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Hindawi Publishing Corporation Advances in Difference Equations Volume 2011, Article ID 963463, 15 pages doi:10.1155/2011/963463 Research Article Existence of Mild Solutions to Fractional Integrodifferential Equations of Neutral Type with Infinite Delay Fang Li1 and Jun Zhang2 School of Mathematics, Yunnan Normal University, Kunming 650092, China Department of Mathematics, Central China Normal University, Wuhan 430079, China Correspondence should be addressed to Fang Li, fangli860@gmail.com Received December 2010; Accepted 30 January 2011 Academic Editor: Jin Liang Copyright q 2011 F Li and J Zhang This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited We study the solvability of the fractional integrodifferential equations of neutral type with infinite delay in a Banach space X An existence result of mild solutions to such problems is obtained under the conditions in respect of Kuratowski’s measure of noncompactness As an application of the abstract result, we show the existence of solutions for an integrodifferential equation Introduction The fractional differential equations are valuable tools in the modeling of many phenomena in various fields of science and engineering; so, they attracted many researchers cf., e.g., 1–6 and references therein On the other hand, the integrodifferential equations arise in various applications such as viscoelasticity, heat equations, and many other physical phenomena cf., e.g., 7–10 and references therein Moreover, the Cauchy problem for various delay equations in Banach spaces has been receiving more and more attention during the past decades cf., e.g., 7, 10–15 and references therein Neutral functional differential equations arise in many areas of applied mathematics and for this reason, the study of this type of equations has received great attention in the last few years cf., e.g., 12, 14–16 and references therein In 12, 16 , Hern´ ndez and Henr´quez a ı studied neutral functional differential equations with infinite delay In the following, we will extend such results to fractional-order functional differential equations of neutral type with infinite delay To the authors’ knowledge, few papers can be found in the literature for Advances in Difference Equations the solvability of the fractional-order functional integrodifferential equations of neutral type with infinite delay In the present paper, we will consider the following fractional integrodifferential equation of neutral type with infinite delay in Banach space X: dq x t − h t, xt dtq t A x t − h t, xt β t, s f s, x s , xs ds, t ∈ 0, T , x t φ t ∈ P, 1.1 t ∈ −∞, , where T > 0, < q < 1, P is a phase space that will be defined later see Definition 2.5 A is a generator of an analytic semigroup {S t }t≥0 of uniformly bounded linear operators on X Then, there exists M ≥ such that S t ≤ M h : 0, T × P → X, f : 0, T × X × P → X, β : D → R D { t, s ∈ 0, T × 0, T : t ≥ s} , and xt : −∞, → X defined by x t θ , for θ ∈ −∞, , φ belongs to P and φ 0 The fractional derivative is xt θ understood here in the Caputo sense The aim of our paper is to study the solvability of 1.1 and present the existence of mild solution of 1.1 based on Kuratowski’s measures of noncompactness Moreover, an example is presented to show an application of the abstract results Preliminaries Throughout this paper, we set J : 0, T and denote by X a real Banach space, by L X the Banach space of all linear and bounded operators on X, and by C J, X the Banach space of all X-valued continuous functions on J with the uniform norm topology Let us recall the definition of Kuratowski’s measure of noncompactness Definition 2.1 Let B be a bounded subset of a seminormed linear space Y Kuratowski’s measure of noncompactness of B is defined as inf d > : B has a finite cover by sets of diameter ≤ d α B This measure of noncompactness satisfies some important properties Lemma 2.2 see 17 Let A and B be bounded subsets of X Then, α A ≤ α B if A ⊆ B, αA α A , where A denotes the closure of A, αA if and only if A is precompact, |λ|α A , λ ∈ R, α λA α A∪B max{α A , α B }, αA B ≤α A αA a α convA α B , where A B {x y : x ∈ A, y ∈ B}, α A for any a ∈ X, α A , where convA is the closed convex hull of A 2.1 Advances in Difference Equations For H ⊂ C J, X , we define t t H s ds u s ds : u ∈ H for t ∈ J, 2.2 where H s {u s ∈ X : u ∈ H} The following lemmas will be needed Lemma 2.3 see 17 If H ⊂ C J, X is a bounded, equicontinuous set, then α H sup α H t 2.3 t∈J Lemma 2.4 see 18 If {un }∞ ⊂ L1 J, X and there exists an m ∈ L1 J, R n m t , a.e t ∈ J, then α {un t }∞ is integrable and n ∞ t α t ≤2 un s ds n ≤ such that un t α {un s }∞ ds n 2.4 The following definition about the phase space is due to Hale and Kato 11 Definition 2.5 A linear space P consisting of functions from R− into X with semi-norm · is called an admissible phase space if P has the following properties P If x : −∞, T → X is continuous on J and x0 ∈ P, then xt ∈ P and xt is continuous in t ∈ J and x t ≤ C xt P, 2.5 where C ≥ is a constant There exist a continuous function C1 t > and a locally bounded function C2 t ≥ in t ≥ such that xt P ≤ C1 t sup x s C2 t x0 s∈ 0,t P, 2.6 for t ∈ 0, T and x as in The space P is complete Remark 2.6 2.5 in is equivalent to φ ≤C φ P, for all φ ∈ P The following result will be used later Lemma 2.7 see 19, 20 Let U be a bounded, closed, and convex subset of a Banach space X such that ∈ U, and let N be a continuous mapping of U into itself If the implication V convN V or V N V ∪ {0} ⇒ α V holds for every subset V of U, then N has a fixed point 2.7 Advances in Difference Equations Let Ω be a set defined by x : −∞, T −→ X such that x| −∞, ∈ P, x|J ∈ C J, X Ω 2.8 Motivated by 4, 5, 21 , we give the following definition of mild solution of 1.1 Definition 2.8 A function x ∈ Ω satisfying the equation ⎧ ⎪φ t , ⎪ ⎨ x t t ∈ −∞, , t ⎪−Q t h 0, φ ⎪ ⎩ s h t, xt R t − s β s, τ f τ, x τ , xτ dτ ds, t ∈ J 2.9 is called a mild solution of 1.1 , where ∞ Q t ξq σ S tq σ dσ, 2.10 ∞ Rt q σt q−1 q ξq σ S t σ dσ and ξq is a probability density function defined on 0, ∞ such that −1− 1/q σ q ξq σ σ −1/q ≥ 0, q 2.11 where q σ ∞ −1 πn n−1 −qn−1 Γ σ nq sin nπq , n! σ ∈ 0, ∞ 2.12 Remark 2.9 According to 22 , direct calculation gives that Rt where Cq,M qM/Γ ≤ Cq,M tq−1 , t > 0, 2.13 q We list the following basic assumptions of this paper H1 f : J × X × P → X satisfies f ·, v, w : J → X is measurable, for all v, w ∈ X × P and f t, ·, · : X × P → X is continuous for a.e t ∈ J, and there exist two positive functions μi · ∈ L1 J, R i 1, such that f t, v, w ≤ μ1 t v μ2 t w P, t, v, w ∈ J × X × P 2.14 Advances in Difference Equations H2 For any bounded sets D1 ⊂ X, D2 ⊂ P, and ≤ s ≤ t ≤ T, there exists an integrable positive function η such that α R t − s f τ, D1 , D2 ≤ ηt s, τ where ηt s, τ : η t, s, τ and supt∈J α D1 t s 0 sup α D2 θ −∞ such that h t1 , ϕ − h t2 , ϕ ϕ−ϕ ≤ L |t1 − t2 | P , t1 , t2 ∈ J, ϕ, ϕ ∈ P 2.16 H4 For each t ∈ J, β t, s is measurable on 0, t and β t ess sup{|β t, s |, ≤ s ≤ t} is bounded on J The map t → Bt is continuous from J to L∞ J, R , here, Bt s β t, s H5 There exists M∗ ∈ 0, such that ∗ LC1 ∗ where C1 T q βCq,M q supt∈J C1 t , β μ1 ∗ C1 μ2 L1 J, R L1 J, R < M∗ , 2.17 supt∈J β t Main Result In this section, we will apply Lemma 2.7 to show the existence of mild solution of 1.1 To this end, we consider the operator Φ : Ω → Ω defined by Φx t ⎧ ⎪φ t , ⎪ ⎨ t ∈ −∞, , ⎪−Q t h 0, φ ⎪ ⎩ t s 0 h t, xt R t − s β s, τ f τ, x τ , xτ dτ ds, t ∈ J 3.1 It follows from H1 , H3 , and H4 that Φ is well defined It will be shown that Φ has a fixed point, and this fixed point is then a mild solution of 1.1 Let y · : −∞, T → X be the function defined by y t Set x t y t ⎧ ⎨φ t , t ∈ −∞, , ⎩0, z t , t ∈ −∞, T t ∈ J 3.2 Advances in Difference Equations and for t ∈ J, It is clear to see that x satisfies 2.9 if and only if z satisfies z0 t −Q t h 0, φ zt s h t, yt zt R t − s β s, τ f τ, y τ z τ , yτ zτ dτ ds 3.3 {z ∈ Ω : z0 Let Z0 0} For any z ∈ Z0 , z · Thus, Z0 , Z0 sup z t Z0 z0 sup z t P t∈J 3.4 t∈J is a Banach space Set z ∈ Z0 : z Br Z0 ≤r , for some r > 3.5 Then, for z ∈ Br , from 2.6 , we have yt zt P ≤ yt zt P P ≤ C1 t sup y τ C2 t y0 0≤τ≤t C2 t φ ∗ ≤ C2 · φ ∗ where C2 P C1 t sup z τ C2 t z0 0≤τ≤t P 3.6 C1 t sup z τ P 0≤τ≤t ∗ C1 r : r ∗ , P sup0≤η≤T C2 η In order to apply Lemma 2.7 to show that Φ has a fixed point, we let Φ : Z0 → Z0 be an operator defined by Φz t 0, t ∈ −∞, and for t ∈ J, Φz t −Q t h 0, φ t s h t, yt zt 3.7 R t − s β s, τ f τ, y τ z τ , yτ zτ dτ ds Clearly, the operator Φ has a fixed point is equivalent to Φ has one So, it turns out to prove that Φ has a fixed point Now, we present and prove our main result Theorem 3.1 Assume that (H1)–(H5) are satisfied, then there exists a mild solution of 1.1 on −∞, T provided that L 16βη∗ < Proof For z ∈ Br , t ∈ J, from 3.6 , we have f t, y t z t , yt zt ≤ μ1 t y t ≤ μ1 t r zt μ2 t r ∗ μ2 t yt zt P 3.8 Advances in Difference Equations In view of H3 , h t, yt ≤ h t, y t zt zt − h t, ≤ L yt zt ≤ Lr ∗ h t, M1 , M1 P 3.9 supt∈J h t, where M1 Next, we show that there exists some r > such that Φ Br ⊂ Br If this is not true, then for each positive number r, there exist a function zr · ∈ Br and some t ∈ J such that Φzr t > r However, on the other hand, we have from 3.8 , 3.9 , and H4 r< Φzr t ≤ − Q t h 0, φ t s h t, yt zr t ≤ LM φ ≤ LM φ R t − s β s, τ f τ, y τ P MM1 M1 zr τ s P t Lr ∗ MM1 t−s s P t t Lr ∗ M1 dτ ds βCq,M s βr ∗ Cq,M ≤L M φ zr τ , yτ q−1 μ2 τ r ∗ dτ ds μ1 τ r 3.10 βrCq,M t−s q−1 μ1 τ dτ ds r∗ t−s q−1 μ2 τ dτ ds M1 M T q βCq,M r μ1 q r ∗ μ2 L1 J,R L1 J,R Dividing both sides of 3.10 by r, and taking r → ∞, we have ∗ LC1 T q βCq,M q μ1 L1 J,R ∗ C1 μ2 L1 J,R ≥ 3.11 This contradicts 2.17 Hence, for some positive number r, Φ Br ⊂ Br Let {zk }k∈N ⊂ Br with zk → z in Br as k → ∞ Since f satisfies H1 , for almost every t ∈ J, we get f t, y t zk t , yt zk −→ f t, y t t z t , yt zt , as k → ∞ 3.12 Advances in Difference Equations In view of 3.6 , we have zk t yt P ≤ r ∗ 3.13 Noting that zk − f t, y t t zk t , yt f t, y t z t , yt zt ≤ 2μ1 t r 2μ2 t r ∗ , 3.14 we have by the Lebesgue Dominated Convergence Theorem that Φzk t − Φz t ≤ h t, y t t s zk − h t, yt t zt ≤ L zk − zt t zk − f τ, y τ τ z τ , yτ zτ dτ ds zk τ , y τ zk − f τ, y τ τ z τ , yτ zτ dτ ds P t s 0 βCq,M −→ 0, zk τ , yτ R t − s β s, τ f τ, y τ t−s q−1 f τ, y τ k −→ ∞ 3.15 Therefore, we obtain lim Φzk − Φz k→∞ Z0 3.16 This shows that Φ is continuous Set G ·, y · z · ,y · · z· : β ·, τ f τ, y τ z τ , yτ zτ dτ 3.17 Let < t2 < t1 < T and z ∈ Br , then we can see Φz t1 − Φz t2 ≤ I1 I2 I3 I4 , 3.18 Advances in Difference Equations where I1 Q t1 − Q t2 I2 h t1 , y t t2 I3 · h 0, φ , zt1 − h t2 , yt2 zt2 , R t1 − s − R t2 − s G s, y s t1 I4 R t1 − s G s, y s t2 z s , ys z s , ys 3.19 zs ds , ds zs It follows the continuity of S t in the uniform operator topology for t > that I1 tends to 0, as t2 → t1 The continuity of h ensures that I2 tends to 0, as t2 → t1 For I3 , we have t2 ∞ I3 ≤ q t1 − s q−1 σ t2 − s q−1 σ ∞ t2 q − t2 − s q−1 ξq σ S t1 − s q σ G s, y s z s , ys zs dσds S t1 − s q σ − S t2 − s q σ ξq σ 0 × G s, y s t2 ≤ Cq,M t1 − s q−1 z s , ys zs − t2 − s q−1 q−1 S t1 − s q σ − S t2 − s q σ G s, y s t2 ∞ dσ ds z s , ys zs ds σ t2 − s q ξq σ × G s, y s ≤ β r μ1 r ∗ μ2 L1 J,R t2 × Cq,M t1 − s q−1 z s , ys zs dσ ds, L1 J,R − t2 − s q−1 ds t2 ∞ q σ t2 − s q−1 ξq σ S t1 − s q σ − S t2 − s q σ dσ ds 3.20 10 Advances in Difference Equations Clearly, the first term on the right-hand side of 3.20 tends to as t2 → t1 The second term on the right-hand side of 3.20 tends to as t2 → t1 as a consequence of the continuity of S t in the uniform operator topology for t > In view of the assumption of μi s i 1, and 3.8 , we see that I4 ≤ Cq,M t1 t1 − s q−1 G s, y s z s , ys t2 ≤ βCq,M r μ1 −→ 0, L1 J,R t1 r ∗ μ2 L1 J,R zs ds t1 − s q−1 ds 3.21 t2 as t2 −→ t1 Thus, Φ Br is equicontinuous Now, let V be an arbitrary subset of Br such that V ⊂ conv Φ V ∪ {0} Set Φ1 z t h t, yt zt , −Q t h 0, φ t s Φ2 z t R t − s β s, τ f τ, y τ z τ , yτ zτ dτ ds 3.22 Noting that for z, z ∈ V , we have h t, yt zt − h t, yt zt ≤ L zt − zt P 3.23 Thus, α h t, yt Vt ≤ Lα Vt ≤ L sup α V t −∞ and bounded set D, we can take a sequence {vn }∞ ⊂ D such n that α D ≤ 2α {vn } ε see 23 , P125 Thus, for {vn }∞ ⊂ V , noting that the choice of V , n and from Lemmas 2.2–2.4 and H2 , we have Advances in Difference Equations α Φ2 V ≤ 2α Φ2 ε 11 sup α Φ2 t ε t∈J t sup α t∈J ≤ sup t∈J ≤ 8β sup t∈J ≤ 8β sup t∈J ≤ 8β sup t∈J t β s, τ f τ, y τ τ , yτ vnτ dτds τ , yτ vnτ dτ 0 t s 0 α t s 0 t s τ , yτ ds dτ ds vnτ ε ε 3.25 s R t − s β s, τ f τ, y τ t ε s R t−s α s β s, τ f τ, y τ t∈J ≤ sup R t−s α R t − s f τ, y τ ηt s, τ α {vn τ } ηt s, τ α {vn } τ , yτ vnτ sup α {vn θ ε τ } dτ ds −∞

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