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RENORMALIZATION FOR CRITICAL ORDERS CLOSE TO 2N JUDITHCRUZANDDANIELSMANIA 0 1 Abstract. Westudythedynamicsoftherenormalizationoperatoractingon 0 thespaceofpairs(φ,t),whereφisadiffeomorphismandt∈[0,1],interpreted 2 asunimodalmapsφ◦qt,whereqt(x)=−2t|x|α+2t−1. Weprovethesocalled n complex bounds for sufficiently renormalizable pairs with bounded combina- a torics. Thisallowsustoshowthatifthecriticalexponentαisclosetoaneven J number then therenormalizationoperator hasauniquefixed point. Further- 8 more this fixed point is hyperbolic and its codimension one stable manifold contains allinfinitelyrenormalizablepairs. ] S D . h 1. Introduction t a The theory of renormalizationwere motivated by the conjecture of Feigenbaum m and P. Coullet-C. Tresser which stated that the period-doubling operator, acting [ on the space of unimodal maps, has a unique fixed-point which is hyperbolic with 1 an one-dimensional unstable direction. v Lyubich [17] proved the Feigenbaum-Coullet-Tresser conjecture for unimodal 1 maps with even critical order asserting that the period-doubling fixed point is hy- 7 perbolic,withacodimensiononestablemanifold(indeedLyubichprovedafarmore 2 1 generalresult). An extension the results of Lyubich’s hyperbolicity to the space of . Cr unimodal maps with r sufficiently large were given by E. de Faria, W. de Melo 1 and A. Pinto[8]. 0 0 All theses results on the uniqueness, hyperbolicity and universality of the fixed 1 pointoftherenormalizationoperatorareforunimodalmapswhosecriticalexponent : is an positive even integer. When the order is a non-integer positive integer, very v i few rigorous results are known. Our goal is to obtain some results in this case. X Fix α>1 andconsiderthe class ofunimodalmaps f =φ◦q :[−1,1]→[−1,1], t r where φ is orientation preserving diffeomorphism of the interval [−1,1], φ(−1) = a −1,φ(1)=1,andq (x)=−2t|x|α+2t−1.Notethatq preservestheinterval[−1,1] t t whent∈[0,1].MarcoMartens[18]proved,basedonrealmethods, theexistence of fixedpoints tothe renormalizationoperator,foreveryperiodic combinatorialtype, acting on the class of unimodal maps mentioned above. It is not clear how to see the renormalization operator, acting on the class of unimodalmaps,asananalyticoperatorwhenthecriticalexponentαisnotaneven naturalnumber. Inviewofthisproblemwedefineanewrenormalizationoperator, denoted by R , in a suitable space of pairs (φ,t), where φ◦q is a unimodal map. α t e Date:January8,2010. 2010 Mathematics Subject Classification. Primary37F25,37E20, 37E05. Key words and phrases. renormalization,unimodal,universality,hyperbolicity. PartiallysupportedbyCAPES.. PartiallysupportedbyFAPESP2008/02841-4, CNPq310964/2006-7 and303669/2009-8. 1 2 JUDITHCRUZANDDANIELSMANIA The advantage of dealing with the new renormalization operator is that it is a compact complex analytic operator when we endow the ambient space of pairs (φ,t) with a structure of a complex analytic space. The complexification of the renormalization operator is done using a result of complex a priori bounds. Then we can see that the map α7→R is a real analytic family of operators. This allow α us to use perturbation methods to solved the conjecture for the renormalization operator when the critical expoenent α is close enough to an even natural number. So we stablished Theorem A. Given a periodic combinatorics σ, if α is close enough to 2N then some iterate of the renormalization operator associate with σ acting on the space of pairs (φ,t), where φ is a real analytic map and t ∈ [0,1], has a hyperbolic fixed point with a codimension one stable manifold. Theorem B. For α is close enough to 2N, the fixed point of the renormalization operator associate with σ is unique. Also we stablished the universality for infinitely renormalizable pairs Theorem C. The stable manifold of the fixed point contains all the pairs infinitely renormalizable with the combinatorics of the fixed point. The structure of the paper is as follows. In the Section 2 we first introduce basic notions on the renormalization of unimodal maps and unimodal pairs. Then in the Section 3 we state our results on the hyperbolicity of the fixed point when the critical order is close enough to an even natural number. We present in the Section 4 the real and complex a priori bounds, the main tool in the proof of our results. In the Section 5 we introduce the composition operator, denoted by L, which relates the new renormalizationoperator and the usual one. For even α, we consider the usual renormalization operator as an operator acting on the space of holomorphicfunctionsintheSection6. Alsoweshowtherelationsbetweenthetwo renormalization operators when the critical exponent is an even natural number. In the last section we proceed to prove the main theorems. 2. Preliminaries 2.1. Some notations. Here the positive integers form the set of natural number denoted in the standard form by N. Let I be a bounded interval in the real line. The a-stadium set D (I) is the set of points in the complex plane whose distance a to the intervalI is smaller thana>0. For sets V andW containedin the complex plane we say the subset V is compactly contained in W denoting by V ⋐W. The BanachspaceCk([−1,1],R),k ∈N, isthe setofmaps Ck endowedwiththe sup norm |f| = sup {|f(x)|,|Df(x)|,...,|Dkf(x)|}. Ck([−1,1]) x∈[−1,1] WedenoteasDiff1([−1,1])the setofdiffeomorphismC1 thatpreservetheorienta- + tionoftheinterval[−1,1].ThisisanopensubsetoftheBanachspaceC1([−1,1],R). RENORMALIZATION FOR CRITICAL ORDERS CLOSE TO 2N 3 2.2. Renormalizationof unimodalmaps. Inthispartwepresentusualnotions ofthe renormalizationoperator,denotedby R. We followthe definitions andnota- tions as in A. Avila, M. Martens e W. de Melo [1]. Fix α>1, the so-calledcritical order of the unimodal map. The parametric unimodal family q :[−1,1]→[−1,1], t with t∈[0,1] and critical exponent α, is defined by q (x)=−2t|x|α+2t−1. t The parameter t defines the maximum q (0)=2t−1. Let t f =φ◦q :[−1,1]→[−1,1] t be the unimodal map where φ∈Diff1([−1,1]) and α>1 is its critical exponent. + Apermutationσ: J →J,whereJ isafinitesetwithqelements,endowedwith a total order ≺, is called a unimodal permutation with period q if it satisfies the following condition. Embedding J in the real line preserving the order ≺ , then the graph of the permutation σ on R2 extends, by the union of the consecutive points of the graph of σ by segments, to the graph of a unimodal map. Moreover the period of σ is q. A collection I = {I ,I ,...,I } of closed intervals in [−1,1] is called a cycle for 1 2 q a unimodal map f if it has the following properties: (1) there exists a repelling periodic point p∈(−1,1) with I =[−|p|,|p|]. q (2) f :I →I , i=1,2,...,q−1, are difeomorphisms. i i+1 (3) f(I )⊂I with f(p)∈∂I , the boundary of I . q 1 1 1 (4) the interiors of I ,I ,...,I are pairwise disjoint. 1 2 q Consider the collection J ={1,2,...,q} with the order relation ≺ defined by q j ≺i, j 6=i, iff infI <infI . j i Then the map σ :J →J q q σ(i)=i+1 mod q, is aunimodal permutation. We saythatσ =σ(I) is the combinatoricsofthe cycle I. As direct consequence of the definition of cycle I ={I ,I ,...,I } we have 1 2 q • I inheres an order from [−1,1], • the map σ =σ(I):I 7→I i i+1 mod q on I is an unimodal permutation, • the orientation o :I →{−1,1} I is defined such that o (I ) = 1 when fi(p) is the left extreme of I and I i i o (I )=−1 in other case. So we have the cycle I is oriented. I i Definition2.1. Aunimodalmapf =φ◦q iscalledrenormalizableifithasacycle. t The first return map to I will be, after a re-escaling,a unimodal map. The prime q renormalization period of f is the smallest q > 1 satisfying the above properties. Define the renormalization operator R such that for an unimodal renormalizable map f =φ◦q we have that Rf is a unimodal map defined by t 1 Rf(z)= fq(pz), p z ∈[−1,1]. The unimodal map Rf is called the renormalizationof f. 4 JUDITHCRUZANDDANIELSMANIA 2.3. Renormalization of a pair. Consider the set U =Diff1([−1,1])×[0,1], + where an element (φ,t)∈U should be interpretated as the unimodal map f =φ◦q :[−1,1]→[−1,1], t with critical exponent α > 1. The diffeomorphism φ is called the diffeomorphic part of the unimodal map f. The metric on U is the product metric induced by the norm of the sup on Diff1([−1,1]) and the interval metric. + Due the problemofthe nonanalyticity ofthe unimodal mapatits criticalpoint when α6∈2N, it is convenient to consider unimodal maps as a pair (φ,t). Definition 2.2. Apair(φ,t)∈U is calledrenormalizableiff =φ◦q isrenormal- t izable. The prime renormalization period of (φ,t) is the same of f. Let σ be an unimodal permutation and U ={(φ,t)∈U|f =φ◦q has a cycle I com σ(I)=σ}. σ t Let I ⊂[−1,1] be an oriented interval. We consider the zoom operator Z :Diff1([−1,1])→Diff1([−1,1]), I + + which assign to the diffeomorphism φ : I → φ(I), the diffeomorphism Z (φ) : I [−1,1]→[−1,1] defined by: Z (φ)=A ◦φ◦A−1, I φ(I) I where the transformation A : J → [−1,1] is the unique affine, orientation pre- J serving transformation carrying the closed interval J to the interval [−1,1]. The intervals I e φ(I) have the same orientation. For(φ,t)∈U ,wedefinetheorientationpreservingdiffeomorphismφ :[−1,1]→ σ 0 [−1,1] as φ0 =Zφ−1(I1)(φ). Here I = I . On the other hand for each I ∈ I, i 6= 0, we define the orientation 0 q i preserving diffeomorphism q :[−1,1]→[−1,1] e φ :[−1,1]→[−1,1] by i i q =Z (q ) i Ii t and φ =Z (φ), i qt(Ii) where q (I ) and I are orientated in the same direction, this is the orientation t i i+1 o(I ) defined by the cycle I. Furthermore, let i+1 |q (I )| t q t = . 1 |φ−1(I )| 1 Since f(I ) = φ◦ q (I ) ⊂ I , in the definition of the cycle I, we have that q t q 1 t ∈[0,1]. This is equivalent to q (0)∈φ−1(I ). 1 t 1 Now we can define the renormalization operator. The σ-renormalization opera- tor, denoted by R :U →U, σ σ is defined by the following expression e (2.1) R (φ,t)=((φ ◦q )◦...◦(φ ◦q )◦(φ ◦q )◦φ ,t ). σ q−1 q−1 2 2 1 1 0 1 e RENORMALIZATION FOR CRITICAL ORDERS CLOSE TO 2N 5 For each σ there exists a unique maximal factorization σ =< σ ,...,σ ,σ > n 2 1 such that R =R ◦...◦R ◦R . σ σn σ2 σ1 A unimodalpermutation σ is called prime iff σ =<σ >. Obviouslyeachpermuta- tioninthemaximalfactorizaetioniseprime. Soeusingeprimesunimodalpermutations we obtain a partition of the set of renormalizable pairs in U. Definition 2.3. The renormalization operator denoted by R:{renormalizable pairs}= U →U, σ σ p[rime e is defined by R|U =R . σ σ We saythatapair(φ,t)∈U isN-timesrenormalizableiffRn(φ,t)isdefinedfor e e all1≤n≤N.And(φ,t)isinfinitely renormalizableifitisN-timesrenormalizable for all N ≥1. e Definition 2.4. The setofrenormalizationtimes {q } , with Λ⊂N andwhere n n∈Λ q <q , is the set of integers q such that f is renormalizable of period q. n n+1 We say that a pair N-times renormalizable (φ,t) ∈ U, for N big enough, has bounded combinatorics by B > 0 if f = φ ◦ q satisfies q /q ≤ B, for all t n+1 n 1≤n<N. 2.4. Iterating pairs. Closely following the section 2 in [1] we observe that a se- quenceofpairsinU, producedby applyinganytimes the renormalizationoperator R , is such that each pair has as first component a decomposition of diffeomor- α phism and the second a parameter carrying the information of the unimodal part oef the unimodal map. Fix a N-times renormalizable pair f = (φ,t) ∈ U and let In = {In,In,...,In } 1 2 qn be the cycle corresponding to n-th renormalization, 1≤n≤N. Each cycle will be partitioned in sets N In = Ln. k k≥0 [ The level sets Ln, k ≥0, are defined by induction. Let k I0 =L0 ={[−1,1]}. 0 If In+1 ∋ In+1 ⊂ In ∈ Ln and 0 ∈/ In+1 then In+1 ∈ Ln+1. If 0 ∈ In+1 then i j k i i k+1 i In+1 ∈Ln+1. Observe that i 0 n In = Ln, k k≥0 [ for n ≤ N. First to In ∈ In, define the orientation preserving diffeomorphism 1 φn :[−1,1]→[−1,1] where 0 φn0 =Zφ−1(In)(φ). 1 ThenforeachIn ∈In,i6=0,definethediffeomorphisms,thatpreserveorientation, i qn :[−1,1]→[−1,1] and φn :[−1,1]→[−1,1] by i i qin =ZIin(qt) 6 JUDITHCRUZANDDANIELSMANIA and φn =Z (φ), i qt(Iin) whereq (In)andIn areorientedinthesamedirection,thisiswiththeorientation t i i+1 o(In ) defined by the cycle In. Furthermore, define i+1 |q (In)| t = t 0 . n |φ−1(In)| 1 The above definitions describe the first component of Rn(φ,t) that consists of the compositions of the diffeomorphisms qn and φn : i i e Rn(φ,t)=((φn ◦qn )◦...◦(φn◦qn)◦(φn◦qn)◦φn,t ). qn−1 qn−1 2 2 1 1 0 n e 3. Precise statements of the main results LetB be the complex Banachspaceofholomorphicmapsf definedina neigh- V borhoodV witha continuousextensionto V, endowedwith the supnorm. LetA V be the set of holomorphic maps ϕ:V →C with continuous extension in V, where ϕ(−1)=−1 and ϕ(1)=1. This is an affine subspace of B . V Denote by T the complex Banach space of holomorphic maps ω ∈ B of the V V form ω = ψ(x2n) in a neighborhood of [−1,1], with ω(−1) = ω(1) = 0, endowed with the sup norm. Let U be the set of holomorphic maps f : V → C with V continuous extension in V of the form f = ψ(x2n) in a neighborhood of [−1,1], with f(−1)=f(1)=−1. Then U is an affine space. V MarcoMartens[18,Theorem2.2]showedthatthenewrenormalizationoperator R , defined on the space of pairs whose first componentare diffeomorphisms C2 in α [−1,1] with critical exponent α>1, has fixed points of any combinatorial type. e FromnowonwefixaprimecombinatoricsσwithperiodsmallerthanB. Denote by H (C,η,M), α>1, the set of the pairs (φ,t) satisfying α (1) φ∈A , where φ is univalent on D Dη η (2) φ is real on the real line (3) |φ| ≤C C3([−1,1]) (4) (φ,t) is M-times renormalizable with combinatorics σ. A pair (φ,t) satisfying the first three above properties for some η,C is called a unimodal pair. Theorem 3.1 (Complex bounds). For all α > 1, there exists ε = ε(B), δ = 0 0 δ (B)>0 and C =C (B)>0 such for all α∈(α −ε,α +ε) the following holds: 0 0 0 0 0 for all C >0andη >0thereexistsN =N (C,η)suchthatif (φ,t)∈H (C,η,M) 0 0 α with M >N then Rn(φ,t)∈H (C ,δ ,M −n) for M >n≥N . 0 α α 0 0 0 Remark 3.2. Usingmethods ofthe proofofthe Theorem3.1andinSullivan[6]and e Martens[18] it is possible to show that the first component of the C3 fixed points (φ⋆,t⋆) of R are indeed analytic and univalent in a neighborhood of the interval α [−1,1].By Theorem3.1 wehavecomplex bounds for the diffeomorphic partofthis fixed point.eLet δ < δ /2. By Theorem 3.1 (φ⋆,t⋆) belongs to H (C ,2δ,∞). In 0 α 0 the case when α ∈ 2N, Sullivan[6] methods implies that there exists such fixed point. Fix δ such that 2δ < δ . Define N˜ = N (C ,δ), where C , N is as in Theo- 0 1 0 0 0 0 rem 3.1. Let (φ,t)∈H (C ,δ,N +1) with critical exponent α close enough to α α 0 1 0 RENORMALIZATION FOR CRITICAL ORDERS CLOSE TO 2N 7 andletINe1 ={I1Ne1,I2Ne1,...,IqNe1 }bethecyclecorrespondingtoN1-threnormaliza- Nf1 tion. Then the maps φN0e1 = Zφ−1(I1Nf1)(φ), qiNe1 = ZIiNf1(qt) and φeNie1 = Zqt(IiNf1)(φ), have univalent extensions in complex domains such that the composition (φNe1 ◦qNe1 )◦...◦(φNe1 ◦qNe1)◦(φNe1 ◦qNe1)◦φNe1 qNf1−1 qNf1−1 2 2 1 1 0 is defined in D . Then it is possible to choose γ > 0 small enough such that the 2δ 1 operator RNαe1 has a extension to the ball B((φ,t),γ˜ ):={(ψ,v)∈A ×C,|e(ψ,v)−(φ∗,t∗)|<γ }, e 1 Dδ/2 1 as a transfoermation Rα :B((φ,t),γ1)→AD2δ ×C, defined by the eexpression Rα(φ,t)=((φNqeNfe1e1−1◦eqqNeNf11−1)e◦...◦(φN2e1 ◦q2N2)◦(φN1e1 ◦q1Ne1)◦φN0e1,tNf1), whereee t = |qt(I0Ne1)| . Nf1 |φ−1(INe1)| 1 SoR isdefinedinanopenneighborhoodofH (C ,δ,N +1)inthespaceA × α α 0 1 Dδ/2 C. The natural inclusion j : A ×C → A ×C is a linear compact operator D2δ Dδ/2 betweeeen Banach spaces. Definition 3.3. The complex renormalization operator, denoted by R, is defined by e R =j◦R . α α Note that Rα is a compact operatoer. ee e Theorem 3.4 (Hiperbolicity). Fix r ∈ N. There exists η > 0 and a real analytic map α→(φ∗,t∗), where α∈(2r−η,2r+η), such that (φ∗,t∗) is a hyperbolic fixed α α α α point to the operator R , with codimension one stable manifold. α The uniqueness of the fixed point to the operator R is showedin the following e α result. The proof will be postpone to the last section. e Theorem 3.5 (Uniqueness of the fixed point). Fix r ∈ N. For each α close to 2r, there exists an unique unimodal fixed point (φ∗,t∗) of R , and it belongs to α α α H (C ,δ ,∞). α 0 0 e We define the stable manifold of the fixed point (φ∗,t∗), denoted by Ws = α α Ws(φ∗,t∗), as the set α α Ws :={(φ,t):Rn(φ,t)→(φ∗,t∗)} α α By Rn(φ,t)e→ (φ∗,t∗) α n α α wesaythatRn(φ,t)belongstoA ×Cfornlargeenough,andRn(φ,t)converges to (φ∗,t∗) in Aα ×C. eDδ α α α Dδ Let V beea neighborhood of the fixed point (φ∗,t∗) of the opeerator R . Define 1 α α α Nk (φ∗,t∗):={(φ,t):Rj(φ,t)∈V ,0≤j ≤k}}, V1 α α 1 e e 8 JUDITHCRUZANDDANIELSMANIA where k ∈N∪∞. Furthermore, we define N∞(φ∗,t∗):= Nk (φ∗,t∗), V1 α α V1 α α k∈N \ this is, the set of pairs such that all your iterates stay close to (φ∗,t∗). So we are α α ready to define the local stable manifold. Definition 3.6. For each V neighborhood of (φ∗,t∗) we define the corresponding α α local stable manifold to be Ws (φ∗,t∗):=Ws(φ∗,t∗)∩Nk (φ∗,t∗). V1 α α α α V1 α α As (φ∗,t∗) is a hyperbolic fixed point, we can choose V such that α α 1 (3.1) Ws (φ∗,t∗):=N∞(φ∗,t∗). V1 α α V1 α α Other important result is the universality for infinitely renormalizable pairs. Theorem 3.7 (Universality). Fix r ∈ N. For α close to 2r we have that all unimodal pairs (φ,t), infinitely renormalizable with combinatorics σ and order α, belongs to the stable manifold of the unique, unimodal fixed point (φ∗,t∗) of R˜ , α α α this is H (C,η,∞)⊆Ws(φ∗,t∗). α α α C>0η>0 [ [ 4. Real and complex a priori bounds We will present the main tool for the development of this work, the called com- plexbounds: thereexistsacomplexdomainV ⊃[−1,1]suchthatfornbigenough thefirstcomponentofRn(φ,t),where(φ,t)∈U satisfyingappropriatedconditions, is well defined and univalent in V. The complex boundes has a lot applications in the study of the renormalization operatorR , r ∈N. One of the most important applications is the convergence of 2r the renormalization operator in the set of the infinitely renormalization maps and the hyperbolicity of this operator in an appropriate space. Sullivan [6] introduced this property for the infinitely renormalization maps with bounded combinatorics. Others related results about infinitely renormalizable unimodal maps with no bounded combinatorics, were given by Lyubich [15], Lyubich e Yampolsky [16], Graczyk e Swiatek [12], Levin e van Strien [10]. For multimodal analytic maps, infinitely renormalizable with bounded combinatorics Smania [4] proved “complex bounds”. We obtain complex bounds for the first component of the renormalizationoper- ator R which is a univalent map. This tool is useful because it allow us to define α the complex renormalizationoperator R , where the critical exponent is α>1. α A emain ingredient in the proof of the Complex Bounds’s Theorem is given in the following lemma where we establisherealbounds. We use this to obtain control on the geometry of the cycles of pairs N-times renormalizables, for N enough big, with bounded combinatorics by a constant B >0. For a proof of the real bounds see [19, Theorem 2.1, Chapter VI]. First fix the critical exponent α>1. RENORMALIZATION FOR CRITICAL ORDERS CLOSE TO 2N 9 Lemma 4.1 (Real bounds). [19] Let B > 0 be a constant. Then there exists 0<b<1 with the following property: for all C >0, there exists N =N(B,C)≥1 such that if (φ,t)∈U is M-times renormalizable with bounded combinatorics by B with M >N, and |φ| ≤C, we have that C3([−1,1]) (1) if In+1 ⊂ In, l = 1,··· ,m are the intervals of the (n+1)-th renormal- izatiilon cyclej, where N ≤ nn< M, contained in the interval In of the n-th j cycle then |In+1| (4.1) b< il <1−b, |In| j where l=1,··· ,m , for all N ≤n<M. n (2) if J is a connected component of In\ mn In+1 then j l=1 il |J| S (4.2) b< <1−b, |In| j for all N ≤n<M. Remark 4.2. Let α > 1 and δ > 0 small enough. We can suppose that a constant b<1oftheLemma4.1isthesameforthepairs(φ,t)∈U,M-timesrenormalizables with bounded combinatorics by B, for M > N big enough, with critical order α, where |α−α|<δ. e So we can establish the following result. e Theorem 4.3. Let B >0, α>1, and C >0. There exists δ >0 and ε=ε(δ)>0, such that the following is satisfied: for each complex domain V containing the interval [−1,1] there exists N =N(B,α,C,V)≥1 such that • if (φ,t) ∈ U is M-times renormalizable with bounded combinatorics by B, for M >N, with critical order α, |α−α|<δ and φ univalent map defined on V, and • |φ| ≤C, C3([−1,1]) e e Then for all N ≤ n < M the maps φn0 = Zφ−1(I1n)(φ), qjn = ZIjn(qt) and φnj = Zφ−1(In )(φ), where j =1,··· ,qn−1, have univalent extensions for maps defined j+1 on a ε-stadium D . ε Proof. Let δ >0 and N ≥ 1 be as in the Observation 4.2. Consider the sectors in the complex plane denoted by π S+ ={z ∈C:|arg(z)|< } a a and π S− ={z ∈C:|arg(−z)|< }, a a wherea>0.Supposethatthepair(φ,t)∈U satisfiesthehypothesisofthetheorem. We fix In = {In,In,...,In} the corresponding cycle to the n-th renormalization, 1 2 q N ≤n≤M.Wedenotebyxn theboundarypointoftheintervalIn,j 6=0,nearest j j tothecriticalpoint. ThereisalevelofrenormalizationbetweenN andnsuchthat the interval containing the critical point in this level contains the interval In. So j choose the first k >0 such that In−k ⊃In, where N ≤n−k <n. Then In is not 0 j j 10 JUDITHCRUZANDDANIELSMANIA containing in In−k+1. We have two cases: 0 Case I. First when k =1. By Lemma 4.1 we obtain dist(0,xn) |In| j ≥ 0 |In| 2|In| j j |In| |In−1| = 0 · 0 2|In−1| |In| 0 j b 1 > · . 2 (1−b) Case II. For k > 1. We can see that In is contained in some interval In−k+1 ⊂ j j(n−k+1) In−k − In−k+1. Actually the interval In in contained in a nesting sequence of 0 0 j intervals of deeper levels. So In ⊂ In−1 ⊂ ···In−k+2 ⊂ In−k+1 and by the j j(n−1) j(n−k+2) j(n−k+1) Lemma 4.1 we have (1−b)k−1 (4.3) |In|<(1−b)k−1|In−k+1 |≤ ·(|In−k|−|In−k+1|). j j(n−k+1) 2 0 0 From Eq.( 4.3) we obtain dist(0,xn) |In−(k−1)| j ≥ 0 |In| 2|In| j j 1 |In−(k−1)| > · 0 (1−b)k−1 |In−k|−|In−k+1| 0 0 b > (1−b)k−1 In both cases we obtain dist(0,xn) b j > . |In| 2(1−b) j With this estimative we can define the diffeomorphisms φn, qn and φn, for j = 0 j j 1,··· ,q −1, in a common domain in the complex plane. In fact, we know the n principal branch of the logarithm function log is holomorphic on the set C\{z ∈ R:z ≤0}. Let q+ :S+ →C and q− :S− →C be the univalent maps where t α t α e e q+(z)=−2teαlogz +2t−1 t e and q−(z)=−2teαlog(−z)+2t−1. t e Wefollowtheproofdefiningacommondomaintothemapsqn,forj =1,··· ,q −1, j n taking in mind two different domains for the critical exponent α>1. Firstly when α ∈ (1,2). For Ijn ⊂ Sα+ (or Ijn ⊂ Sα−) applying the zoom operator ZIjn for the diffeomorphisms qt+|Ijn e(or qt−|Ijn ). eSo we can define qjn = ZIjn(qt+) (or qjn = ZIjn(qt−)) on the set ǫ1-stadium D ={z ∈C:dist(z,[−1,1])<ǫ }, ǫ1 1 where b ǫ = . 1 2(1−b) This set contains the interval [−1,1]. Now for α ≥ 2. We consider the distance a of the boundary point xn of the j j

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