, the Bowen-Margulis measure, and the skinning measures. The convergence of Patterson-Sullivan measures has been proved for strongly convergent sequences under the assumption that the limit manifold is geometrically finite, and its critical exponent is greater than $(n-1)/2$ , [Reference McMullenMcM99]. The Bowen-Margulis measure and the skinning measures are defined in terms of the Patterson-Sullivan measures. Answering a question of Oh, we prove the convergence of these two measures, which could have its own interest.

Proposition 1.6. Suppose that $(M_k=\mathbb {H}^{n}/ \Gamma _k)_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which are strongly convergent to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ with $\delta (\Gamma )>(n-1)/2$ . For $r>0$ , we denote by $M_{k}^{<r}\subset M_k, M^{<r}\subset M$ the sets of points with injectivity radius less than r. Then the Bowen-Margulis measures $m_{\mathrm {{BM}}}^{k}$ on $T^{1}M_k^{<r}$ converge to the one on $T^{1}M^{<r}$ weakly. Moreover, we have the convergence of total masses.

Remark 1.7. The convergence of the Bowen-Margulis measures on $T^{1}M_{k}^{<r}$ might be helpful for proving that the Benjamini-Schramm limit of $(M_k)_{k\in \mathbb N}$ is also M (see, for instance [Reference Abert, Bergeron, Biringer, Gelander, Nikolav, Raimbault and SametABB+17, Section 3.9] for a general definition of Benjamini-Schramm convergence).

We now discuss the convergence of skinning measures $\sigma ^{\pm }$ for the special type of well-positioned convex sets in hyperbolic manifolds. Geodesic balls with sufficiently small radii and the thin part in hyperbolic manifolds are well-positioned. We refer readers to Section 2.5 for the definition and detailed discussions.

Corollary 1.8. Suppose that $(M_k=\mathbb {H}^{n}/\Gamma _k)_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds that strongly converges to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ with $\delta (M)>(n-1)/2$ . Let $D_k\subset M_k, D\subset M$ be well-positioned convex sets, so that $(D_k)_{k\in \mathbb N}$ strongly converges to D. Then

$$\begin{align*}\Vert\sigma^{\pm}_{\partial D_k}\Vert \rightarrow \Vert\sigma^{\pm}_{\partial D}\Vert.\end{align*}$$

The relative result also holds for subsets $\Omega _k\subseteq D_k,\, \Omega \subseteq D$ so that $(\Omega _k)_{k\in \mathbb N}$ strongly converges to $\Omega $ .

Organization of the paper

We review definitions of geometric finiteness, the Bowen-Margulis measure, and skinning measures in Sections 2.1, 2.3, 2.4, respectively. Section 2.2 is about the relation between the critical exponent and the bottom spectrum. Section 2.5 defines strong convergence of hyperbolic manifolds and the convergence of well-positioned convex sets. Section 3 discusses small eigenvalues of the negative Laplacian on negatively pinched Hadamard manifolds and gives a proof of Theorem 1.1. In Section 4, we prove the convergence results of the Bowen-Margulis measure and the skinning measures, that is, Proposition 1.6 and Corollary 1.8. The last section, Section 5, proves the uniform asymptotic counting results of geodesic loops and orthogeodesics along strongly convergent sequences, that is, the proof of Theorem 1.3.

2 Background

2.1 Geometric finiteness

In this subsection, we let X denote an n-dimensional negatively pinched Hadamard manifold whose sectional curvatures lie between $-\kappa ^{2}$ and $-1$ for some $\kappa \geq 1$ . For any isometry $\gamma \in \operatorname {\mathrm {Isom}}(X)$ , we define its translation length $\tau (\gamma )$ as follows:

$$ \begin{align*}\tau(\gamma):=\inf_{p\in X} d_{X}(p, \gamma(p)),\end{align*} $$

where $d_{X}$ is the Riemannian distance function in X. Based on the translation length, we can classify isometries in X into three types; we call $\gamma $ loxodromic if $\tau (\gamma )>0$ . In this case, the infimum is attained exactly when the points are on the axis of $\gamma $ . The isometry $\gamma $ is called parabolic if $\tau (\gamma )=0$ and the infimum is not attained. The isometry $\gamma $ is elliptic if $\tau (\gamma )=0$ and the infimum is attained.

From now on, we consider torsion-free discrete isometry subgroups $\Gamma <\operatorname {\mathrm {Isom}}(X)$ , that is, $\Gamma $ contains no elliptic elements. If $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ is a torsion-free discrete isometry subgroup, we call it a Kleinian group. Given $0<\epsilon <\epsilon (n, \kappa )$ , where $\epsilon (n, \kappa )$ is the Margulis constant depending on the dimension n and the constant $\kappa $ , let $\mathcal {T}_{\epsilon }(\Gamma )$ be the set consisting of all points $p\in X$ , such that there exists an isometry $\gamma \in \Gamma $ with

$$ \begin{align*}d(p, \gamma p)\leq \epsilon.\end{align*} $$

It is an $\Gamma $ -invariant set, and the quotient $\mathcal {T}_{\epsilon }(\Gamma )/ \Gamma $ is the thin part of the quotient manifold $M=X/ \Gamma $ , denoted by $M^{<\epsilon }$ .

A subgroup $P<\Gamma $ is called parabolic if the fixed point set of P consists of a single point $\xi \in \partial _{\infty } X$ , where $\partial _{\infty } X$ is the visual boundary of X. Note that $\mathcal {T}_{\epsilon }(P)\subset X$ is precisely invariant under P, that is, $\operatorname {\mathrm {stab}}_{\Gamma }(\mathcal {T}_{\epsilon }(P))=P$ [Reference BowditchBow95, Corollary 3.5.6]. By abuse of notation, we can regard $\mathcal {T}_{\epsilon }(P)$ as a subset of $M=X/ \Gamma $ , which is called a Margulis cusp. The union of all Margulis cusps consists of the cuspidal part of M, denoted by $\operatorname {\mathrm {cusp}}_{\epsilon }(M)$ .

The limit set $\Lambda (\Gamma )$ of a discrete, torsion-free isometry subgroup $\Gamma <\operatorname {\mathrm {Isom}}(X)$ is defined to be the set of accumulation points of a $\Gamma $ -orbit $\Gamma (p)$ in $\partial _{\infty } X$ for any point $p\in X$ . We call $\Gamma $ elementary if $\Lambda (\Gamma )$ is finite; otherwise, we say $\Gamma $ is nonelementary. For any two points $\xi $ and $\eta $ in $\partial _{\infty } X$ , we use $\xi \eta $ to denote the unique geodesic in X connecting these two points. The convex hull of $\Lambda (\Gamma )\subset \partial _{\infty } X$ is the smallest closed convex subset in X whose accumulation set is $\Lambda (\Gamma )$ , denoted by $\operatorname {\mathrm {Hull}}(\Gamma )$ . We let $C(M)=\operatorname {\mathrm {Hull}}(\Gamma )/ \Gamma $ denote the convex core of quotient manifold $M=X/ \Gamma $ . For any constant $\epsilon>0$ , we define the truncated core by

$$ \begin{align*}C(M)^{>\epsilon}=C(M)-M^{<\epsilon}.\end{align*} $$

Given a constant $0<\epsilon <\epsilon (n, \kappa )$ , a discrete isometry subgroup $\Gamma $ is geometrically finite if the truncated core $C(M)^{>\epsilon }$ is compact in $M=X/ \Gamma $ . If, in addition, $C(M)$ is compact, that is, $\Gamma $ contains no parabolic isometries, then $\Gamma $ is called convex cocompact. Furthermore, if $\Gamma <\operatorname {\mathrm {Isom}}(X)$ is geometrically finite, the parabolic fixed points in $\Lambda (\Gamma )$ are bounded, defined as follows:

Definition 2.1. [Reference BowditchBow93] A parabolic fixed point $\xi \in \Lambda (\Gamma )$ is bounded if $(\Lambda (\Gamma )\setminus \{p\})/ \operatorname {\mathrm {stab}}_{\Gamma }(p)$ is compact.

Given a point $x\in X$ and a discrete isometry group $\Gamma \in \operatorname {\mathrm {Isom}}(X)$ , the Poincaré series is defined as

$$ \begin{align*}P_{s}(\Gamma, x)=\sum_{\gamma\in \Gamma} e^{-sd_{X}(x, \gamma x)}.\end{align*} $$

The critical exponent of $\Gamma $ is defined as

$$ \begin{align*}\delta(\Gamma):=\inf\{s \mid P_{s}(\Gamma, x)<\infty\}.\end{align*} $$

It is not hard to see that the definition of $\delta (\Gamma )$ is independent of the choice of x.

2.2 Eigenvalues and spectrum

As in Section 2.1, we let $M=X/ \Gamma $ , where X is a negatively pinched Hadamard manifold, and $\Gamma $ is a torsion-free discrete isometry subgroup. Define the Sobolev space $H^1(M)$ as the space obtained by the completion of $C^\infty _0(M)$ with respect to the norm $\Vert f\Vert =\sqrt {\int _M|f|^2 + \int _M|\nabla f|^2}$ . This space can be also defined as functions in $L^2(M)$ whose weak derivative (in the sense of distributions) is also in $L^2(M)$ .

Given $f\in H^1(M)$ , we define the Rayleigh quotient $R(f)$ of f by

$$\begin{align*}R(f) = \frac{\int_M|\nabla f|^2}{\int_M|f|^2}. \end{align*}$$

The Rayleigh quotient is closely related to the spectrum $Spec(M)$ of the negative Laplace operator. Namely, by posing the following minimization problem

$$\begin{align*}\lambda=\inf \bigg\lbrace R(f)\,\bigg|\, f\in H^1(M) \bigg\rbrace ,\end{align*}$$

we obtain a $L^2$ integrable smooth function f satisfying $-\Delta f = \lambda f$ .

We let $\lambda _{0}(M)$ denote the bottom of the spectrum, and we say that $\lambda \in Spec(M)$ is a small eigenvalue of M if $\lambda <(n-1)^2/4$ . Moreover, given a constant $\mu <(n-1)^2/4$ , we define $Spec_\mu (M)$ as the collection (counting multiplicities) of eigenvalues of the negative Laplacian on M less than or equal to $\mu $ . The set of small eigenvalues is a finite set (see [Reference HamenstädtHam04]).

In the rest of the subsection, we list several properties of the bottom of the spectrum $\lambda _{0}(M)$ . We will use these properties in Section 3 to prove the uniform spectral gap for strongly convergent sequences of geometrically finite groups $(\Gamma _{k}<\operatorname {\mathrm {Isom}}(X))_{k\in \mathbb N}$ .

Lemma 2.2. [Reference HamenstädtHam04] Let $\Gamma <\operatorname {\mathrm {Isom}}(X)$ be a torsion-free discrete elementary isometry subgroup of a negatively pinched Hadamard manifold X with dimension n. Then $\lambda _0(X/\Gamma )\geq (n-1)^2/4$ .

Lemma 2.3. [Reference HamenstädtHam04, Lemma 2.3] Suppose that $\Gamma <\operatorname {\mathrm {Isom}}(X)$ is a geometrically finite discrete isometry subgroup of a negatively pinched Hadamard manifold X with dimension n. Then for every $r>0$ , we have that $\mu _1(M\setminus B_r(C(M)))\geq (\tanh r)^2(n-1)^2/4$ , where $M=X/ \Gamma $ and $\mu _1(M\setminus B_r(C(M)))$ denotes the smallest Rayleigh quotient for all smooth functions f with compact support in $M\setminus B_r(C(M))$ .

If $X=\mathbb {H}^{n}$ , we have the following result relating $\lambda _{0}(M)$ to the critical exponent $\delta (\Gamma )$ .

Theorem 2.4. [Reference SullivanSul87] For any nonelementary complete hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ , one has

$$ \begin{align*} \lambda_{0}(M)= \begin{cases} (n-1)^{2}/4 &\text{if }\delta(\Gamma)\leq (n-1)/2,\\ \delta(\Gamma)(n-1-\delta(\Gamma)) &\text{if }\delta(\Gamma)\geq (n-1)/2. \end{cases} \end{align*} $$

2.3 Patterson-Sullivan measure

Given a point $p\in \mathbb {H}^{n}$ , and $\xi \in \partial _{\infty } \mathbb {H}^{n}$ , the Busemann function $B(x, \xi )$ on $\mathbb {H}^{n}$ with respect to p is defined by

$$ \begin{align*}B(x, \xi)=\lim_{t\rightarrow \infty} (d(x, \rho_{\xi}(t))-t),\end{align*} $$

where $\rho _{\xi }(t)$ is the unique geodesic ray from p to $\xi $ . The Busemann cocycle $\beta _{\xi }(x, y): \mathbb {H}^{n}\times \mathbb {H}^{n}\times \partial _{\infty } \mathbb {H}^{n}\rightarrow \mathbb {R}$ is defined by

$$ \begin{align*}\beta_{\xi}(x, y)=\lim_{t\rightarrow \infty} (d(\rho_{\xi}(t), x)-d(\rho_{\xi}(t), y)).\end{align*} $$

For a discrete isometry subgroup $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ , there exists a family of finite measures $(\mu _{x})_{x\in \mathbb {H}^{n}}$ on $\partial _{\infty } \mathbb {H}^{n}$ whose support is the limit set $\Lambda (\Gamma )$ and satisfies the following conditions:

  1. 1. It is $\Gamma $ -invariant, that is, $\gamma _{\ast }(\mu _{x})=\mu _{\gamma x}$ .

  2. 2. The Radon-Nikodym derivatives exist for all $x, y\in \mathbb {H}^{n}$ , and for all $\xi \in \partial _{\infty } \mathbb {H}^{n}$ , they satisfy

    $$ \begin{align*}\dfrac{d\mu_{x}}{d\mu_{y}}(\xi)=e^{-\delta(\Gamma) \beta_{\xi}(x, y)}.\end{align*} $$

Such family of measures is a family of Patterson-Sullivan density of dimension $\delta (\Gamma )$ for $\Gamma $ . The Patterson-Sullivan measures have very nice properties when the group $\Gamma $ is geometrically finite.

Theorem 2.5. [Reference McMullenMcM99, Theorem 3.1] Let $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ be a geometrically finite Kleinian group. Then $\partial _{\infty }\mathbb {H}^{n}$ carries a unique $\Gamma $ -invariant density $\mu $ of dimension $\delta (\Gamma )$ with total mass one. Moreover, $\mu $ is nonatomic and supported on $\Lambda (\Gamma )$ , and the Poincaré series diverges at $\delta (\Gamma )$ .

Theorem 2.6. [Reference McMullenMcM99, Theorem 1.2] Suppose that $(\Gamma _{k}<\operatorname {\mathrm {Isom}}(\mathbb {H}^{n}))_{k\in \mathbb N}$ is a sequence of Kleinian groups converging strongly to $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ . If $\Gamma $ is geometrically finite with $\delta (\Gamma )>(n-1)/2$ , then the Patterson-Sullivan densities $\mu _{k}$ of $\Gamma _{k}$ converge to the Patterson-Sullivan density $\mu $ of $\Gamma $ in the weak topology on measures.

Remark 2.7. Theorem 1.2 in [Reference McMullenMcM99] is stated for the $3$ -dimensional hyperbolic space. However, the proof works exactly the same for general hyperbolic spaces $\mathbb {H}^{n}$ .

The proof Theorem 2.6 relies heavily on the analysis of the Poincaré series of parabolic groups and its uniform convergence. This is also essential in the later proof of the convergence of Bowen-Margulis measures and the uniform counting formulas for orthogeodesics in the rest of the paper. For readers’ convenience, we list the analytic properties of the Poincaré series corresponding to parabolic groups in the section. The details can be found in [Reference McMullenMcM99, Section 6].

Let $L<\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ be a torsion-free elementary isometry subgroup, which is either a hyperbolic group, that is, a cyclic group generated by a loxodromic isometry, or a parabolic group. Given $x\in \partial _{\infty } \mathbb {H}^{n}$ and $s\geq 0$ , the absolute Poincaré series for L is defined to be

$$ \begin{align*}P_{s}(L, x)=\sum_{\gamma\in L} |\gamma'(x)|^{s},\end{align*} $$

where the derivative is measured in the spherical measure. Given any open subset $U\subset \partial _{\infty } \mathbb {H}^{n}$ , define

$$ \begin{align*}P_{s}(L, U, x)=\sum_{\gamma(x)\in U} |\gamma'(x)|^{s}.\end{align*} $$

Suppose that $(L_k<\operatorname {\mathrm {Isom}}(\mathbb {H}^{n}))_{k\in \mathbb {N}}$ is a sequence of torsion-free elementary isometry subgroups which converges geometrically to a parabolic group $L<\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ with parabolic fixed point c, that is, $L_k$ converges to L in the Hausdorff topology on closed subsets of $\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ . The Poincaré series for $(L_k, s_k)$ , where $s_k\geq 0$ converges uniformly if for any compact subset $K\subset \partial _{\infty } \mathbb {H}^{n}\setminus \{c\}$ and $\epsilon>0$ , there is a neighborhood U of c, such that for all $x\in K$ ,

$$ \begin{align*}P_{s_k}(L_k, U, x)<\epsilon\end{align*} $$

for $k\gg 0$ sufficiently large. By using the same argument of the proof of Theorem 6.1 in [Reference McMullenMcM99], we have the following:

Theorem 2.8. Suppose that $(\Gamma _{k}<\operatorname {\mathrm {Isom}}(\mathbb {H}^{n}))_{k\in \mathbb {N}}$ is a sequence of torsion-free discrete isometry subgroups which strongly converges to a geometrically finite torsion-free group $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ . Let $L<\Gamma $ be a parabolic subgroup and $(L_k<\Gamma _k)_{k\in \mathbb {N}}$ be a sequence of elementary groups which converges to L geometrically. If

$$ \begin{align*} \delta(\Gamma)> \begin{cases} 1 &\text{if }n=3,\text{ or}\\ (n-2)/2 &\text{if }n> 3, \end{cases} \end{align*} $$

then the Poincaré series for $(L_k, \delta (\Gamma _k))$ converges uniformly to the one of $(L, \delta (\Gamma ))$ .

2.4 Bowen-Margulis measure

The Bowen-Margulis measure is a measure defined on the unit tangent bundle $T^{1} \mathbb {H}^{n}$ of $\mathbb {H}^{n}$ in terms of the Patterson-Sullivan measures. One can identify the unit tangent bundle $T^{1}\mathbb {H}^{n}$ with the set of geodesic lines $l: \mathbb R\rightarrow \mathbb {H}^{n}$ , such that the inverse map sends the geodesic line l to its unit tangle vector $\dot {l}(0)$ at $t=0$ . Given a point $x_0\in \mathbb {H}^{n}$ , we can also identify $T^{1}\mathbb {H}^{n}$ with $\partial _{\infty } \mathbb {H}^{n}\times \partial _{\infty } \mathbb {H}^{n}\times \mathbb R$ via the Hopf’s parametrization:

$$ \begin{align*}v\rightarrow (v_{-}, v_{+}, t),\end{align*} $$

where $v_{-}, v_{+}$ are the endpoints at $-\infty $ and $\infty $ of the geodesic line defined by v and t is the signed distance of the closest point to $x_{0}$ on the geodesic line.

We let $\pi : T^{1} \mathbb {H}^{n}\rightarrow \mathbb {H}^{n}$ denote the base point projection. The geodesic flow on $T^{1}\mathbb {H}^{n}$ is the smooth one-parameter group of diffeomorphisms $(g^{t})_{t\in \mathbb R}$ of $T^{1} \mathbb {H}^{n}$ , such that $g^{t}(l(s))=l(s+t)$ , for all $l\in T^{1} \mathbb {H}^{n}$ , and $s, t\in \mathbb R$ . Similarly, one can define the geodesic flow on $T^{1}M$ by replacing the geodesic lines l by locally geodesic lines. The Kleinian group $\Gamma $ acts on $T^{1}\mathbb {H}^{n}$ via postcomposition, that is, $\gamma \circ l$ , and it commutes with the geodesic flow. For simplicity, we sometimes write $\delta (\Gamma )$ as $\delta $ if the context is clear in the rest of the paper.

Given the Patterson-Sullivan density $(\mu _{x})_{x\in \mathbb {H}^{n}}$ and a point $x_{0}\in \mathbb {H}^{n}$ , one can define the Bowen-Margulis measure $\tilde {m}_{\mathrm {{BM}}}$ on $T^{1}\mathbb {H}^{n}$ given by

$$ \begin{align*} d\tilde{m}_{\mathrm{{BM}}}(v)&=e^{-\delta(\beta_{v_{-}}(\pi(v), x_{0})+\beta_{v_{+}}(\pi(v), x_{0}))}d\mu_{x_{0}}(v_{-})d\mu_{x_{0}}(v_{+})dt\\&= e^{-2\delta(v_-|v_+)_{x_0}}d\mu_{x_{0}}(v_{-})d\mu_{x_{0}}(v_{+})dt. \end{align*} $$

Here we introduce the notation $(v_-|v_+)_{x_0} = \frac 12 (\beta _{v_{-}}(y, x_{0})+\beta _{v_{+}}(y, x_{0}))$ , where y is any point in the geodesic joining $v_-, v_+$ . It is not hard to verify that $(v_-|v_+)_{x_0}$ does not depend on y.

The Bowen-Margulis measure $\tilde {m}_{\mathrm {{BM}}}$ is independent of the choice of $x_{0}$ , and it is invariant under both the action of the group $\Gamma $ and the geodesic flow. Hence, it descends to a measure $m_{\mathrm {{BM}}}$ on $T^{1}M$ invariant under the quotient geodesic flow, which is called the Bowen-Margulis measure on $T^{1}M$ .

Theorem 2.9. [Reference SullivanSul84, Reference BabillotBab02] Let $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ be a geometrically finite Kleinian group. The Bowen-Margulis measure $m_{\mathrm {{BM}}}$ has finite total mass, and the geodesic flow is mixing with respect to $m_{\mathrm {{BM}}}$ .

Another related measure we consider in the paper is the so-called skinning measure. Let D be a nonempty proper closed convex subset in $\mathbb {H}^{n}$ . We denote its boundary by $\partial D$ and the set of points at infinity by $\partial _{\infty } D$ . Let

(1) $$ \begin{align} P_{D}: \mathbb{H}^{n}\cup (\partial_{\infty} \mathbb{H}^{n}\setminus \partial_{\infty} D)\rightarrow D \end{align} $$

be the closest point map. In particular, for points $x\in \mathbb {H}^{n}$ , $P_{D}(x)$ is the point on D which minimizes the distance function $d(y, x)$ for $y\in D$ , and for points $\xi \in \partial _{\infty }\mathbb {H}^{n}\setminus \partial _{\infty } D$ , $P_{D}(\xi )$ is the point $y\in D$ which minimizes the function $y\rightarrow \beta _{\xi }(y, x_{0})$ for a given $x_{0}$ .

The outer unit normal bundle $\partial ^{1}_{+}D$ of the boundary of D is the topological submanifold of $T^{1}\mathbb {H}^{n}$ consisting of the geodesic lines $v: \mathbb R\rightarrow \mathbb {H}^{n}$ , such that $P_{D}(v_{+})=v(0)$ . Similarly, one can define the inner unit normal bundle $\partial ^{1}_{-} D$ which consists of geodesic lines v such that $P_{D}(v_{-})=v(0)$ . Note that when D is totally geodesic, $\partial ^{1}_{+}D=\partial ^{1}_{-}D$ . Given the Patterson-Sullivan density $(\mu _{x})_{x\in \mathbb {H}^{n}}$ , the outer skinning measure on $\partial ^{1}_{+}D$ is the measure $\tilde {\sigma }^{+}_{D}$ defined by

$$ \begin{align*}d\tilde{\sigma}_{D}^{+}(v)=e^{-\delta\beta_{v_{+}}(P_{D}(v_{+}), x_{0})}d\mu_{x_{0}}(v_{+}).\end{align*} $$

Similarly, one can define the inner skinning measure $\tilde {\sigma }_{D}^{-}$ on $\partial ^{1}_{-}D$ as follows:

$$ \begin{align*}d\tilde{\sigma}_{D}^{-}(v)=e^{-\delta\beta_{v_{-}}(P_{D}(v_{-}), x_{0})}d\mu_{x_{0}}(v_{-}).\end{align*} $$

For simplicity, we sometimes identify a precisely invariant subset $C\subset M=\mathbb {H}^{n}/ \Gamma $ with its fundamental domain $\tilde {C}$ in the universal cover, and use the notation $\sigma ^{\pm }_{\partial C}$ to denote the outer/inner skinning measure $\tilde {\sigma }^{\pm }_{\tilde {C}}$ on $\partial ^{1}_{\pm }\tilde {C}$ .

2.5 Convergence of convex sets

In this subsection, we first define strong convergence that admits disconnected limits. Suppose that $((M_k,g_k))_{k\in \mathbb {N}}$ is a sequence of n-manifolds of pinched sectional curvature $-\kappa ^2\leq K\leq -1$ . We say that the sequence converges strongly to a (possibly disconnected) geometrically finite n-manifold $(N=\cup _{i}^{m} N_i,g)$ if the following holds:

  1. 1. There exist points $p_{k,i}\in M_k$ , $p_{i}\in N_i$ so that $d(p_{k,i}, p_{k,j})\rightarrow +\infty $ for $i\neq j$ and $(M_k,p_{k,i})\rightarrow (N_i,p_i)$ geometrically, that is, there exists an exhaustion $U_{1,i}\subset U_{2,i} \subset \ldots $ of relatively compact open sets of $(N_i,p_i)$ and smooth maps $\varphi _{k,i}:U_{k,i}\rightarrow M_k$ so that $\varphi _{k,i}(p_i) = p_{k,i}$ and $\varphi _{k,i}^*g_k$ converges smoothly in compact sets to g.

  2. 2. For any $\epsilon $ , the truncated cores $C(M_k)^{>\epsilon }$ converge to the disjoint union $\cup _i C(N_i)^{>\epsilon }$ . This means that for large k, we have $C(M_k)^{>\epsilon } = \cup _{i=1}^m C(M_{k,i})^{>\epsilon }$ , where $C(M_{k,i})^{>\epsilon }\subset Im(\varphi _{k,i})$ and $\varphi ^{-1}_{k,i}(C(M_{k,i})^{>\epsilon })$ converges to $C(N_i)^{>\epsilon }$ in the Hausdorff topology of compact sets in $N_i$ .

The definition accommodates situations like Dehn drilling and pinching closed geodesics in hyperbolic 3-manifolds. The pinching case can result in disconnected limit manifolds. If $M_k$ and N are hyperbolic manifolds, and N is connected, this definition is equivalent to the one described in [Reference McMullenMcM99] for strong convergence. Because of this, in the cases when N is connected, we will simply omit the mention of possibly disconnected, as well as the subindex i from our notation.

Moreover, given a sequence $(M_k)_{k\in \mathbb {N}}$ converging strongly to a possibly disconnected manifold N, we say that the sequence of functions $(f_k:M_k\rightarrow \mathbb {R})_{k\in \mathbb N}$ converges strongly to a function $f:N\rightarrow \mathbb {R}$ if, with the notation above, we have that for any base point $p_i$ the sequence $(f_k\circ \varphi _{k,i})_{k\in \mathbb N}$ converges smoothly in compact sets to f. Similarly, if $\Sigma _k,\Sigma $ are smooth properly embedded submanifolds in $M_k, N$ , we say that $(\Sigma _k)_{k\in \mathbb N}$ converges strongly to $\Sigma $ if $\varphi _{k,i}^{-1}(\Sigma _k)$ converges smoothly in compact sets to $\Sigma $ . Since for any fixed compact set in $N_i$ the maps $\varphi _{k, i}$ are embeddings for k sufficiently large, we can define strong convergence of functions and submanifolds of $T^1 M_k$ to $T^1 M$ by composing the derivatives of $\varphi _{k, i}$ with the projections from $T^{*}M_k$ to $T^1 M_k$ .

Using the definition of strong convergence, we obtain a straightforward corollary:

Corollary 2.10. Suppose that $(M_k)_{k\in \mathbb {N}}$ is a sequence of manifolds with negatively pinched curvature which converges strongly to a (possibly disconnected) geometrically finite manifold N with negatively pinched curvature. Then the manifolds $M_k$ are also geometrically finite for sufficiently large k.

Proof. Suppose that $N=\cup _{i}^{m} N_i$ . The truncated core $C(N)^{>\epsilon }$ is compact for any $0<\epsilon <\epsilon (n, \kappa )$ , since N is geometrically finite. By Item (2) in the definition of strong convergence, $C(M_{k})^{>\epsilon }$ is also compact for large k, since $C(M_{k, i})^{>\epsilon }$ is compact for large k, and all $1\leq i\leq m$ .

In Section 3, we work on sequences of manifolds of negatively pinched curvature that converge strongly to (possibly disconnected) limit manifolds. Given an n-dimensional manifold M with negatively pinched curvature (possibly disconnected) and a constant $\mu <(n-1)^{2}/4$ , $Spec_{\mu }(M)$ is defined as the collection of eigenvalues of the negative Laplacian on M less than $\mu $ . If M is disconnected, $ Spec_\mu (M)$ agrees with the union of $Spec_\mu $ of each component of M (counting multiplicity). Specifically, a function $f:M\rightarrow \mathbb {R}$ satisfies the equation $-\Delta f = \lambda f$ if and only if its restriction to each component of M is either an eigenfunction with eigenvalue $\lambda $ , or $0$ . Moreover, while taking orthonormal eigenfunctions for M, we can consider that each eigenfunction has support in a unique component of M.

In Sections 4 and 5, we focus on sequences of hyperbolic manifolds strongly converging to connected limit manifolds. Suppose now $M=\mathbb {H}^{n}/ \Gamma $ is an n-dimensional hyperbolic manifold. As we stated in the Introduction, locally convex sets in M are in 1-to-1 correspondence with $\Gamma $ -precisely invariant convex sets in $\mathbb {H}^{n}$ by the projection map $\text {Proj}: \mathbb {H}^{n}\rightarrow M$ . In particular, we sometimes identify local convex sets with one of their lifts which are $\Gamma $ -precisely invariant, and we do not consider immersed locally convex sets, for example, nonprimitive closed geodesics. For simplicity, we will omit the word locally and plainly denote the sets as convex.

We say that a convex set D in M is well-positioned if $\partial \tilde {D}$ is smooth, where $\tilde {D}$ denotes the lift of D to $\mathbb {H}^3$ , and $\sigma ^{\pm }_{\partial D}$ has compact support.

Example 2.11. Suppose that M is a geometrically finite hyperbolic manifold. Embedded geodesic balls and the thin part of M are well-positioned convex sets.

Proof. Geodesic balls with radii smaller than the injectivity radius of the center and Margulis tubes are compact convex subsets, so they are well-positioned. The lifts of a cusp neighborhood D in M are horoballs whose boundaries are smooth. Since M is geometrically finite, all parabolic fixed points are bounded. Hence, the intersection of $\partial D$ with the convex core is compact. Thus, $\sigma ^{\pm }_{\partial D}$ has compact support and D is well-positioned.

Suppose that $(M_{k}=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds that converges strongly to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ . We say that well-positioned convex sets $D_k\subset M_k$ strongly converge to a well-positioned convex set $D\subset M$ if

  1. 1. the boundary $\partial D_k$ converges strongly to $\partial D$ , or equivalently, the lifts of $\varphi _k^{-1}(\partial D_k)$ converge smoothly in compact sets to lifts of $\partial D$ , where $\varphi _k:U_k\rightarrow M_k$ are the smooth maps in the definition of strong convergence of $(M_k)_{k\in \mathbb N}$ ,

  2. 2. $\bar {\pi }(supp(\sigma ^{\pm }_{\partial D_{k}}))$ is contained in $\varphi _k\left (N_1(\bar {\pi }(supp(\sigma ^{\pm }_{\partial D})))\right )$ for large k, where $\bar {\pi }: T^{1}M\rightarrow M$ and $N_1$ denotes the 1-neighborhood.

Example 2.12. Let $(M_{k}=\mathbb {H}^{n}/ \Gamma _k)_{k\in \mathbb {N}}$ be a sequence of hyperbolic manifolds that converges strongly to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ .

  1. 1. Suppose that $(x_{k})_{k\in \mathbb {N}}$ is a sequence of points in $M_{k}$ that converges to $x\in M$ . The geodesic balls around the $x_{k}$ with radius r converge strongly to the geodesic ball of x with the same radius, where r is smaller than the injectivity radius of x.

  2. 2. Given $0<\epsilon <\epsilon (n, \kappa )$ , the thin parts $M_{k}^{<\epsilon }$ converge strongly to the thin part $M^{<\epsilon }$ .

3 Convergence of small eigenvalues

In this section, we study the convergence of small eigenvalues and prove the uniform spectral gap for strongly convergent sequences of geometrically finite n-manifolds of negatively pinched curvature $-\kappa ^2\leq K \leq -1$ .

Proposition 3.1. Let M be a geometrically finite Riemannian n-manifold of pinched sectional curvature $-\kappa ^2\leq K\leq -1$ , and let $\epsilon =\epsilon (n, \kappa )>0$ be the Margulis constant. Given $\mu <(n-1)^2/4$ , there exists a sufficiently large constant $r(\mu )=r>0$ and some constant $\eta (\mu ,r)=\eta>0$ , so that if $f\in H^1(M)$ with $R(f)\leq \mu $ , then $ \int _{B_{2r}(C(M)^{>\epsilon })} |f|^2\geq \eta \int _M |f|^2$ . Moreover, one can take $\eta \rightarrow \bigg (1-\frac {4\mu }{(n-1)^2}\bigg )$ as $r\rightarrow + \infty $ .

Proof. Since $C^\infty _0(M)$ is dense in $H^1(M)$ , we can assume without loss of generality that f is compactly supported with $\int _M f^2 = 1$ .

Observe that we can find $C^1$ functions $g,h:\mathbb {R}\rightarrow [0,1]$ so that

  • $g^2(x) + h^2(x)=1$ for any $x\in \mathbb {R}$ ,

  • $supp(g)\subseteq (-\infty ,1],\, supp(h)\subseteq (0,+\infty ]$ .

Given a positive constant $r>0$ , we define $u:=u_r(x),\alpha :=\alpha _r(x)\in C^1_0(M)$ satisfying the following properties, by using scalings of $g,h$ along equidistant sets to $\partial C(M)$ :

  1. 1. $0\leq u,\alpha \leq 1$

  2. 2. $supp(u) \subseteq B_{2r}(C(M))$

  3. 3. $supp(\alpha ) \subseteq int(B^c_r(C(M)))$

  4. 4. $u^2+\alpha ^2\equiv 1$

  5. 5. $|\nabla u|,|\nabla \alpha |\leq \frac {C}{r}$ everywhere in M, for some constant C independent of r and M.

Similarly, for the thick-thin decomposition of M, we define functions $v:=v_r(x),\beta :=\beta _r(x)\in C^1_0(M)$ along equidistant sets to $\partial M^{>\epsilon }$ satisfying the following properties

  1. 1. $0\leq v,\beta \leq 1$

  2. 2. $supp(v) \subseteq B_{2r}(M^{>\epsilon })$

  3. 3. $supp(\beta ) \subseteq int(B^c_r(M^{>\epsilon }))$

  4. 4. $v^2+\beta ^2\equiv 1$

  5. 5. $|\nabla v|,|\nabla \beta |\leq \frac {C}{r}$ everywhere in M, for some constant C independent of r and M.

Define then $f_1:=uvf,\,f_2:=u\beta f,\,f_3:=\alpha f$ which are in $C^1_0(M)$ . By the definitions of $u,\alpha ,v,\beta $ , we have

  1. 1. $supp(f_1)\subseteq B_{2r}(M^{>\epsilon }\cap C(M))$

  2. 2. $supp(f_2)\subseteq B^c_{r}(M^{>\epsilon })$

  3. 3. $supp(f_3)\subseteq B^c_{r}(C(M))$

  4. 4. $f^2_1+f^2_2+f^2_3=f^2$ .

We can expand $R(f_1)$ as

$$\begin{align*}R(f_1) = \bigg(\int_M f^2|\nabla (uv)|^2+2uvf\langle\nabla (uv), \nabla f \rangle + u^2v^2|\nabla f|^2\bigg)\bigg/\bigg(\int_M u^2v^2f^2\bigg). \end{align*}$$

Since $\nabla (uv) = u\nabla v + v\nabla u$ , then it follows that $|\nabla (uv)|\leq \frac {2C}{r}$ , and subsequently

$$\begin{align*}\int_M f^2|\nabla (uv)|^2 \leq \frac{4C^2}{r^2}. \end{align*}$$

By Cauchy-Schwarz, we also have that

$$\begin{align*}\bigg|\int_M 2uvf\langle\nabla (uv), \nabla f \rangle\bigg| \leq 2\int_M |\langle f\nabla(uv),\nabla f \rangle| \leq \frac{4C}{r}\sqrt{R(f)}. \end{align*}$$

Collecting these inequalities and defining $a:=\int _M f^2_1$ for convenience, we arrive to

(2) $$ \begin{align} R(f_1) \leq \bigg( \frac{4C^2}{r^2} + \frac{4C}{r}\sqrt{R(f)} + \int_M u^2v^2|\nabla f|^2\bigg)\bigg/a. \end{align} $$

Similarly, define $b:=\int _M f^2_2,\,c:=\int _M f^2_3$ . Then

(3) $$ \begin{align} R(f_2) \leq \bigg( \frac{4C^2}{r^2} + \frac{4C}{r}\sqrt{R(f)} + \int_M u^2\beta^2|\nabla f|^2\bigg)\bigg/b, \end{align} $$
(4) $$ \begin{align} R(f_3) \leq \bigg( \frac{4C^2}{r^2} + \frac{4C}{r}\sqrt{R(f)} + \int_M \alpha^2|\nabla f|^2\bigg)\bigg/c. \end{align} $$

By doing $a(2)+b(3)+c(4)$ , we obtain

(5) $$ \begin{align} aR(f_1)+bR(f_2)+cR(f_3) &\leq \bigg( \frac{12C^2}{r^2} + \frac{12C}{r}\sqrt{R(f)} + \int_M (u^2v^2 + u^2\beta^2 + \alpha^2)|\nabla f|^2\bigg)\nonumber\\ &= \bigg( \frac{12C^2}{r^2} + \frac{12C}{r}\sqrt{R(f)} + \int_M |\nabla f|^2\bigg)\nonumber\\ &\leq\bigg( \frac{12C^2}{r^2} + \frac{12C}{r}\sqrt{\mu} + \mu \bigg). \end{align} $$

Since $supp(f_2)\subseteq int(B^c_{r}(M^{>\epsilon })),\,supp(f_3)\subseteq int(B^c_{r}(C(M)))$ , we have by Lemmas 2.2 and 2.3 (or more precisely, by applying a combination of the lemmas on each component of M) that $R(f_2)\geq (\tanh r)^2(n-1)^2/4,\,R(f_3)\geq (\tanh r)^2(n-1)^2/4$ . Using these bounds together with the obvious bound $aR(f_1)\geq 0$ , we arrive to

$$\begin{align*}(b+c)\frac{(\tanh r)^2(n-1)^2}{4} \leq \frac{12C^2}{r^2} + \frac{12C}{r}\sqrt{\mu} + \mu, \end{align*}$$
$$\begin{align*}(b+c) \leq \frac{4}{(\tanh r)^2(n-1)^2}\bigg( \frac{12C^2}{r^2} + \frac{12C}{r}\sqrt{\mu} + \mu\bigg). \end{align*}$$

By the fact that $a+b+c=1$ , we obtain

$$\begin{align*}a \geq \frac{4}{(\tanh r)^2(n-1)^2}\bigg(\frac{(\tanh r)^2(n-1)^2}{4} - \frac{12C^2}{r^2} - \frac{12C}{r}\sqrt{\mu} - \mu\bigg). \end{align*}$$

The result follows from observing that for the left-hand side, we have $\int _{B_{2r}(M^{>\epsilon }\cap C(M))} f^2 \geq a$ , whereas the right-hand side depends only on $\mu ,r$ and converges to $1-\frac {4\mu }{(n-1)^2}>0$ as $r\rightarrow +\infty $ .

Now we use Proposition 3.1 to take limits of eigenfunctions with small eigenvalues along a strongly convergent sequence of manifolds with negatively pinched curvature.

Lemma 3.2. Suppose that $(M_k)_{k\in \mathbb {N}}$ is a sequence of n-manifolds of pinched curvature $-\kappa ^{2}\leq K\leq -1$ that converges strongly to a (possibly disconnected) geometrically finite n-manifold M. Let $\mu <(n-1)^2/4$ , and for each $M_k$ , let $f_k$ be an eigenfunction of the negative Laplacian so that $R(f_k)\leq \mu $ and $\int _{M_k}|f_k|^2 = 1$ . Then, after possibly taking a subsequence, we have that $f_k$ converges strongly to f, a nonzero eigenfunction of the negative Laplacian in M with $R(f)\leq \mu $ .

Proof. By Proposition 3.1, there exist $r>0$ and $\eta>0$ independent of k so that $\int _{B_{2r}(C(M_k)^{>\epsilon })} |f_k|^2\geq \eta $ . By elliptic regularity and strong convergence, we have that the Sobolev norms

$$\begin{align*}\Vert f_k \Vert_{W^{2,\ell}(B_{2r}(C(M_k)^{>\epsilon}))} \end{align*}$$

are uniformly bounded for any given $\ell $ . By the Rellich-Kondrachov compactness theorem, we can take a convergent subsequence with limit f in $B_{2r}(C(M)^{>\epsilon })$ in any $W^{2,\ell }$ norm. Taking $r\rightarrow +\infty $ and doing a Cantor diagonal argument, we have that $R(f) \leq \mu ,\, -\Delta _M f = R(f)f,\, \int _{M} |f|^2\geq \eta $ , which concludes the Lemma.

Recall that $Spec_{\mu }(M)$ denotes the collection of eigenvalues of the negative Laplacian on the negatively pinched manifold M which are smaller than $\mu $ , where for convenience, we assume that $\mu <(n-1)^2/4$ is not an eigenvalue of M (this is possible for all $\mu <(n-1)^2$ /4 with the exception of finitely many values). Suppose that $(M_{k})_{k\in \mathbb {N}}$ is a sequence of negatively pinched manifolds which converges strongly to a geometrically finite n-manifold M. Given any small eigenvalue $\lambda \in Spec_\mu (M)$ , we can use the discreteness of small eigenvalues to take $\epsilon>0$ small enough so that $(\lambda -\epsilon ,\lambda +\epsilon )\cap\, Spec_\mu (M) = \lbrace \lambda \rbrace $ . We have then that $(\lambda -\epsilon ,\lambda +\epsilon )\cap Spec_\mu (M_k)$ is either empty or accumulates to $\lambda $ as $k\rightarrow \infty $ , where we desire to prove the latter case. Let then $m_\lambda $ be the multiplicity of $\lambda $ and $m_{\lambda ,k}$ be the cardinality of $(\lambda -\epsilon ,\lambda +\epsilon )\cap Spec_\mu (M_k)$ (counting multiplicities). We say $Spec_{\mu }(M_k)$ converges to $Spec_{\mu }(M)$ , if $\lim _{k\rightarrow \infty } m_{\lambda ,k} = m_\lambda $ for any small eigenvalue $\lambda \in Spec_{\mu }(M)$ .

Theorem 3.3. Suppose that $(M_k)_{k\in \mathbb {N}}$ is a sequence of n-manifolds of pinched curvature $-\kappa ^{2}\leq K\leq -1$ that converges strongly to a (possibly disconnected) geometrically finite n-manifold M. Then for any given $\mu <(n-1)^2/4$ not in $Spec(M)$ , we have that $Spec_\mu (M_k)$ converges (counting multiplicities) to $Spec_\mu (M)$ .

Proof. To prove the theorem, we will show the convergence of eigenspaces. Namely, let $V_k, V$ denote the linear spaces of functions generated by the eigenfunctions with eigenvalues in $Spec_\mu (M_k)$ and $ Spec_\mu (M)$ , which have a natural orthogonal decomposition by the eigenspaces of $Spec_\mu (M_k)$ and $Spec_\mu (M)$ . We show that $V_k\rightarrow V$ , in the following sense:

  1. 1. Any function $f\in V$ can be obtained as the limit of a strongly convergent sequence $(f_k\in V_k)_{k\in \mathbb {N}}$ .

  2. 2. Any sequence of families $( f_{l,k} \subset V_k)_{k\in \mathbb {N}}$ of orthonormal functions in $M_k$ converges strongly (after possibly taking a subsequence) to a linearly independent family of functions in M.

Item (1) implies that $\liminf _{k\rightarrow \infty } m_{\lambda , k}\geq m_\lambda $ , and Item (2) implies that $\limsup _{k\rightarrow \infty } m_{\lambda , k}\leq m_\lambda $ . Thus, it suffices to prove the convergence of eigenspaces. We first show Item (2). Suppose that $f_{1,k},\ldots f_{l,k}$ are orthonormal eigenfunctions of $M_k$ . By Lemma 3.2, we can assume they converge in compact sets to $f_1,\ldots ,f_l$ . If the functions $f_1,\ldots , f_l$ are not linearly independent in $L^2(M)$ , there exist real numbers $\alpha _1,\ldots ,\alpha _l$ not all vanishing so that $\alpha _1f_1+\ldots +\alpha _lf_l\equiv 0$ . Hence, $g_k = \alpha _1f_{1,k}+\ldots +\alpha _lf_{l, k}$ are functions in $H^1(M_k)$ with norm $\sqrt {\alpha _1^2+\ldots + \alpha _k^2}\neq 0$ . We can normalize $\Vert g_k\Vert _{L^2(M)}=1$ so that $R(g_k)\leq \mu $ , and since the limit of $g_k$ in compact sets is not identically zero from Proposition 3.1, we have a contradiction.

Now we prove Item (1). Assume that not all functions in V are obtained as limits of functions in $V_k$ . Let $V'$ be the proper maximal space in V, consisting of functions that can be obtained as limits. Assume that there exists an eigenfunction f of M with eigenvalue $\lambda $ , such that f is orthogonal to $V'$ . Approximate f in $H^1(M)$ by a compactly supported function $f_0$ , which is normalized so that $\int _M|f_0|^2=1$ and $R(f_0)$ is close to $\lambda $ . It follows that $\int _M f_0g =\int _M (f_0-f)g$ can be taken uniformly small for all $g\in V'$ with $\int _M |g|^2=1$ . Let $f^{k}_{0}$ be the pullback of $f_{0}$ in $M_k$ by the maps $\varphi _{k,i}$ from the definition of strong convergence. Then for sufficiently large k, we have that (after identifying the compact cores) $\int _{M_k} f_{0}^{k}g_k$ can be also taken uniformly small for any $g_k\in V_k$ with $\int _{M_k}|g_k|^2=1$ by Proposition 3.1. For large k, we also have that in $M_k$ the Rayleigh quotient $R(f^{k}_{0})$ is close to $\lambda $ . Denote then by $f_{0,k}$ the projection of $f_{0}^{k}$ perpendicular to $V_k$ . Then $R(f_{0, k})$ is also very close to $\lambda $ for sufficiently large k. Hence, this contributes to an eigenfunction in $M_k$ which does not belong to $V_k$ . However, by construction, $V_k$ is the linear space of functions generated by eigenfunctions with eigenvalues in $Spec_{\mu }(M_k)$ , which gives a contradiction. Therefore, any function $f\in V$ can be obtained as the limit of a strongly convergent sequence $(f_k\in V_k)$ .

Recall that the Lax-Phillips spectral gap $s_{1}=\min \{\lambda _1(M), (n-1)^{2}/4\}-\lambda _{0}(M)$ for a hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ . We obtain the following convergence result of spectral gap for strongly convergent sequences of hyperbolic manifolds.

Theorem 3.4. Suppose that $(M_k=\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})/ \Gamma _k)_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which converges strongly to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ . Then the sequence of Lax-Phillips spectral gaps $s_1(M_k)$ converges to $s_1(M)$ .

Proof. By [Reference McMullenMcM99, Theorem 1.5] and Theorem 2.4, we have that $\lim _{k\rightarrow \infty } \lambda _0(M_k) = \lambda _0(M)$ . By Theorem 3.3, if $\lambda _{1}(M)\geq (n-1)^{2}/4$ , then $\liminf \lambda _{1}(M_k)\geq (n-1)^{2}/4$ for sufficiently large k, or if $\lambda _{1}(M)<(n-1)^{2}/4$ , we have that $\lim _{k\rightarrow \infty } \lambda _1(M_k) = \lambda _1(M)>\lambda _0(M)$ for sufficiently large k. In either case, the convergence of $s_1(M_k)$ to $s_1(M)$ follows.

Proof of Theorem 1.1 . The proof follows from Theorems 3.3 and 3.4.

4 Uniform convergence of measures

In this section, we prove convergence for skinning measures and the Bowen-Margulis measure under strong convergence. We assume that M is a hyperbolic n-manifold, and by $M^{<\epsilon }$ , we denote the $\epsilon $ -thin part of M for a constant $\epsilon $ smaller than the n-dimensional Margulis constant. We first prove that the Bowen-Margulis measure of the thin part is (uniformly) relatively small.

Proposition 4.1. Suppose $(M_k=\mathbb {H}^{n}/ \Gamma _k)_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds that strongly converges to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ with $\delta (\Gamma )>(n-1)/2$ . Let $m^k_{\mathrm {BM}}, m_{\mathrm {BM}}$ be the Bowen-Margulis measures on $T^{1}M_{k}$ and $T^{1}M$ , respectively. Then, for any $\alpha>0$ , there exist $\epsilon>0$ and $N>0$ so that for $\epsilon '<\epsilon $ and $k>N$ , we have that

$$\begin{align*}\int_{T^{1}M^{<\epsilon'}_{k}} dm^{k}_{\mathrm{BM}} <\alpha. \end{align*}$$

Proof. This follows Dalbo-Otal-Peigne’s proof [Reference Dal’bo, Otal and PeignéDOP00] on the finiteness of $m_{\mathrm {BM}}$ . We first let $\epsilon>0$ be a constant which is smaller than the shortest geodesic in M. Take a fundamental domain F for the convex core of M in the universal cover $\mathbb {H}^{n}$ , and divide F as the thin part $F^{<\epsilon }$ (i.e., the intersection of F with the thin part of M) and the thick part $F^{>\epsilon }$ . Consider a component D of $F^{<\epsilon }$ , which must be a cuspidal component. Suppose that $\mathcal {H}$ is the corresponding horoball based at the parabolic fixed point $\xi $ , so that D is a fundamental domain for the parabolic subgroup $\mathcal {P}<\pi _1(M)$ that preserves $\mathcal {H}$ .

As detailed in [Reference Dal’bo, Otal and PeignéDOP00, page 118], we can bound $\tilde {m}_{\mathrm {BM}}$ in D by

$$\begin{align*}\tilde{m}_{\mathrm{BM}}(T^1D) \leq \sum_{p\in\mathcal{P}}\int_{\mathcal{D}\times p\mathcal{D}} c^\mu(d\eta^-d\eta^+) \int_{(\eta^-\eta^+)\cap\mathcal{H}}dt, \end{align*}$$

where $c^\mu (d\eta ^-d\eta ^+)=e^{-2\delta (\Gamma )(\eta ^-|\eta ^+)_{x}}d\mu _{x}(\eta ^{-})d\mu _{x}(\eta ^{+})$ for a given point $x\in \mathbb {H}^{n}$ and $\mathcal {D}\subseteq \partial _{\infty } \mathbb {H}^{n}\setminus \lbrace \xi \rbrace $ is a compact set, such that $\lbrace p\mathcal {D} \rbrace _{p\in \mathcal {P}}$ covers $\Lambda (M) \setminus \lbrace \xi \rbrace $ . The existence of the compact set $\mathcal {D}$ is ensured by the assumption that M is geometrically finite, hence, the parabolic fixed point $\xi $ is bounded [Reference BowditchBow93]. Now, let $\mathcal {P}_k$ be the elementary group in $M_k$ that converges to $\mathcal {P}$ , which is either parabolic or loxodromic. We discuss the proof that when the groups $\mathcal {P}_{k}$ are loxodromic. The argument for parabolic subgroups is similar.

Let $\mathcal {H}_k$ be a neighborhood of the geodesic $\xi ^-_k\xi ^+_k$ preserved by $\mathcal {P}_k$ so that $\mathcal {H}_k\rightarrow \mathcal {H}$ , $\xi ^\pm _k\rightarrow \xi $ . Since $M_k$ converges to M strongly, by [Reference McMullenMcM99], we can take $\mathcal {D}$ large enough so that $\lbrace p\mathcal {D} \rbrace _{p\in \mathcal {P}_k}$ covers $\Lambda (M_k)\setminus \lbrace \xi ^-_k, \xi ^+_k\rbrace $ . Hence, it follows that

$$\begin{align*}m^k_{\mathrm{BM}}(T^1(\mathcal{H}_k/\mathcal{P}_k)) \leq \sum_{p\in\mathcal{P}_k}\int_{\mathcal{D}\times p\mathcal{D}} c^\mu_k(d\eta^-d\eta^+) \int_{(\eta^-\eta^+)\cap\mathcal{H}_k}dt. \end{align*}$$

Assume without loss of generality that we can take a common point $x\in \mathcal {H}_k,\mathcal {H}$ . There exist compact set $K\subset \mathbb {H}^n$ and open neighborhood $V\subseteq \mathbb {H}^n$ of $\xi $ so that for k large, if the (oriented) geodesic $\eta ^-\eta ^+$ with $\eta ^-\in \mathcal {D}\cap \Lambda (\Gamma _k)$ and $\eta ^+\in p\mathcal {D}\cap \Lambda (\Gamma _k)$ intersects $\mathcal {H}_k$ , then the point of entry belongs to $K\cap \partial \mathcal {H}_k$ and $p^{-1}x$ belongs to V. In particular, such geodesic $\eta ^-\eta ^+$ verifies $0\leq (\eta ^-|\eta ^+)_x\leq diam(K)$ . Moreover, we have that $|\int _{(\eta ^-\eta ^+)\cap \mathcal {H}_{k}}dt - d(x,px)|<2diam(K)$ . Hence, there exists a constant $C>0$ depending only on $diam(K)$ so that

$$\begin{align*}m^k_{\mathrm{BM}}(T^1(\mathcal{H}_k/\mathcal{P}_k)) \leq C\,\left(\sum_{p\in\mathcal{P}^{\prime}_k} \mu^k_x(\mathcal{D})\mu^k_x(p\mathcal{D})(d(x,px)+C)\right), \end{align*}$$

where $\mu ^{k}_{x}$ denotes the Patterson-Sullivan measure on $M_k$ and $\mathcal {P}^{\prime }_k$ is the subset of $\lbrace p\in \mathcal {P}_k\,|\, p^{-1}x \in V \rbrace $ so that the summand $\int _{\mathcal {D}\times p\mathcal {D}} c^\mu _k(d\eta ^-d\eta ^+) \int _{(\eta ^-\eta ^+)\cap \mathcal {H}_k}dt$ is non-zero.

Recall that

$$\begin{align*}\mu^k_x(p\mathcal{D}) = \int_{\mathcal{D}} e^{-\delta(\Gamma_k)B_\eta(p^{-1}x,x)}\mu^k_x(d\eta), \end{align*}$$

so we would like to estimate $B_\eta (p^{-1}x,x)$ . Observe that as $\mathcal {H}_k$ is preserved by $\mathcal {P}_k$ , we have that if $\eta ^-\eta ^+$ is a geodesic with $\eta ^-\in \mathcal {D}\cap \Lambda (\Gamma _k)$ and $\eta ^+\in p\mathcal {D}\cap \Lambda (\Gamma _k)$ that intersects $\mathcal {H}_k$ , then the exit point of $\eta ^-\eta ^+$ from $\mathcal {H}_k$ belongs to $pK\cap \partial \mathcal {H}_k$ . By triangular inequality, we have that under such conditions $|\int _{(\eta ^-\eta ^+)\cap \mathcal {H}_{k}}dt - B_\eta (x,px)|<2diam(K)$ . Hence, for $p\in \mathcal {P}^{\prime }_k$ have $|B_\eta (p^{-1}x,x) - d(p^{-1}x,x)|\leq 4diam(K)$ . Combining this with our previous inequality (and making the domain of the sum bigger if necessary), we get

$$\begin{align*}m^k_{\mathrm{BM}}(T^1(\mathcal{H}_k/\mathcal{P}_k)) \leq C\, \left(\sum_{p\in\mathcal{P}_k, p^{-1}x\in V} (\mu^k_x(\mathcal{D}))^2e^{-\delta(\Gamma_k)d(p^{-1}x,x)}(d(x,px)+C)\right) \end{align*}$$

for some $C>0$ independent of $\epsilon $ and k.

We claim that the above discussion holds for smaller $\epsilon $ corresponding to a smaller neighborhood $V(\epsilon )$ for the same base point x. Consider a smaller thin part corresponding to $\epsilon '<\epsilon $ . The sets $\mathcal {H}_k, K$ vary with $\epsilon '$ , although it is clear that $\mathcal {H}_k(\epsilon ')\subset \mathcal {H}_k(\epsilon )$ and $diam(K(\epsilon ')) < diam(K(\epsilon ))$ . Hence, after taking a base point $y\in K(\epsilon ')$ , we have

$$\begin{align*}m^k_{\mathrm{BM}}(T^1(\mathcal{H}_k(\epsilon')/\mathcal{P}_k)) \leq C\,\left(\sum_{p\in\mathcal{P}_k, p^{-1}y\in V(\epsilon')} (\mu^k_y(\mathcal{D}))^2e^{-\delta(\Gamma_k)d(p^{-1}y,y)}(d(y,py)+C)\right) \end{align*}$$

for a constant $C>0$ independent of $\epsilon '$ and k.

The neighborhood $V(\epsilon ')$ is smaller and smaller as $\epsilon '\rightarrow 0$ , as if $\eta ^-\eta ^+$ intersects $\mathcal {H}_k(\epsilon ')$ , then it has to intersect $\mathcal {H}_k(\epsilon )$ . Then for the p summands considered for $\epsilon '$ , we have

$$\begin{align*}d(y,py)\leq d(x,px)+C',\quad \mu^k_y(\mathcal{D}) \leq C'e^{-\delta(\Gamma_k)d(x,y)}\mu^k_x(\mathcal{D}) \end{align*}$$

for $C'$ constant independent of $\epsilon '$ and k. We always have the bound $d(y,py)\geq d(x,px) - 2d(x,y)$ by triangular inequality and the fact that p is an isometry.

Putting altogether, we have that

(6) $$ \begin{align} m^k_{\mathrm{BM}}(T^1(\mathcal{H}_k(\epsilon')/\mathcal{P}_k)) \leq C"(\mu^k_x(\mathcal{D}))^2\,\left(\sum_{p\in\mathcal{P}_k, p^{-1}x\in V(\epsilon')} e^{-\delta(\Gamma_k)d(p^{-1}x,x)}(d(x,px)+C")\right) \end{align} $$

for a constant $C">0$ independent of $\epsilon '$ and k. Recall that when $\delta (\Gamma _k)$ is strictly bigger than $(n-1)/2$ , by [Reference McMullenMcM99, Theorem 6.1], the tails of the series $\sum _{p\in \mathcal {P}_k}e^{-\delta (\Gamma _k)d(p^{-1}x,x)}$ are uniformly small. Specifically, for any $\eta>0$ , there exists a neighborhood $U\subset \mathbb {H}^{n}$ of $\xi $ so that

$$\begin{align*}\sum_{p\in\mathcal{P}_k, \,px\subset U}e^{-\delta(\Gamma_k)d(p^{-1}x,x)} < \eta, \end{align*}$$

for k sufficiently large. We also have that the tails of the series $\sum _{p\in \mathcal {P}_k}e^{-\delta (\Gamma _k)d(p^{-1}x,x)}(d(x,px)+C")$ are uniformly small, as $d(x,px)$ is uniformly dominated by $e^{cd(p^{-1}x,x)}$ for any $c>0$ . Hence, by taking $\epsilon '$ sufficiently small, the right-hand side of (6) corresponds to a smaller tail of the series $\sum _{p\in \mathcal {P}_k}e^{-\delta (\Gamma _k)d(p^{-1}x,x)}(d(x,px)+C")$ . Thus, by applying [Reference McMullenMcM99, Theorem 6.2] for the sequence of exponents $\delta (\Gamma _k)-c$ , the right-hand side of (6) will be arbitrarily small for $\epsilon '$ sufficiently small and k sufficiently large.

Next, we use Proposition 4.1 to prove the convergence of the Bowen-Margulis measures. The following proposition is a restatement of Proposition 1.6.

Proposition 4.2. Suppose that $(M_k=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which is strongly convergent to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ with $\delta (\Gamma )>(n-1)/2$ . Let $m^k_{\mathrm {BM}}, m_{\mathrm {BM}}$ be the Bowen-Margulis measures on $T^{1}M_k$ and $T^{1}M$ , respectively. For $r>0$ , we denote by $M_{k}^{<r}\subset M_k, M^{<r}\subset M$ the set of points with injectivity radius less than r. Then, for any $r>0$ , we have

$$\begin{align*}\lim_{k\rightarrow\infty}\int_{T^1M_k^{<r}}dm^k_{\mathrm{BM}} \rightarrow \int_{T^1M^{<r}} dm_{\mathrm{BM}}. \end{align*}$$

Moreover, by taking r sufficiently large, we have that

$$\begin{align*}\Vert m^k_{\mathrm{BM}}\Vert \rightarrow \Vert m_{\mathrm{BM}}\Vert.\end{align*}$$

Proof. Denote $M^{a,b}=M^{>a}\cap M^{<b}$ . Take $U_1,\ldots U_m\subset M$ balls with compact closure, whose union covers $C(M)^{\epsilon ,r} = C(M) \cap M^{\epsilon ,r}$ . Take $\bar {\varphi }_1,\ldots ,\bar {\varphi }_m$ partition of unity subordinated to $U_1,\ldots U_m$ , in the sense that $\bar {\varphi }=\sum _{i=1}^m \bar {\varphi }_i$ has support contained in $M^{\epsilon -\eta ,r+\eta }$ and is identically equal to $1$ in $C(M)^{\epsilon ,r}$ , for some arbitrarily small $\eta>0$ . Let $\tilde {U_i}$ be a lift of $U_i$ in $\mathbb {H}^n$ , such that the union covers a fundamental domain of M. We denote $\varphi _i$ a compactly supported function subordinated to $\tilde {U}_i$ , such that $\varphi _i=\bar {\varphi }_{i}\circ \text {Proj}$ .

Then since the Patterson-Sullivan measures $\mu ^k_{x_0}$ converge weakly to $\mu _{x_0}$ , the critical exponents $\delta _k=\delta (\Gamma _k)$ converge to $\delta =\delta (\Gamma )$ , and we can express the Bowen-Margulis measures as $d\tilde {m}^k_{\mathrm {{BM}}}(v)=e^{-\delta _k(\beta _{v_{-}}(\pi (v), x_{0})+\beta _{v^{+}}(\pi (v), x_{0}))}d\mu ^k_{x_{0}}(v_{-})d\mu ^k_{x_{0}}(v_{+})dt$ , then, for k sufficiently large, we have

(7) $$ \begin{align} \bigg|\int_{T^1\tilde{U_i}}\varphi_id\tilde{m}^k_{\mathrm{BM}} - \int_{T^1\tilde{U_i}}\varphi_i d\tilde{m}_{\mathrm{BM}}\bigg| <\alpha, \end{align} $$

for some small $\alpha>0$ .

By Proposition 4.1, we have that $\int _{T^1 M^{<\epsilon }_k} dm^k_{\mathrm {BM}}, \int _{T^1 M^{<\epsilon }} dm_{\mathrm {BM}}<\alpha $ , and by construction, we have that

(8) $$ \begin{align} \bigg|\int_{T^1M^{<r}}dm_{\mathrm{BM}} - \sum_{i=1}^m\int_{T^1\tilde{U_i}}\varphi_id\tilde{m}_{\mathrm{BM}}\bigg| < \int_{T^1M^{<\epsilon}} dm_{\mathrm{BM}} + \int_{T^1M^{r,r+\eta}} dm_{\mathrm{BM}}. \end{align} $$

Now, since $M_k$ converges strongly to M, for k large, we have that $\sum _{i=1}^m\int _{T^1\tilde {U_i}}\varphi _id\tilde {m}^{k}_{\mathrm {BM}}$ is bounded between $(1-\alpha )\int _{T^1M_k^{\epsilon +\eta , r-\eta }}dm^k_{\mathrm { BM}}$ and $(1+\alpha )\int _{T^1M_k^{\epsilon -\eta , r+\eta }}dm^k_{\mathrm {BM}}$ . Hence

(9) $$ \begin{align} \bigg|\int_{T^1M_k^{<r}}dm^k_{\mathrm{BM}} - \sum_{i=1}^m\int_{T^1\tilde{U_i}}\varphi_id\tilde{m}^k_{\mathrm{BM}}\bigg| < \int_{T^1M_k^{<\epsilon}} dm^k_{\mathrm{BM}} + \alpha\int_{T^1M_k^{\epsilon,r}} dm^k_{\mathrm{BM}} + \int_{T^1M_k^{r,r+\eta}} dm^k_{\mathrm{BM}}. \end{align} $$

By a similar partition of unity argument, we can show that for any $0<a<b$ , there exists $\eta _0>0$ sufficiently small so that for any $k\gg 1$ sufficiently large, we have that

(10) $$ \begin{align} \int_{T^1M_k^{a,b}}dm^k_{\mathrm{BM}} < 2 \int_{T^1M^{a-\eta_0,b+\eta_0}}dm_{\mathrm{BM}}. \end{align} $$

Finally, we have to see that the function $(a,b)\mapsto \int _{T^1M^{a,b}}dm^k_{\mathrm {BM}}$ is continuous. Because of monotonicity, this reduces to prove that for any $r>0$ , $\int _{T^1\partial M^{<r}}dm^k_{\mathrm {BM}}=0$ . Indeed, the lift $\partial \tilde {M}^{<r}\subseteq \mathbb {H}^n$ is contained in the union of tubes around closed geodesics of length $\leq r$ (considering parabolic cusps corresponding to $0$ length geodesics). For core geodesics of length strictly less than r, these tubes are strictly convex, and hence, the boundaries intersect any geodesic in a discrete set. If we happen to have a geodesic of length r, then the intersection of $\partial \tilde {M}^{<r}$ with any geodesic is a discrete set, unless the geodesic is equal to the geodesic axis. In either case, the set $\partial \tilde {M}^{<r}\subseteq \mathbb {H}^n$ has zero measure for the Bowen-Margulis measure $d\tilde {m}_{\mathrm {{BM}}}(v)= e^{-2\delta (v_-|v_+)_{x_0}}d\mu _{x_{0}}(v_{-})d\mu _{x_{0}}(v_{+})dt$ , as for almost every geodesic line $\ell $ , the intersection $\partial \tilde {M}^{<r}\cap \ell $ has length $0$ .

Applying the triangular inequality, replacing equations (7), (8), (9), and then using Proposition 4.1, (10) (for sufficiently large k and $\eta $ sufficiently small), we have that

(11) $$ \begin{align} \begin{aligned} \bigg| \int_{T^1M_k^{<r}}dm^k_{\mathrm{BM}} - \int_{T^1M^{<r}} dm_{\mathrm{BM}} \bigg| &< \bigg|\int_{T^1 M_k^{<r}}dm^k_{\mathrm{BM}} - \sum_{i=1}^m\int_{T^1\tilde{U_i}}\varphi_id\tilde{m}^k_{\mathrm{BM}}\bigg| \\&+ \sum_{i=1}^m \bigg|\int_{T^1\tilde{U_i}}\varphi_{i}d\tilde{m}^k_{\mathrm{BM}} - \int_{T^1\tilde{U_i}}\varphi_i d\tilde{m}_{\mathrm{BM}}\bigg| \\&+ \bigg|\int_{T^1M^{<r}}dm_{\mathrm{BM}} - \sum_{i=1}^m\int_{T^1\tilde{U_i}}\varphi_id\tilde{m}_{\mathrm{BM}}\bigg|\\ &<\int_{T^1M_k^{<\epsilon}} dm^k_{\mathrm{BM}} + \alpha\int_{T^1M_k^{\epsilon,r}} dm^k_{\mathrm{BM}} + \int_{T^1M_k^{r,r+\eta}} dm^k_{\mathrm{BM}} \\&+ m\alpha + \int_{T^1M^{<\epsilon}} dm_{\mathrm{BM}} + \int_{T^1M^{r,r+\eta}} dm_{\mathrm{BM}}\\ &<(m+2)\alpha + 2\alpha\int_{T^1M^{<r+\eta}} dm_{\mathrm{BM}} + 3 \int_{T^1M^{r-\eta,r+2\eta}} dm_{\mathrm{BM}} \end{aligned} \end{align} $$

which goes to $0$ as $k\rightarrow +\infty $ , and $\alpha ,\eta \rightarrow 0$ .

The last part of the section is to prove the convergence of skinning measures.

Proof of Corollary 1.8.

Observe that since we have strong convergence for well-positioned convex sets $D_k\rightarrow D$ , we can take lifts $\widetilde {D_k}, \tilde {D}\subset \mathbb {H}^n$ and compact sets $E_k\subset \partial \widetilde {D_k}, E \subset \partial \tilde {D}$ so that $E_k$ , E are fundamental domains for the support of $\sigma ^{\pm }_{\partial D_k}, \sigma ^{\pm }_{\partial D}$ (respectively) and $E_k$ converges strongly to E. We can further assume there exists a set $F\subset \mathbb {S}^{n-1}$ so that $P_{D_k}(F)$ , $P_D(F)$ cover $E_k$ and E (respectively) on its interior, see (1) for the definition of the maps $P_{D_{k}}$ and $P_{D}$ . Under these assumptions, we have

$$\begin{align*}\Vert\sigma^{\pm}_{\partial D_k}\Vert \leq \tilde{\sigma}^{\pm}_{\widetilde{D_k}}(P_{D_k}(F)) \rightarrow \tilde{\sigma}^{\pm}_{\tilde{D}}(P_D(F)). \end{align*}$$

Reducing the set F so that $\tilde {\sigma }^{\pm }_{\widetilde {D_k}}(P_{D_k}(F)\setminus E_k), \tilde {\sigma }^{\pm }_{\tilde {D}}(P_D(F)\setminus E)$ are arbitrarily small, we then have

$$\begin{align*}\Vert\sigma^{\pm}_{\partial D_k}\Vert=\tilde{\sigma}^{\pm}_{\widetilde{D_k}}(E_k) \rightarrow \tilde{\sigma}^{\pm}_{\tilde{D}}(E) =\Vert\sigma^{\pm}_{\partial D}\Vert, \end{align*}$$

which proves the first statement

The relative result for subsets $\Omega _k, \Omega $ is proved by taking the fundamental domains $E^{\prime }_k\subset \partial \widetilde {D_k}$ , $E'\subset \partial \tilde {D}$ for the support of $\sigma ^{\pm }_{\partial \Omega _{k}}, \sigma ^{\pm }_{\partial \Omega }$ (respectively) and arguing as above.

5 Application: Uniform orthogeodesic counting

In this section, we use the results of uniform spectral gap and convergence of the Bowen-Margulis and skinning measures in Sections 3 and 4 to prove Theorem 1.3. Suppose that $D^{+}, D^{-}$ are well-positioned convex subsets of a hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ . A common perpendicular from $D^{-}$ to $D^{+}$ is a locally geodesic path in M which starts perpendicularly from $D^{-}$ and arrives perpendicularly to $D^{+}$ . For any $t\geq 0$ , let $\mathcal N_{D^{-}, D^{+}}(t)$ be the cardinality of the set of common perpendiculars from $D^-$ to $D^+$ with length at most t.

As before, $(M_k=\mathbb {H}^{n}/ \Gamma _k)_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which converges strongly to a geometrically finite manifold $M=\mathbb {H}^{n}/ \Gamma $ , so that we have well-positioned convex subsets $D^\pm _k\subset M_k$ that strongly converge to $D^\pm \subset M$ . Before the proof, we need to introduce the following notations.

Given $v\in T^{1}\mathbb {H}^{n}$ , the strong stable/unstable manifold is defined as

$$ \begin{align*}W^{\pm}(v)=\{v'\in T^{1}\mathbb{H}^{n}: d(v(t), v'(t))\rightarrow 0 \text{ as } t\rightarrow \pm \infty\},\end{align*} $$

which is equipped with Hamenstädt’s distance function $d_{W^{\pm }(v)}$ , see [Reference HamenstädtHam89, Reference Parkkonen and PaulinPP17]. Then given any constant $r>0$ , for all $v\in T^{1}\mathbb {H}^{n}$ , we can define the open ball of radius r centered at v in the strong stable/unstable manifold in the following

$$ \begin{align*}B^{\pm}(v, r)=\{v'\in W^{\pm}(v): d_{W^{\pm}(v)}(v, v')<r\}.\end{align*} $$

Given any $v\in T^{1}\mathbb {H}^{n}$ , and $\eta , \eta '>0$ , let

$$ \begin{align*}V^{\pm}_{v, \eta,\eta'}=\bigcup_{s\in \left[-\eta, \eta\right]} g^{s} B^{\pm}(v, \eta').\end{align*} $$

Given a proper closed convex subset D of $\mathbb {H}^{n}$ , for all subsets $\Omega ^{-}$ of $\partial ^{1}_{+}D$ and $\Omega ^{+}$ of $\partial ^{1}_{-}D$ , let

$$ \begin{align*}\mathcal{V}_{\eta, \eta'}(\Omega^{\pm})=\bigcup_{v\in \Omega^{\pm}} V^{\mp}_{v, \eta, \eta'}.\end{align*} $$

By using the projection map $\pi :T^{1}\mathbb {H}^{n}\rightarrow \mathbb {H}^{n}$ , the strong stable/unstable manifold $W^{\pm }(v)$ projects to the stable/unstable horosphere of v centered at $v_+$ and $v_-$ , denoted by $H_{\pm }(v)=\pi (W^{\pm }(v))$ . The corresponding horoball bounded by $H_{\pm }(v)$ is denoted by $HB_{\pm }(v)$ . Following the notation in [Reference Parkkonen and PaulinPP17], we let

$$ \begin{align*}\mu_{W^{+}(v)}=\tilde{\sigma}^{-}_{HB_{+}(v)} \quad \text{ and } \quad \mu_{W^{-}(v)}=\tilde{\sigma}^{+}_{HB_{-}(v)}\end{align*} $$

denote the skinning measures on the strong stable/unstable manifolds $W^{\pm }(v)$ .

Definition 5.1. Given a discrete isometry subgroup $\Gamma <\operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ , we say $(\mathbb {H}^{n}, \Gamma )$ has radius-continuous strong stable/unstable ball masses if, for every $\epsilon>0$ , and $r\geq 1$ close enough to $1$ ,

$$ \begin{align*}\mu_{W^{\pm}(v)}(B^{\pm}(v, r))\leq e^{\epsilon} \mu_{W^{\pm}(v)} (B^{\pm}(v, 1)),\end{align*} $$

for all $v\in T^{1}\mathbb {H}^{n}$ where $B^{\pm }(v, 1)$ meets the support of $\mu _{W^{\pm }(v)}$ .

The following proposition proves that the radius-continuous property of the strong stable/unstable ball masses can be taken uniformly along a strongly convergent sequence of geometrically finite hyperbolic manifolds.

Proposition 5.2. Suppose $(M_{k}=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which strongly converges to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/ \Gamma $ with $\delta (\Gamma )>(n-1)/2$ . Let $(D_{k}\subseteq M_k)_{k\in \mathbb {N}}$ be a sequence of well-positioned convex subsets in $M_{k}$ which strongly converges to a well-positioned convex subset D, with lifts to $\mathbb {H}^n$ denoted by $\widetilde {D_k}, \widetilde {D}$ , respectively. Let $\Omega _k^{\mp }\subseteq \partial ^1_\pm \widetilde {D_k}$ , $\Omega ^{\mp }\subseteq \partial ^1_\pm \widetilde {D}$ be compact sets so that $\Omega _k^{\mp }$ converges strongly to $\Omega ^{\mp }$ . Then there exists sufficiently large $R>0$ , so that for any $\epsilon $ , we have $\eta =\eta (\epsilon ,R)>0$ satisfying that

$$\begin{align*}\mu^k_{W^\pm(v)}(B^{\pm}(v,(1+r)R)) \leq e^\epsilon \mu^k_{W^\pm(v)}(B^{\pm}(v,R)) \end{align*}$$

for any $v\in \Omega _k^{\mp }$ , $0<r<\eta $ .

Proof. Let’s prove that case for $\Omega ^{+}$ , and the proof for $\Omega ^-$ is similar. As done in the proof of [Reference RoblinRob03, Proposition 6.2] (using [Reference RoblinRob00, Section 3.1]), the function $(v,R)\mapsto \mu _{W^\pm (v)}(B^\pm (v,R))$ is continuous for $v\in T^1\mathbb {H}^n, R>0$ , as well as $\Gamma $ -invariant. Moreover, since $\Omega ^+$ is compact, there exists $R>0$ sufficiently large so that the function $v\mapsto \mu _{W^-(v)}(B^-(v,R))$ is a uniformly continuous positive function in some neighborhood of $\Omega ^-$ . It suffices then to prove the statement for sufficiently large k.

Denote by $A(v,R,r) = B^-(v,(1+r)R)\setminus B^-(v,R) \subset W^-(v)$ the annulus in $W^-(v)$ with center v between radius $R, (1+r)R$ . We will show that there exists $m>0$ and function $\eta (\epsilon )>0$ so that for k large, $v\in \mathcal {V}_{\eta ,\eta } (\Omega ^{+})$ and $0<r<\eta $ the following two statements hold

  1. 1. $ \mu ^k_{W^-(v)}(B^-(v,R))\geq m$ ,

  2. 2. $ \mu ^k_{W^-(v)}(A(v,R,r)) < \epsilon $ .

Then it is clear that the statement follows from Items (1) and (2) by making $\epsilon $ arbitrarily small. Now we prove Items (1) and (2) respectively.

  1. 1. For a vector $u\in T^{1}\mathbb {H}^{n}$ , we define a function $P_{u}: W^{-}(u)\rightarrow \partial _{\infty }\mathbb {H}^{n}$ , where $P_{u}(v)$ is the endpoint of the bi-infinite geodesic $u_{-}\pi (v)$ different from $u_{-}$ , as shown in Figure 1. Since $\mathcal {V}_{\eta ,\eta } (\Omega ^+)$ has compact closure, we can take finitely many $v_i \in \mathcal {V}_{\eta ,\eta } (\Omega ^+)$ so that for any $u\in \mathcal {V}_{\eta ,\eta } (\Omega ^+)$ , there exists $v_i$ , such that

    $$\begin{align*}P_u^{-1}P_{v_i}(B^-(v_i,R/2))\subseteq B^-(u,R). \end{align*}$$
    Moreover, we can assume that the conformal factor between $\mu ^k_{W^-(v_i)}$ and $\mu ^k_{W^-(u)}$ at the sets $B^-(v_i,R/2)$ , $P_u^{-1}P_{v_i}(B^-(v_i,R/2))$ is between $\frac 12$ and $2$ . This can be done uniformly for all k by following [Reference RoblinRob03, Section 1.H]. By taking $\eta $ small, we can assume that $\mu _{W^-(v_i)}(B^-(v_i,R/2))> 2m$ for some fixed $m>0$ and for any $v_i\in \mathcal {V}_{\eta ,\eta } (\Omega ^+)$ . Then, by weak-convergence of measures, we have that for any $v_i$ (and large k) $\mu ^k_{W^-(v_i)}(B^-(v_i,R/2))> 2m$ . Then it follows that
    $$\begin{align*}\mu^k_{W^-(u)}(B^-(u,R)) \geq \mu^k_{W^-(u)}(P_u^{-1}P_{v_i}(B^-(v_i,R/2))) \geq \frac12 \mu^k_{W^-(v_i)}(B^-(v_i,R/2))> m. \end{align*}$$
  2. 2. Since $\mathcal {V}_{\eta ,\eta } (\Omega ^+)$ has compact closure and $\delta (\Gamma )>(n-1)/2$ , given $\epsilon>0$ , we can take $\eta $ small enough so that for $v\in \mathcal {V}_{\eta ,\eta } (\Omega ^+)$ , we have that $\mu _{W^-(v)}(A(v,R,5\eta ))<\epsilon $ . We will take again a finite collection of vectors $v_i$ , although now they need to satisfy the following list of properties.

    • The finite collection of $v_i$ is taken so that $B^-(v_i,4\eta )\subset A(v,R,5\eta )$ for some $v\in \mathcal {V}_{\eta ,\eta } (\Omega ^+)$ . Denote their total number by $C_2$ ,

    • For any $v\in \mathcal {V}_{\eta ,\eta } (\Omega ^+)$ and any $B^-(u,2\eta )\subset A(v,R,5\eta )$ , we have that

      $$\begin{align*}P_u^{-1}P_{v_i}(B^-(v_i,4\eta))\supseteq B^-(u,2\eta) \end{align*}$$
      with conformal factor bounded between $\frac 12$ and $2$ .

      Figure 1

    Take sufficiently large k so that $\mu ^k_{W^-(v_i)}(B^-(v_i,4\eta )) \leq \mu _{W^-(v_i)}(B^-(v_i,4\eta )) + \zeta $ for $\zeta $ small still to be determined.Let $v\in \mathcal {V}_{\eta ,\eta } (\Omega ^+)$ . Cover $A(v,R,\eta )$ by finitely many disjoint measurable sets $B_j$ , so that each $B_j$ is contained in a ball $B^-(u_j,2\eta )$ inside of $A(v,R,5\eta )$ . Then by the second bullet point, for each $u_j$ , we choose $v_i$ so that

    $$\begin{align*}P_{u_j}^{-1}P_{v_i}(B^-(v_i,4\eta))\supseteq B^-({u_j},2\eta). \end{align*}$$
    Observe that each $v_i$ can only be repeatedly selected less than $C_3$ times, for some constant $C_3$ depending only on the dimension n. Then we have the following chain of inequalities, which follow from the covering $\{B_j\}$ of $A(v,R,r)$ , the inclusion $P_{u_j}^{-1}P_{v_i}(B^-(v_i,4\eta ))\supseteq B^-({u_j},2\eta ) \supseteq B_j$ , the bound on the conformal factor of $P_u^{-1}P_{v_i}$ , the convergence $\mu ^{k}_{W^-(v)} \rightarrow \mu _{W^-(v)}$ , the inclusion $B^-(v_i,4\eta )\subset A(v,R,5\eta )$ , and the bound on the cardinality of the finite set of $v_i$ ’s
    (12) $$ \begin{align} \mu^k_{W^-(v)}(A(v,R,r)) &\leq \sum_j \mu^k_{W^-(v)}(B_j) \leq C_3\sum_i \mu^k_{W^-(v)}(P_{u_j}^{-1}P_{v_i}(B^-(v_i,4\eta)))\nonumber\\ &\leq 2 C_3\sum_i \mu^k_{W^-(v)}(B^-(v_i,4\eta)) \leq 2C_3 \sum_i \left(\mu_{W^-(v)}(B^-(v_i,4\eta)) + \zeta\right)\nonumber\\ &\leq 4C_3\sum_i \left(\mu_{W^-(v)}(A(v,R,5\eta)) + \zeta\right) \leq 4C_2 C_3 (\epsilon + \zeta) \end{align} $$
    which is arbitrarily small for $\eta $ small and k large.

Now we state and sketch the general uniform orthogeodesic counting for convergent sequences of convex sets in strongly convergent hyperbolic n-manifolds. For a thorough presentation, we refer the reader to Theorem 5.5 in the Appendix.

Theorem 5.3. Suppose that $(M_{k}=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which strongly converges to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/\Gamma $ with $\delta (\Gamma )>(n-1)/2$ . Let $(D^{\pm }_{k})_{k\in \mathbb {N}}$ be a sequence of well-positioned convex subsets in $M_k$ which converges strongly to a well-positioned convex subset $D^{\pm }$ in M, respectively. Then we can count $\mathcal N_{D^{-}_k, D^{+}_k}(t)$ uniformly, in the sense that

$$ \begin{align*}\mathcal N_{D^{-}_k, D^{+}_k}(t)\approx\dfrac{||\sigma^{+}_{D^{-}_k}||\cdot || \sigma^{-}_{D^{+}_k}||}{\delta(\Gamma_k) ||m^k_{\mathrm{{BM}}}||} e^{\delta(\Gamma_k) t}\end{align*} $$

up to a multiplicative error uniformly close to 1 along the sequence as t gets larger, and with $||\sigma ^{\mp }_{D^{\pm }_k}||, ||m^k_{\mathrm {{BM}}}||,\delta (\Gamma _k) $ converging to $||\sigma ^{\pm }_{D^{\mp }}||, ||m_{\mathrm {{BM}}}||,\delta (\Gamma )$ , respectively. In particular, for $n=3$ , there exist constants $A>0,0<b<2$ so that

$$ \begin{align*}\mathcal N_{D^{-}_k, D^{+}_k}(t)\leq Ae^{bt}\end{align*} $$

Proof. There is an explicit counting formula of $\mathcal N_{D^{-}, D^{+}}(t)$ for orthogeodesic arcs between two convex sets $D^{\pm }$ given in [Reference Parkkonen and PaulinPP17, Theorem 3]:

$$ \begin{align*}\mathcal N_{D^{-}, D^{+}}(t)=\dfrac{||\sigma^{+}_{D^{-}}||\cdot || \sigma^{-}_{D^{+}}||}{\delta ||m_{\mathrm{{BM}}}||} e^{\delta(\Gamma) t}(1+O(e^{-\kappa t})).\end{align*} $$

This formula holds under the assumption that $(\mathbb {H}^{n}, \Gamma )$ has radius-continuous strong stable/unstable masses. The constant $O(\cdot )$ and the parameter $\kappa $ depend on $\Gamma $ , the convex sets $D^{\pm }$ , the speed of mixing, and the property of radius-continuous strong stable/unstable masses.

By Proposition 4.2 and Corollary 1.8, the Bowen-Margulis measure and the skinning measures converge to the ones of the limit manifold M weakly. The critical exponent $\delta (\Gamma _{k})$ converges to $\delta (\Gamma )$ [Reference McMullenMcM99, Theorem 1.5]. The convergence of the speed of mixing is controlled by the spectral gap [Reference Edwards and OhEO21]. Hence, this quantity also converges to the one of the limit manifold by Theorem 1.1. Therefore, it suffices to prove the sequence $\Gamma _k$ and the limit $\Gamma $ have uniform radius-continuous strong stable/unstable ball masses property, which follows from Proposition 5.2.

Remark 5.4. Careful readers might notice that [Reference Parkkonen and PaulinPP17, Theorem 3] has the assumption that the manifold has radius-Hölder-continuous strong stable/unstable ball masses, which is not satisfied by the strongly convergent sequence of hyperbolic manifolds $M_k$ and the limit manifold M. However, this assumption can be replaced by the property of radius-continuous strong stable/unstable masses [Reference Parkkonen and PaulinPP17, Lemma 11], and the uniform radius-continuity suffices to control the error term in our setting. We write down the details about the replacement in the Appendix for readers’ convenience, and most of the arguments follow from [Reference Parkkonen and PaulinPP17].

Proof of Theorem 1.3.

By Example 2.12, connected components $D_{k}^{\pm }$ in the thin part of $M_{k}$ are well-positioned convex sets that are strongly convergent to the well-positioned convex sets $D^{\pm }$ (respectively). By Theorem 5.3, there is a uniform counting formula for orthogeodesics between $D^{-}_{k}$ to $D^{+}_{k}$ along the sequence. This proves Item (1). Similarly, for small $r>0$ , the radius r embedded balls centered at $x_{k}$ are well-positioned convex subsets which are strongly convergent to the embedded r-ball centered at x. In that case, let $D^{+}_{k}=D^{-}_{k}$ be the radius r ball at $x_k$ , and $D^+=D^-$ be the radius r ball at x. Observe that if we change the radius $r>0$ to a radius $s>0, s<r$ , we have a one-to-one correspondence between the set of orthogeodesics by extending/shortening the geodesic arcs. Such correspondence takes an orthogeodesic of length $\ell $ to its extension of length $\ell +2(r-s)$ . Hence, applying Theorem 5.3 again and making s arbitrarily small (or equivalently, translating by $2r$ the counting function for the balls of radius r), we obtain the uniform counting for geodesic loops based at $x_k$ along the sequence.

Proof of Corollary 1.5.

As explained for instance by Roblin in [Reference RoblinRob03, Chapter 5], one can deduce an asymptotic counting of closed primitive geodesics in manifolds with negative pinched curvature from the asymptotic counting of orbit distance (i.e., geodesic loops), which only depends on the geometry of the universal cover. Namely, if $\mathcal {G}_{M}(\ell )$ is the set of closed primitive geodesics in M of length less than $\ell>0$ , then [Reference RoblinRob03, Corollary 5.3]

$$\begin{align*}\#\mathcal{G}_{M}(\ell) \approx \frac{e^{\delta\ell}}{\delta\ell} \text{ as } \ell\rightarrow+\infty. \end{align*}$$

Combining with the uniform counting of geodesic loops (Theorem 1.3), we obtain the uniform counting of closed primitive geodesics along a strongly convergent sequence of hyperbolic manifolds.

Appendix

Let’s start with notations needed in the Appendix. Recall that $P_{D}: \mathbb {H}^{n}\cup (\partial _{\infty } \mathbb {H}^{n}\setminus \partial _{\infty } D)\rightarrow D$ is the closest point map defined in Section 2.4 for any nonempty proper closed convex subset D in $\mathbb {H}^{n}$ . Let $P^{+}_{D}$ denote the inverse of the restriction to $\partial ^{1}_{+}D $ of the positive endpoint map $v\mapsto v_{+}$ , which is a homeomorphism from $\partial _{\infty } \mathbb {H}^{n}\setminus \partial _{\infty } D$ to $\partial ^{1}_{+} D$ . It is a natural lift of $P_{D}$ , such that $\pi \circ P^{+}_{D}=P_{D}$ on $\partial _{\infty } \mathbb {H}^{n}\setminus \partial _{\infty } D$ , where $\pi : T^{1}\mathbb {H}^{n}\rightarrow \mathbb {H}^{n}$ . Similarly, one can define $P^{-}_{D}=\iota \circ P^{+}_{D}$ , where $\iota : T^{1}\mathbb {H}^{n}\rightarrow T^{1} \mathbb {H}^{n}$ is the antipodal flip map given by $\iota v=-v$ .

Define

$$ \begin{align*}\mathcal U_{D}^{\pm}=\{v\in T^{1}\mathbb{H}^{n}: v_{\pm}\notin \partial_{\infty} D\}.\end{align*} $$

This is an open set in $T^{1}\mathbb {H}^{n}$ which is invariant under the geodesic flow and satisfies the $\mathcal U^{\pm }_{\gamma D}=\gamma \mathcal U^{\pm }_{D}$ for any $\gamma \in \operatorname {\mathrm {Isom}}(\mathbb {H}^{n})$ . Define a fibration $f_{D}^{+}: \mathcal U^{+}_{D}\rightarrow \partial ^{1}_{+} D$ as the composition of the positive endpoint map and $P^{+}_{D}$ . Given $w\in \partial ^{1}_{+} D$ , the fiber of w for $f^{+}_{D}$ is the set

$$ \begin{align*}W^{0+}(w)=\{v\in T^{1}\mathbb{H}^{n}: v_{+}=w_{+}\}.\end{align*} $$

Similarly, one can define a fibration $f^{-}_{D}=\iota \circ f^{+}_{D}\circ \iota : \mathcal U^{-}_{D}\rightarrow \partial ^{1}_{-} D$ and the fiber $W^{0-}(w)=\{v\in T^{1}\mathbb {H}^{n}: v_{-}=w_{-}\}$ .

Suppose that $D^{\pm }$ are two well-positioned convex subsets in $M=\mathbb {H}^{n}/ \Gamma $ , and $\psi ^{\pm }\in C^{\infty }_{0}(T^{1}M)$ are compactly supported functions. Let

$$ \begin{align*}\mathcal{N}_{\psi^{-}, \psi^{+}}(t)=\sum_{\lambda, 0<\ell_\lambda\leq t} \psi^{-}(v^{-}_{\lambda})\psi^{+}(v^{+}_{\lambda}),\end{align*} $$

where the sum is taken over all common perpendiculars $\lambda $ between $D^{-}$ and $D^{+}$ whose initial vector $v^{-}_{\lambda }$ belongs to $\partial ^{1}_{+} D^{-}$ and the terminal vector $v^{+}_{\lambda }$ belongs to $\partial ^{1}_{-} D^+$ , and the length $\ell _{\lambda }\leq t$ .

In order to count orthogeodesics between $D^-$ and $D^+$ , we can parametrize the set of orthogeodesics by a quotient of $\Gamma $ up to a choice of base point. Denote by $\widetilde {D^\pm }$ the lifts of $D^\pm $ in $\mathbb {H}^n$ , and distinguish two components $D^\pm _0\subset \widetilde {D^\pm }$ . Then for each $\gamma \in \Gamma $ , we can consider the projection to M of the unique orthogeodesic between $D^-_0$ and $\gamma D^+_0$ , such that the closures of $D^{-}_{0}$ and $\gamma D^{+}_{0}$ in $\mathbb {H}^{n}\cup \partial _{\infty } \mathbb {H}^{n}$ have empty intersection. It is a simple exercise to see that $\gamma _1,\gamma _2\in \Gamma $ map to the same orthogeodesic if and only if there exists $g^\pm \in Stab(D^\pm _0)$ so that $\gamma _1 = g^-\gamma _2 g^+$ . Hence, we can parametrize orthogeodesic by taking the quotient $\Gamma /\sim := \Gamma /\lbrace \gamma _1 = g^-\gamma _2 g^+, g^\pm \in Stab(D^\pm _0) \rbrace $ . Although this labeling depends on the choice of $D^\pm _0$ , we will always work once this decision has been made. We use $v^\mp _{\gamma }\in \partial ^1_\pm D^\mp $ to denote the unit tangent vector of $\gamma $ at the start/end.

Theorem 5.5. Suppose that $(M_{k}=\mathbb {H}^{n}/ \Gamma _{k})_{k\in \mathbb {N}}$ is a sequence of hyperbolic manifolds which strongly converges to a geometrically finite hyperbolic manifold $M=\mathbb {H}^{n}/\Gamma $ with $\delta (\Gamma )>(n-1)/2$ . Let $(D^{\pm }_{k})_{k\in \mathbb {N}}$ be a sequence of well-positioned convex subsets in $M_k$ which strongly converges to $D^{\pm }$ in M, respectively. Let as well $(\psi ^\pm _k \in C^\infty _0(T^1M_k))_{k\in \mathbb {N}}$ , $\psi ^\pm \in C^\infty _0(T^1M)$ be compactly supported functions so that $\psi ^\pm _k$ converges strongly to $\psi ^\pm $ , respectively. Then, for any $\epsilon>0$ , there exists $t_0 = t_0(\epsilon ), k_0 = k_0(\epsilon )>0$ so that for any $t>t_0$ , $k>k_0$ , we have that

(13) $$ \begin{align} \frac{\sigma^{+}_{D^{-}_k}(\psi^-_k)\cdot \sigma^{-}_{D^{+}_k}(\psi^+_k)}{\delta(\Gamma_k) ||m^k_{\mathrm{{BM}}}||} -\epsilon \leq \frac{N_{\psi^{-}_k, \psi^{+}_k}(t)}{e^{\delta(\Gamma_k) t}} \leq \frac{\sigma^{+}_{D^{-}_k}(\psi^-_k)\cdot \sigma^{-}_{D^{+}_k}(\psi^+_k)}{\delta(\Gamma_k) ||m^k_{\mathrm{{BM}}}||} + \epsilon. \end{align} $$

Here, $\sigma ^{+}_{D^{-}_k}(\psi ^-_k)=\int _{\partial ^{1}_{+} D_{k}^{-}}\psi ^-_k d\sigma ^+_{k}$ , and $\sigma ^{-}_{D^{+}_k}(\psi ^+_k)$ is similarly defined.

Proof. Since both terms in (13) are bilinear in $\psi ^{\pm }_{k}$ , we can assume without loss of generality that, by using a partition of unity, the support of $\psi ^{\pm }_{k}$ is contained in a small relatively compact open set $U^{\pm }_{k}$ in $T^{1} M_k$ , and there is a small relatively compact open set $\widetilde {U^{\pm }_{k}}$ in $T^{1}\mathbb {H}^{n}$ , such that the restriction of the quotient map $q_k: T^{1}\mathbb {H}^{n}\rightarrow T^{1} M_{k}$ to $\widetilde {U^{\pm }_{k}}$ is a diffeomorphism to $U^{\pm }_{k}$ . Define $\widetilde {\psi ^\pm _k}\in C^\infty _0(T^1\mathbb {H})$ with support in $\widetilde {U^{\pm }_{k}}$ and coinciding with $\psi ^\pm \circ q_k$ on $\widetilde {U^{\pm }_{k}}$ . Similarly, we can define a compactly supported function $\tilde {\psi }\in C^\infty _0(T^1\mathbb {H})$ corresponding to $\psi $ . Observe that we can choose the lifts $\widetilde {U^{\pm }_{k}}$ and $\widetilde {\psi ^{\pm }_{k}}$ appropriately, such that $\widetilde {\psi ^\pm _k}$ converges strongly to $\widetilde {\psi ^\pm }$ and

$$\begin{align*}\int_{\partial^1_\pm \widetilde{D^\mp_k}} \widetilde{\psi^\mp_k} d\sigma^\pm_{\widetilde{D^\mp_k}} = \int_{\partial^1_\pm D^\mp_k} \psi^\mp_k d\sigma^\pm_{\partial D^\mp_k}, \end{align*}$$

where $\widetilde {D^{\pm }_k}$ are lifts of $D^{\pm }_k$ . From now on, we will distinguish components of $\widetilde {D^\pm _k}$ . By abuse of notation, we still denote by $D^\pm _k$ a connected component of $\widetilde {D^\pm _k}$ , which we assume is the only connected component of $\widetilde {D^{\pm }_{k}}$ so that the intersection of $\partial ^1_\mp D^\pm _k$ with $\widetilde {U^{\pm }_{k}}$ is nonempty by using partition of unity. Observe that then we can label other components by $\Gamma _k$ left action $\gamma \mapsto \gamma D^\pm _k$ . These labels are redundant (i.e., label the same set) if and only if $\gamma _1^{-1}\gamma _2$ belongs to the stabilizer of $D^\pm _k$ .

Take $\eta , R>0$ and k sufficiently large so that the statement of Proposition 5.2 applies for the sequence of convergent precompact subsets $(\Omega ^\pm _k:=\partial ^1_\mp \widetilde {D^\pm _k} \cap supp(\widetilde {\psi ^\pm _k}))_{k\in \mathbb {N}}$ . We will fix $R>0$ from now on, but will keep taking smaller (independent of k) $\eta $ . Observe that for small, fixed $\tau>0$ , we have the inclusion

$$\begin{align*}\mathcal{V}_{\eta e^{-\tau},Re^{-\tau}} (\Omega^\pm_k) \subset \mathcal{V}_{\eta,R} (\Omega^\pm_k) \end{align*}$$

is precompact in each slice $V^{\pm }_{w,\eta ,R}$ , and converges as a whole to $\mathcal {V}_{\eta e^{-\tau },Re^{-\tau }} (\Omega ^\pm ) \subset \mathcal {V}_{\eta ,R} (\Omega ^\pm )$ in the usual sense. If by we denote the characteristic function of a set A, then we can construct smooth functions $\chi ^\pm _k\in C^\infty (T^1 \mathbb {H}^n)$ so that the following items hold

  1. 1. For $w\in \Omega ^\pm _k, v \in W^{0\mp }(w)$

  2. 2. The Sobolev norms $\Vert \chi ^\pm _k \Vert _\beta $ are uniformly bounded (i.e., independent of k), where $\beta $ is the Sobolev norm appearing in the statement of [Reference Edwards and OhEO21, Theorem 1.1].

  3. 3. For any $w\in \Omega ^\pm _k$ , we have that

    $$\begin{align*}e^{-\epsilon} \nu^\pm_w (V^\mp_{w,\eta,R}) \leq \int_{V^\mp_{w,\eta,R}} \chi^\pm_k d\nu^\pm_w \leq \nu^\pm_w (V^\mp_{w,\eta,R}) \end{align*}$$
    for $\epsilon>0$ independent of k, where $d\nu ^\pm _w := dsd\mu _{W^\mp (w)}$ .

In order to define the test functions to apply exponential mixing, we start with the functions $H^\pm _k:\partial ^1_\mp \widetilde { D^\pm _k} \rightarrow \mathbb {R}$ defined by

$$\begin{align*}H^\pm_k(w) = \frac{1}{\int_{V^\mp_{w,\eta,R}} \chi^\pm_k d\nu^\pm_w}. \end{align*}$$

Let $\Phi ^\pm _k:T^1 \mathbb {H}^n\rightarrow \mathbb {R}$ defined by

$$\begin{align*}\Phi^\pm_k = (H^\pm_k \widetilde{\psi^\pm_k})\circ f^\mp_{D^\pm_k}\chi^\pm_k. \end{align*}$$

By construction, we have that $\Vert \Phi ^\pm _k \Vert _\beta $ are uniformly bounded and have support in $\mathcal {V}_{\eta ,R} (\Omega ^\pm _k)$ . Moreover, $\Phi ^\pm _k$ are nonnegative, measurable functions satisfying

(14) $$ \begin{align} \int_{T^1\mathbb{H}^n}\Phi^\pm_k d\tilde{m}^k_{\mathrm{{BM}}} = \int_{\partial^1_\mp D^\pm_k} \psi^\pm_k d\sigma_{k}^\mp .\end{align} $$

Following [Reference Parkkonen and PaulinPP17], we will estimate in two ways the quantity

(15) $$ \begin{align} I_k(T) := \int^T_0 e^{\delta(\Gamma_k) t} \sum_{\gamma\in\Gamma_k} \int_{T^1\mathbb{H}^n} (\Phi^-_k\circ g^{-t/2})(\Phi^+_k\circ g^{t/2}\circ \gamma^{-1}) d\tilde{m}^k_{\mathrm{{BM}}}dt .\end{align} $$

By [Reference Edwards and OhEO21, Theorem 1.1] and Theorem 1.1, there exist uniform $\kappa>0, O(.)$ , such that

(16) $$ \begin{align} I_k(T) &= \int^T_0 e^{\delta(\Gamma_k) t} \left(\frac{1}{\Vert m^k_{\mathrm{{BM}}}\Vert} \int_{T^1\mathbb{H}^n}\Phi^-_k d\tilde{m}^k_{\mathrm{{BM}}} \int_{T^1\mathbb{H}^n}\Phi^+_k d\tilde{m}^k_{\mathrm{{BM}}} + O(e^{-\kappa t}\Vert \Phi^-_k \Vert_\beta\Vert \Phi^+_k \Vert_\beta)\right)dt\nonumber\\ &=\frac{e^{\delta(\Gamma_k) T}}{\delta(\Gamma_k)\Vert m^k_{\mathrm{{BM}}}\Vert} \int_{\partial^1_- D^-_k} \psi^- d\sigma_{k}^- \int_{\partial^1_+ D^+_k} \psi^+ d\sigma_{k}^+ + \int^T_{0} e^{\delta(\Gamma_k) t} O(e^{-\kappa t}\Vert \Phi^-_k \Vert_\beta\Vert \Phi^+_k \Vert_\beta)dt\nonumber\\ &=e^{\delta(\Gamma_k) T} \left( \frac{\sigma^{+}_{D^{-}_k}(\psi^-_k)\cdot \sigma^{-}_{D^{+}_k}(\psi^+_k)}{\delta(\Gamma_k) \Vert m^k_{\mathrm{{BM}}}\Vert} + e^{-\delta(\Gamma_k) T}\int^T_{0} e^{\delta(\Gamma_k) t} O(e^{-\kappa t}\Vert \Phi^-_k \Vert_\beta\Vert \Phi^+_k \Vert_\beta)dt\right),\end{align} $$

where we used (14) for the second equality. Observe in the final line that we can make the error term $e^{-\delta (\Gamma _k) T}\int ^T_{0} e^{\delta (\Gamma _k) t} O(e^{-\kappa t}\Vert \Phi ^-_k \Vert _\beta \Vert \Phi ^+_k \Vert _\beta )dt$ arbitrarily small for any $T>T_0$ , where $T_0$ is sufficiently large and independent of k. Now we use a second way to compute this integral $I_{k}(T)$ . Let $\delta _k=\delta (\Gamma _k)$ . We interchange the integral over t and the summation over $\gamma $ . Then

$$ \begin{align*}I_{k}(T)=\sum_{\gamma\in \Gamma_k} \int_{0}^{T} e^{\delta_{k} t} \int_{T^{1}\mathbb{H}^{n}}(\Phi^{-}_{k} \circ g^{-t/2})(\Phi^{+}_{k}\circ g^{t/2}\circ \gamma^{-1})d \tilde{m}^{k}_{\mathrm{{BM}}} dt.\end{align*} $$

Suppose that if $v\in T^{1}\mathbb {H}^{n}$ belongs to the support of $(\Phi ^{-}_{k} \circ g^{-t/2})(\Phi ^{+}_{k}\circ g^{t/2}\circ \gamma ^{-1})$ , then

$$ \begin{align*}v\in g^{t/2} \mathcal{V}_{\eta, R}(\partial^{1}_{+}D_{k}^{-})\cap g^{-t/2} \mathcal{V}_{\eta, R}(\gamma \partial^{1}_{-}D_{k}^{+}).\end{align*} $$

Then by [Reference Parkkonen and PaulinPP17, Lemma 7], which is proved by using hyperbolic geometry in $\mathbb {H}^{n}$ , we have the following

(17) $$ \begin{align} d(w_{k}^{\pm}, v_{\gamma}^{\pm})=O(\eta+e^{-\ell_{\gamma}/2}) ,\end{align} $$

where $w_{k}^{-}=f^{+}_{D_{k}}(v), w_{k}^{+}=f^{-}_{\gamma D_{k}^{+}}(v)$ , $v_{\gamma }^{\pm }$ are endpoints of the common perpendicular between $D_{k}^{-}$ and $\gamma D_{k}^{+}$ , and $\ell _{\gamma }$ is the length of the common perpendicular. Since the Lipschitz norm of $\widetilde {\psi ^\pm _k}$ are uniformly bounded, and in particular bounded by the $\beta $ Sobolev norm of $\psi ^\pm _k$ , we have

$$ \begin{align*}|\widetilde{\psi^{\pm}_{k}}(w^{\pm}_{k})-\widetilde{\psi^{\pm}_{k}}(v^{\pm}_{\gamma})|=O((\eta+e^{-\ell_{\gamma}/2})|| \psi_{k}^{\pm}||_{\beta}).\end{align*} $$

If we define $\hat {\Phi }^{\pm }_{k}=H^{\pm }_{k}\circ f^{\mp }_{D^{\pm }_{k}}\chi ^{\pm }_{k}$ so that $\Phi ^\pm _k= (\widetilde {\psi ^\pm _k}\circ f^\mp _{D_{k}^{\pm }})\hat {\Phi }^\pm _k$ , by applying the previous equation, we obtain

(18) $$ \begin{align} I_{k}(T)=\sum_{\gamma \in \Gamma_{k}} [\psi_{k}^{\pm}(v_{\gamma}^{-}) \psi_{k}^{\pm}(v^{+}_{\gamma})&+O((\eta+e^{-\ell_{\gamma}/2})|| \psi^{-}_{k}||_{\beta} || \psi^{+}_{k}||_{\beta})]\times \nonumber\\ &\int_{0}^{T} e^{\delta_{k}t} \int_{v\in T^{1}\mathbb{H}^{n}} \hat{\Phi}^{-}_{k}(g^{-t/2}v) \hat{\Phi}^{+}_{k}(\gamma^{-1} g^{t/2}v) d\tilde{m}_{\mathrm{{BM}}}^{k}(v)dt, \end{align} $$

for $O(.)$ independent of k.

We now related another test function to $\hat {\Phi }^{\pm }_{k}$ following [Reference Parkkonen and PaulinPP17, Lemma 8]. Let $h^{\pm }_{k}: T^{1}\mathbb {H}^{n}\rightarrow \left [ 0, \infty \right ] $ be the $\Gamma _{k}$ -invariant measurable map defined by

(19) $$ \begin{align} h^{\mp}_{k}(w)=\dfrac{1}{2\eta \mu_{W^{\pm}_{w}}(B^{\pm}(w, R))} \end{align} $$

if $\mu _{W^{\pm }(w)}(B^{\pm }(w, R))>0$ , and $h^{\pm }_{k}(w)=0$ otherwise. We define the test function $\phi ^{\mp }_{k}=\phi ^{\mp }_{\eta , R, \Omega ^{\pm }_{k}}: T^{1}\mathbb {H}^{n}\rightarrow \left [ 0, \infty \right ] $ by

By the properties of $\chi _{k}^{\pm }$ , we have

$$ \begin{align*}\phi^{\pm}_{\eta e^{-\tau}, R e^{-\tau}, \partial^{1}_{\mp} \Omega^{\pm}_{k}} e^{-\epsilon}\leq \hat{\Phi}^{\pm}_{k}\leq \phi^{\pm}_{k}.\end{align*} $$

Hence, it suffices to consider the integral

(20) $$ \begin{align} i_{k}(T)=\sum_{\gamma \in \Gamma_{k}} [\psi_{k}^{\pm}(v_{\gamma}^{-}) \psi_{k}^{\pm}(v^{+}_{\gamma})&+O((\eta+e^{-\ell_{\gamma}/2})|| \psi^{-}_{k}||_{\beta} || \psi^{+}_{k}||_{\beta})]\times \nonumber\\ &\int^{T}_{0} e^{\delta_{k} t} \int_{T^{1} \mathbb{H}^{n}} (\phi^{-}_{k}\circ g^{-t/2})(\phi^{+}_{k}\circ g^{t/2}\circ \gamma^{-1})d \tilde{m}^{k}_{\mathrm{{BM}}} dt. \end{align} $$

By the definition of $\phi _{k}^{\pm }$ , the right-hand side of (20) is equal to

(21)

By the $\Gamma $ -invariance of $h^{\pm }_{k}$ , one has

$$ \begin{align*}h^{-}_{k} \circ f^{+}_{D^{-}_{k}}(g^{-t/2}v)&=e^{-\delta_{k}(t/2)} h^{-}_{k, e^{-t/2}R}(g^{t/2}w^{-}_{k}),\\h^{+}_{k}\circ f^{-}_{D^{+}_{k}}(\gamma^{-1} g^{t/2}v)&=e^{-\delta_{k}(t/2)}h^{+}_{k, e^{-t/2}R}(g^{-t/2}w^{+}_{k}), \end{align*} $$

where $w^{-}_{k}=f^{+}_{D^{-}_{k}}(v)$ , $w^{+}_{k}=f^{-}_{\gamma D^{+}_{k}}(v)=\gamma f^{-}_{D^{+}_{k}} (\gamma ^{-1}v)$ , and $h^{-}_{k, e^{-t/2}R}$ is defined the same as in (19), except we replace R by $e^{-t/2}R$ . Therefore,

$$ \begin{align*}h^{-}_{k}\circ f^{+}_{D_{k}^{-}}(g^{-t/2}v)h^{+}_{k}\circ f^{-}_{D_{k}^{+}}(\gamma^{-1} g^{t/2}v)=e^{-\delta_{k}t} h^{-}_{k, e^{-t/2}R}(g^{t/2}w^{-}_{k})h^{+}_{k, e^{-t/2}R}(g^{-t/2}w^{+}_{k}).\end{align*} $$

The remaining part is nonzero if and only if

$$ \begin{align*}v\in g^{t/2} \mathcal{V}_{\eta, R}(\Omega_{k}^{-})\cap \gamma g^{-t/2} \mathcal{V}_{\eta, R}(\Omega_{k}^{+})=\mathcal{V}_{\eta, e^{-t/2}R}(g^{t/2}\Omega^{-}_{k})\cap \mathcal{V}_{\eta, e^{-t/2}R}(\gamma g^{-t/2}\Omega^{+}_{k}).\end{align*} $$

By [Reference Parkkonen and PaulinPP17, Lemma 7], there exist constants $t_{0}>0$ and $c_{0}$ (independent of k), such that if $t\geq t_{0}$ , the following holds: there exists a common perpendicular $\alpha _{\gamma }$ from $D^{-}_{k}$ to $\gamma (D^{+}_{k})$ with

  1. 1. $\vert \ell _{\gamma }-t \vert \leq 2\eta +c_{0} e^{-t/2}$ ,

  2. 2. $d(\pi (v^{\pm }_{\gamma }), \pi (w^{\pm }_{k}))\leq c_{0}e^{-t/2},$

  3. 3. $d(\pi (g^{\pm t/2}w^{\mp }_{k}), \pi (v))\leq \eta +c_{0}e^{-t/2}$ .

For all $\gamma \in \Gamma _{k}$ and $T\geq t_{0}$ , we define

$$ \begin{align*}\mathcal{A}_{k, \gamma}(T)=\{ (t, v)\in [t_{0}, T]\times T^{1}\mathbb{H}^{n}: v\in \mathcal{V}_{\eta, e^{-t/2}R}(g^{t/2}\Omega^{-}_{k})\cap \mathcal{V}_{\eta, e^{-t/2}R}(\gamma g^{-t/2}\Omega^{+}_{k})\},\end{align*} $$

and the integral

(22) $$ \begin{align} j_{k, \gamma}(T)& =\int\int_{(t, v)\in \mathcal{A}_{k, \gamma}(T)} h^{-}_{k, e^{-t/2}R}(g^{t/2}w^{-}_{k})h^{+}_{k, e^{-t/2}R} (g^{-t/2} w^{+}_{k}) dt d \tilde{m}_{BM}^{k}(v)\nonumber\\ &=\dfrac{1}{(2\eta)^{2}} \int \int_{(t, v)\in \mathcal{A}_{k, \gamma}(T)}\dfrac{dt d\tilde{m}^{k}_{BM}(v)}{\mu_{W^{+}(w^{-}_{t})}(B^{+}(w^{-}_{t}, r_{t})) \mu_{W^{-}(w^{+}_{t})} (B^{-}(w^{+}_{t}, r_{t}))} ,\end{align} $$

where

$$ \begin{align*}r_{t}=e^{-t/2}R, \quad w^{-}_{t}=g^{t/2}w^{-}_{k}, \quad w^{+}_{t}=g^{-t/2} w^{+}_{k}.\end{align*} $$

There exists then a constant $c^{\prime \prime }_{0}>0$ (independent of k), such that for $T\geq t_{0}$ , one has

(23) $$ \begin{align} -c^{\prime\prime}_{0}+\sum_{\gamma\in \Gamma_{T-O(\eta+e^{-\ell_{\gamma}/2}), -O(\eta+e^{-\ell_{\gamma}/2}), k}} [\psi_{k}^{\pm}(v_{\gamma}^{-}) \psi_{k}^{\pm}(v^{+}_{\gamma})&+O((\eta+e^{-\ell_{\gamma}/2})|| \psi^{-}_{k}||_{\beta} || \psi^{+}_{k}||_{\beta})] j_{k, \gamma}(T)\nonumber\\&\leq i_{k}(T)\leq\nonumber\\ c^{\prime\prime}_{0}+\sum_{\gamma\in \Gamma_{T+O(\eta+e^{-\ell_{\gamma}/2}), O(\eta+e^{-\ell_{\gamma}/2}), k}} [\psi_{k}^{\pm}(v_{\gamma}^{-}) \psi_{k}^{\pm}(v^{+}_{\gamma})&+O((\eta+e^{-\ell_{\gamma}/2})|| \psi^{-}_{k}||_{\beta} || \psi^{+}_{k}||_{\beta})] j_{k, \gamma}(T+O(\eta+e^{-\ell_{\gamma}/2})), \end{align} $$

where $\Gamma _{s, r, k}=\{\gamma \in \Gamma _k| t_0+2+c_0\leq \ell _\gamma \leq s, v^{\pm }_{\gamma }\in N_{r}\Omega ^{\pm } \}$ for all $s, r\in \mathbb {R}$ .

Claim 5.6. For any $\epsilon>0$ , if $\eta $ is small enough and $\ell _{\gamma }$ is large enough, then

$$ \begin{align*}j_{k, \gamma}(T)=e^{O(\eta+e^{-\ell_{\gamma}/2})}e^{O(\epsilon^{c'})}\dfrac{(2\eta+O(e^{-\ell_{\gamma}/2}))^{2}}{(2\eta)^{2}},\end{align*} $$

for $c'>0$ independent of k.

Proof. Since $(\mathbb {H}^{n}, \Gamma _{k})$ has radius-continous strong stable/unstable ball masses. By [Reference Parkkonen and PaulinPP17, Lemma 11], for every $\epsilon>0$ and every $(t, v)\in \mathcal {A}_{k, \gamma }(T)$ , one has

$$ \begin{align*}\mu_{W^{\pm}(w_{t}^{\mp})}(B^{\pm}(w^{\mp}_{t}, r_{t}))=e^{O(\epsilon)} \mu_{W^{\pm}(v_{\gamma})} (B^{\pm}(v_{\gamma}, r_{\ell_{\gamma}}))\end{align*} $$

if $\eta $ is small enough and $\ell _{\gamma }$ is large enough, independent of k. Here, $v_{\gamma }$ denote the midpoint of the common perpendicular from $D^{-}_{k}$ to $\gamma (D^{+}_{k})$ . Hence,

$$ \begin{align*}j_{k, \gamma}(T)=\dfrac{e^{O(\epsilon)}\int\int_{(t, v)\in \mathcal{A}_{k, \gamma}(T)} dt d\tilde{m}_{\mathrm{{BM}}}^{k}(v)}{\mu_{W^{+}(v_{\gamma})} (B^{+}(v_{\gamma}, r_{\ell_{\gamma}}))\mu_{W^{-}(v_{\gamma})} (B^{-}(v_{\gamma}, r_{\ell_{\gamma}}))}.\end{align*} $$

By [Reference Parkkonen and PaulinPP17, Lemma 10], for every $(t, v)\in \mathcal {A}_{k, \gamma }(T)$ , one has

$$ \begin{align*}dt d\tilde{m}_{\mathrm{{BM}}}^{k}(v)=e^{O(\eta+e^{-\ell_{\gamma}/2})}dt ds d\mu_{W^{-}(v_{\gamma})}(v') d\mu_{W^{+}(v_{\gamma})}(v")dt,\end{align*} $$

where $v'=f^{+}_{HB_{-}(v_{\gamma })}(v)$ and $v"=f^{-}_{HB_{+}(v_{\gamma })}(v)$ . By [Reference Parkkonen and PaulinPP17, Lemma 9], the distances $d(v, v_{\gamma }), d(v', v_{\gamma })$ , and $d(v", v_{\gamma })$ are $O(\eta +e^{-t/2})$ . Combining these equations together, the claim follows.

Applying then Claim 5.6 in equation (23), we get

(24) $$ \begin{align} I_k(t) = \sum_{\gamma\in \Gamma_{k}} &[\psi_{k}^{\pm}(v_{\gamma}^{-}) \psi_{k}^{\pm}(v^{+}_{\gamma})] + O(\eta e^{\delta_k t}), \end{align} $$

for t sufficiently large independent of k, and $O(.)$ independent of $k,\eta $ . Then by multiplying $e^{-\delta _k t}$ to equations (16), (24), we get that for fixed $\eta>0$

(25) $$ \begin{align} \frac{\sigma^{+}_{D^{-}_k}(\psi^-_k)\cdot \sigma^{-}_{D^{+}_k}(\psi^+_k)}{\delta(\Gamma_k) ||m^k_{\mathrm{{BM}}}||} - O(\eta) \leq \frac{N_{\psi^{-}_k, \psi^{+}_k}(t)}{e^{\delta(\Gamma_k) t}} \leq \frac{\sigma^{+}_{D^{-}_k}(\psi^-_k)\cdot \sigma^{-}_{D^{+}_k}(\psi^+_k)}{\delta(\Gamma_k) ||m^k_{\mathrm{{BM}}}||} + O(\eta) \end{align} $$

for t sufficiently large independent of k and $O(.)$ independent of $k,\eta $ , from where the result follows.

More about the proof of Theorem 5.3.

As $(D^\pm _k)_{k\in \mathbb {N}}$ is a sequence of well-positioned convex sets in $M_k$ which converges strongly to a well-positioned set $D^\pm $ in M, we can select $\psi ^\pm _k \in C^\infty _0(T^1M_k)$ , $\psi ^\pm \in C^\infty _0(T^1M)$ be compactly supported functions so that $(\psi ^\pm _k)_{k\in \mathbb {N}}$ converges strongly to $\psi ^\pm $ and $\psi ^\pm _k \equiv 1$ in $supp(\sigma ^\mp _{\partial D^\pm _k})$ . Hence, in the notation of Theorem 5.5

$$\begin{align*}\mathcal N_{\psi^-_k, \psi^+_k}(t) =\mathcal N_{D^{-}_k, D^{+}_k}(t),\quad \sigma^\mp_{D^\pm_k}(\psi^\pm_k)= \Vert \sigma^\mp_{D^\pm_k}\Vert, \end{align*}$$

and in particular $\frac {\sigma ^{+}_{D^{-}_k}(\psi ^-_k)\cdot \sigma ^{-}_{D^{+}_k}(\psi ^+_k)}{\delta (\Gamma _k) ||m^k_{\mathrm {{BM}}}||}\neq 0$ . Then we can restate the conclusion of Theorem 5.3 by a multiplicative error uniformly close to 1 along the sequence as t gets larger.

Acknowledgments

We would like to thank Martin Bridgeman for pointing out the uniform counting question to us, and Hee Oh for suggesting Proposition 1.6 and useful discussions. We are very grateful to Curtis T. McMullen and Frédéric Paulin for helpful comments on an earlier draft, and Ian Biringer for email correspondence. We also appreciate the anonymous referees for the helpful suggestions. The first author is partially supported by the National Science Foundation under grant DMS-2203237. The second author is supported by the National Science Foundation under grant DMS-2001997.

Competing interest

The authors have no competing interest to declare.

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