Existence of nonnegative nontrivial periodic solutions to a doubly degenerate parabolic equation with variable exponent

The authors investigate a degenerate parabolic equation with delay and nonlocal term, which describes slow diffusive processes in physics or biology. ...

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Li and Gao Boundary Value Problems 2014, 2014:77 http://www.boundaryvalueproblems.com/content/2014/1/77

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Existence of nonnegative nontrivial periodic solutions to a doubly degenerate parabolic equation with variable exponent Zhongqing Li* and Wenjie Gao *

Correspondence: [email protected] College of Mathematics, Jilin University, Changchun, 130012, PR China

Abstract The authors investigate a degenerate parabolic equation with delay and nonlocal term, which describes slow diﬀusive processes in physics or biology. The existence of a nonnegative nontrivial periodic solution is obtained through the use of the Leray-Schauder degree method. MSC: Primary 35D05; secondary 35K55 Keywords: degenerate parabolic equation; periodic solution; variable exponent; topological degree; De Giorgi iteration

1 Introduction In this paper, we are interested in the following evolutional p(x)-Laplacian equation: ⎧ ∂u ⎪ – div(|∇um |p(x)– ∇um ) ⎪ ∂t ⎪ ⎪ ⎪ ⎨ = [a(x, t) – K(ξ , t)u (ξ , t – τ ) dξ ]u, (x, t) ∈ Q , T ⎪ ⎪ u(x, t) = , (x, t) ∈ T , ⎪ ⎪ ⎪ ⎩ u(x, ) = u(x, T), x ∈ .

(.)

Here, is a bounded simply connected domain with smooth boundary ∂ in RN , QT = × (, T), T = ∂ × (, T), T > , and τ ∈ (, +∞). We assume m > , p ∈ C ,α (), with p+ := max p(x), p– := min p(x), p+ ≥ p– >  and that a ∈ L∞ (QT ) and K ∈ L∞ (QT ) can be extended as T-periodic functions to × R. Furthermore, we assume that K ≥  for a.e. (x, t) ∈ QT . Equation (.) is a doubly degenerate parabolic equation with delay and nonlocal term, which models diﬀusive periodic phenomena in physics and mathematical biology. In biology, it arises from population model, where u(x, t) denotes the density of population at time t located at x ∈ , a is the natural growth rate of the population, the nonlocal term K(ξ , t)u (ξ , t – τ ) dξ evaluates a weighted fraction of individual, and the delayed density u at time t – τ appearing in the nonlocal term represents the time needed to an individual to become adult. In physics, problem (.) is proposed based on some evolution phenomena in electrorheological ﬂuids []. It describes the ability of a conductor to undergo signiﬁcant changes when an electric ﬁeld is imposed on. This model has been ©2014 Li and Gao; licensee Springer. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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employed for some technological applications, such as medical rehabilitation equipment and shock wave absorber. When p(x) is a constant and m > , p > , the model describes the slow diﬀusion process in physics, which has been extensively investigated; see [–]. For example, in [], the authors studied the following doubly degenerate parabolic equation with logistic periodic sources: p– ∂u – div ∇um ∇um = uα a – buβ . ∂t They proved the existence of a nontrivial nonnegative periodic solution via monotonicity method. Using a Moser iterative method (see [–]), they also obtained some a priori bounds and asymptotic behaviors for the solutions. Recently, the variable exponent Sobolev space and its applications have attracted considerable interest; see [, –] and the references therein. When p+ ≥ p– >  and m > , the doubly degenerate parabolic equation (.) is a more realistic model which describes the rather slow diﬀusion process. In our models, the principal term div(|∇um |p(x)– ∇um ), in place of the usual term um or div(|∇um |p– ∇um ), represents nonhomogeneous diﬀusion that depends on the position x ∈ and thus gives a better description of nonhomogeneous character of the process. There are many diﬀerences between Sobolev spaces with constant exponent and those with variable exponent; many powerful tools applicable in constant exponent spaces are not available for variable exponent spaces. For instance, the variable exponent spaces are no longer translation invariant and Young’s inequality f ∗gp(·) ≤ Cf p(·) g holds if and only if p is constant (see monograph []). As we all know, the frequently used Hölder’s inequality, Poincaré’s inequality, etc., will be presented in new forms for variable exponent spaces. The presence of the nonlocal term and p(x)-Laplacian term makes the sup-solution and sub-solution method (as in []) in vain. In our paper, we adopt the topological degree method (as in [–]) to show the existence of nontrivial periodic solutions to problem (.). However, the method employed in the variable exponent case [] or in the constant exponent case [–] cannot be directly used to derive the uniform upper bound for solutions, which is a crucial step in applying the topological degree method. We apply a modiﬁed De Giorgi iteration to establish the crucial uniform bound. We believe that the modiﬁed De Giorgi iteration used in this paper can be employed to other types equations with nonstandard growth conditions. We now discuss the main plan of the paper. In Section , we review some preliminaries concerning the variable exponent Sobolev spaces and introduce a family of regularized problems for problem (.). We regularize the degenerate part through replacing the term div(|∇um |p(x)– ∇um ) by  p(x)–

div ∇ σ um + u + η  ∇ σ um + u ,

, η > .

In Section , in order to apply the topological degree method, we combine these regularized problems with a relatively simpler equation and derive some a priori estimates. By virtue of the De Giorgi iteration technique, we deduce an a priori L∞ bound for solutions to the regularized problems in Proposition .; and the uniform lower bound estimate is obtained in Proposition .. In Section , we establish the existence of nonnegative non-

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trivial solution of (.) through the limit process as and η tend to zero. Finally, in the Appendix, we give a proof of the iteration lemma (Lemma .) for the sake of readability.

2 Preliminaries and the regularized problems of (1.1) First of all, for the reader’s convenience, we recall some preliminary results concerning the variable exponent Sobolev spaces. One may ﬁnd these standard results in monographs [, ]. Let p be a continuous function deﬁned in , p(x) > , for any x ∈ . . Lp(x) () space: We have L

p(x)

p(x) () := u : u is measurable in and dx < ∞ , u(x)

equipped with the following Luxemburg norm: u(x) p(x) dx ≤  . λ

|u|Lp(x) () := inf λ >  :

The space (Lp(x) (), | · |Lp(x) () ) is a separable, uniformly convex Banach space. . W ,p(x) () space: We have

W ,p(x) () := u ∈ Lp(x) () : |∇u| ∈ Lp(x) () , ,p(x)

endowed with the norm |u|W ,p(x) () := |∇u|Lp(x) () + |u|Lp(x) () . We denote by W () the closure of C∞ () in W ,p(x) (). In fact, the norm |∇u|Lp(x) () and |u|W ,p(x) () are equivalent ,p(x) ,p(x) norms in W (). W ,p(x) () and W () are separable and reﬂexive Banach spaces with the above norms. . Frequently used relationships in the estimate: + p– p p(x) p(x) dx , dx u(x) u(x) min

≤ |u|Lp(x) () + p– p p(x) p(x) ≤ max dx , dx . u(x) u(x)

. p(x)-Hölder’s inequality: For any u ∈ Lp(x) () and v ∈ Lq(x) (), with

 p(x)

+

 q(x)

= , we have

uv dx ≤  +  |u| p(x) |v| q(x) . L () L () p– q– . Embedding relationships: If p and p are in C(), and  ≤ p (x) ≤ p (x), for any x ∈ , then there exists a positive constant Cp (x),p (x) such that |u|Lp (x) () ≤ Cp (x),p (x) |u|Lp (x) () , i.e. the embedding Lp (x) () → Lp (x) () is continuous.

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If q ∈ C() and  ≤ q(x) < p∗ (x), for any x ∈ , then the embedding W q(x) L () is continuous and compact. Here

,p(x)

p∗ (x) :=

⎧ ⎨

Np(x) , N–p(x)

⎩+∞,

() →

p(x) < N, p(x) ≥ N.

. p(x)-Poincaré’s inequality: There exists a positive constant Cp such that |u|Lp(x) () ≤ Cp |∇u|Lp(x) () , for any u ∈ ,p(x) W (). We next deﬁne the weak solutions to problem (.). Deﬁnition . u is said to be a weak periodic solution to (.) provided that um ∈ – ,p(x) Lp (, T; W ()) with |∇um | ∈ Lp(x) (QT ), u ∈ C(QT ) and u satisﬁes ∂ϕ m p(x)– m = + ∇u ∇u ∇ϕ –u ∂t QT

 – auϕ + uϕ K(ξ , t)u (ξ , t – τ ) dξ dx dt,

(.)

for all ϕ ∈ C  (QT ) satisfying ϕ(x, T) = ϕ(x, ) for x ∈ and ϕ(·, t)|∂ =  for t ∈ [, T]. As in [], we introduce the following regularized problem: ⎧ p(x)– ∂u ⎪ – div{(|∇(σ um + u)| + η)  ∇(σ um + u)} ⎪ ∂t ⎪ ⎪ ⎪ ⎨ = [a – K(ξ , t)u (ξ , t – τ ) dξ ]u,

⎪ ⎪ u(·, t)|∂ = , ⎪ ⎪ ⎪ ⎩ u(·, ) = u(·, T),

a.e. (x, t) ∈ QT ,

(.)

a.e. t ∈ (, T),

p+ –

where  < <  ,  < η < (  ) p– – and σ ∈ [, ] are given constants. –

p Deﬁnition . We say that u η is a weak periodic solution of (.), if um

η ∈ L (, T; ,p(x) p(x) (QT ), u η ∈ C(QT ), and u η solves W ()) with |∇um

η | ∈ L

=

p(x)–  ∂ϕ m + ∇ σ u η + u η + η  ∇ σ um

η + u η ∇ϕ ∂t QT

– au η ϕ + u η ϕ K(ξ , t)u η (ξ , t – τ ) dξ dx dt, –u η

(.)

for all ϕ ∈ C  (QT ) satisfying ϕ(x, T) = ϕ(x, ) for x ∈ and ϕ(·, t)|∂ =  for t ∈ [, T]. Remark . For any p ∈ C ,α (), the set {ϕ ∈ C  (QT ) : ϕ(·, T) = ϕ(·, )} is dense in {ϕ ∈ – ,p(x) C(QT ) ∩ Lp (, T; W ()) : |∇um | ∈ Lp(x) (QT ), ϕ(·, T) = ϕ(·, )}, thus in the sense of the deﬁnition of weak solution above, u η can be chosen as test function.

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We investigate problem (.) extensively before studying the limit process as , η → . Deﬁne a map G η : [, ] × L∞ (QT ) → L∞ (QT ) as follows: (σ , f ) → u η = G η (σ , f ), where u η is a weak periodic solution of the problem: ⎧ p(x)– ∂u m   ∇(σ um + u)} = f , ⎪ ⎪ ⎨ ∂t – div{(|∇(σ u + u)| + η) u(·, t)|∂ = , ⎪ ⎪ ⎩ u(·, ) = u(·, T).

a.e. (x, t) ∈ QT , a.e. t ∈ (, T),

(.)

Given α ∈ L∞ (QT ), let f = f (α) ∈ L∞ (QT ) be deﬁned by

f (x, t) = f (α)(x, t) = a(x, t) – K(ξ , t)α  (ξ , t – τ ) dξ α

for (x, t) ∈ QT .

Therefore, if a nonnegative function u η ∈ L∞ (QT ) satisﬁes u η = G η (, f (u η )), then u η is a weak solution of (.). Deﬁne T η (σ , u) = G η σ , f (u) ,

(σ , u) ∈ [, ] × L∞ (QT ).

Then, according to [] or the classical regularity results from [], one obtains the following lemma. p+ –

Lemma . Assume that  < <  ,  < η < (  ) p– – and λ ∈ L∞ (QT ). Then T η is a continuous compact operator from [, ] × L∞ (QT ) to L∞ (QT ). Furthermore, u η = T η (σ , λ) ∈ C(QT ).

3 A priori estimates to the regularized problem First of all, the following modiﬁed De Giorgi iteration lemma will be useful (we give a proof in the Appendix). Lemma . (Iteration lemma) Suppose ϕ(t) is a nonnegative and nonincreasing function on [K , +∞), it satisﬁes ϕ(h) ≤

M h–k

α

ϕ β (k) + ϕ γ (k) ,

(.)

for any h > k ≥ k , and for some constants M > , α > , β > , γ > . Then ϕ(k + d) = , δ



where d = M δ– (ϕ β– (k ) + ϕ γ – (k )) α , and δ = min{β, γ }. Next, we prove a crucial a priori L∞ bound for u η via a De Giorgi iteration technique as in [].

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Proposition . Let K >  and assume that u η is a nonnegative T-periodic continuous function such that

 p(x)– ∂u – div ∇ um + u + η  ∇ um + u ≤ K u, ∂t

(.)

u(·, t)|∂ = .

(.)

Then there exists a constant R > , such that u η L∞ (QT ) < R, where R is independent of

and η. mq

Proof Step . Multiplying (.) by u η , with any q > . Integrating over and noticing that u η (·, t)|∂ = , we have

 d umq+ dx mq +  dt η

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇umq dx +

η

η

η

≤ K

umq+ dx.

η

(.)

–

p(x) p Since |∇um ≥ |∇um

η |

η | – , we deal with the second term on the left-hand side of (.) as follows.

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇umq dx

η

–

m(q–) p u η ∇um

η

≥q =q

η

m p(x) m(q–) u η ∇u η dx

≥q

η

p– p– + q – 

p–

m(q–) u η dx

dx – q

m(p–p–+q–) p– ∇u η dx – q

m(q–) u η dx.

(.)

Combining (.) and (.), we have p–

m(p–p–+q–) p– p–  d ∇u η dx umq+ dx + q mq +  dt η p– + q – 

m(q–) ≤ K umq+ dx + q u η dx.

η

(.)

We estimate the right-hand side of (.) by Hölder’s inequality, the embedding theorem and Young’s inequality with to deduce

umq+ dx + q

η

K

m(q–) u η dx

m(p– +q–) u η dx

≤ K

mq+ m(p– +q–)

mq+

– m(p– +q–)

||

– +q–)

m(p u η

+q

p–q– +q– dx

q–

– p– +q–

||

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m(p–p–+q–) p– ∇u η dx

≤C

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mq+ m(p– +q–)

m(p–p–+q–) p– ∇u η dx

+C

p–q– +q–

m(p– +q–) m(p–p–+q–) p– ∇u η dx + C(  )C mp– –m–

≤ 

p– +q– m(p–p–+q–) p– ∇u η dx + C(  )C p– .

+ 

(.)

Choosing  and  appropriately, we have from (.) and (.)

d dt

umq+

η (x, t) dx ≤ C ,

(.)

for any q > , where C depends on q, p– , m, and . Integrating (.) over [τ , τ + T] and using the T-periodicity of u η , we have q

p–

m(p–p–+q–) p– p– ∇u η dx dt p– + q –  QT

m(q–) umq+ dx dt + q u η dx dt. ≤ K

η QT

(.)

QT

Similarly to (.), we obtain

m(p–p–+q–) p– ∇u η dx dt ≤ C ,

(.)

QT

where C depends on q, p– , m, T and . By Poincaré’s inequality, we have

– +q–)

QT

um(p

η

dx dt ≤

m(p–p–+q–) p– ∇u η dx dt ≤ C .

(.)

QT

Recall our assumption that p– > , m > , and thus m(p– + q – ) > mq + . Consequently, considering (.), we obtain

QT

umq+

η (x, t) dx dt ≤ C ,

(.)

which implies that there exists a t ∈ (τ , τ + T) such that

umq+

η (x, t ) dx ≤ C .

(.)

From (.) and (.), we conclude

umq+

η (x, t) dx ≤ C + C (t – t ),

for any t ≥ t . In view of the T-periodicity of u η , (.) shows

umq+

η (x, τ + T) dx ≤ C + C T.

umq+

η (x, τ ) dx =

(.)

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We ﬁnally arrive at

sup t∈(τ ,τ +T)

umq+

η (x, t) dx ≤ C,

(.)

for any q > , where C depends on q, p– , m, T and . Step . Let

Ak (t) = x ∈ ; u η (x, t) > k ,

sup Ak (t),

μk =

t∈(τ ,τ +T)

where |Ak (t)| is the Lebesgue measure of the set Ak (t). Multiplying (.) by (u η – k)m + χ[t ,t ] (t) on both sides, where χ[t ,t ] (t) represents the characteristic function of the interval [t , t ], and integrating over QT , we have

 m+

t

d t dt

t

+ t

t

≤ K

(u η – k)m+ dx dt +

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇(u η – k)m dx dt

η

η +

t

u η (u η – k)m + dx dt.

Let Ik (t) := (u η – k)m+ dx. We assume that the absolutely continuous function Ik (t) at+ tains its maximum at ∈ [τ , τ + T]. Take t = – θ , t = and θ small enough so that t > τ . (In fact, this is always possible because of the periodicity of u η ; for example, if = τ , we take = τ + T, then > τ and t > τ .) Then we have Ik () ≥ Ik ( – θ ) and  θ

–θ

 ≤ K θ

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇(u η – k)m dx dt

η

η +

–θ

u η (u η – k)m + dx dt.

(.)

Letting θ → + yields

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇(u η – k)m dx

η

η +

≤ K

u η (u η – k)m + dx.

(.)

After a direct computation, we obtain an estimate for the left-hand side of (.) as follows:

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇(u η – k)m dx

η

η +

≥

=

m(u η – k)m– ∇(u η – k)+ p(x) dx +

∇(u η – k)m p(x) dx +

– ∇(u η – k)m p dx – Ak ().

≥ Ak ()

(.)

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Substituting (.) into (.), we have

– ∇(u η – k)m p dx ≤ K

Ak ()

u η (u η – k)m dx + μk .

(.)

Ak ()

We now deal with (.). On one hand, by the embedding theorem pr–

(u η – k)

mr

dx

≤S

p–

Ak ()

– ∇(u η – k)m p dx,

(.)

Ak ()

where S is the Sobolev embedding constant, and ⎧ ⎨

r

Np– , N–p– = p– (N+p– ) ⎩ , N

if p– < N, if p– ≥ N.

On the other hand, from (.), where we may ﬁx a special q, using Hölder’s inequality, we obtain

u η (u η – k)m dx K Ak ()

N+p– p–

≤ K

u η

p– N+p –

dx

Ak ()

N N+p –

dx

Ak ()

≤C

N+p–

(u η – k)m N

N+p–

(u η – k)m N

N N+p –

dx

Ak ()

Nr–N–p– ≤ C Ak () r(N+p– )

r

(u η – k)

mr

dx

.

(.)

Ak ()

Let Jk () =

Ak () (u η

– k)mr dx. Then (.), (.), and (.) imply –

Nr–N–p pr–   r(N+p– ) () ≤ Cμ J Jk () r + μk . k – k p S

(.)

Utilizing Young’s inequality with , we obtain from (.) –

Nr–N–p  r r r p– (N+p– ) p– p– Jk + Sr μk Jk ≤  p– Sr C p– μk Nr–N–p– p– (N+p– )

≤ Cμk

 p–

r p–

Jk + Cμk

–

Nr–N–p r – – – ≤ C Jk + C( )μk(p –)(N+p ) + Cμkp .

Upon choosing appropriately, one obtains –

r –Nr–N–p – – Jk () ≤ C μk(p –)(N+p ) + μkp .

(.)

For any h > k > , it is easy to see Jk () ≥ Ah ()(h – k)rm .

(.)

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The relationships (.) and (.) above imply that μh ≤

M h–k

rm

–

–

(N+p ) r + Nr–p (p– –)(N+p– ) p– + μk . μk

–

–

(N+p ) >  and Noticing that Nr–p (p– –)(N+p– ) thus u η L∞ (QT ) < R, where

r p–

(.)

> , by the iteration Lemma ., we obtain μR =  and

Nr–p– (N+p– )  r R = M – |QT | (p– –)(N+p– ) + |QT | p– – rm ,

with r Nr – N – p– , . = min (p– – )(N + p– ) p–

Theorem . Assume K ≥ , for a.e. (x, t) ∈ QT . Then there exists a positive constant R such that deg u – T η , u+ , BR ,  = , where u+ = max{u, }. Proof From Proposition ., we take K = aL∞ (QT ) , it implies that there exists a positive constant R >  independent of and η, such that u η = G η (, ρf (u+ η )), for any u η ∈ ∂BR , ρ ∈ [, ]. Hence the topological degree deg(u – G η (, ρf (u+ )), BR , ) is well deﬁned in BR . Thanks to the homotopy invariance property of the Leray-Schauder degree, we have deg u – G η , f u+ , BR ,  = deg u – G η (, ), BR ,  .

(.)

Using the fact that G η (, ) = , one has deg u – G η (, ), BR ,  = deg(I, BR , ) = . From (.) and (.), we get deg(u – T η (, u+ ), BR , ) = .

(.)

Using the standard method, similar to that in [] or [], one can prove the following. Proposition . Assume that a ∈ L∞ (QT ), K ∈ L∞ (QT ). If u η solves u = G η (σ , ρf (u+ ) + –σ ), for some σ ∈ [, ] and ρ ∈ [, ], then u η ≥  for any (x, t) ∈ QT . Moreover, if u η = , then u η >  in QT . In what follows, we prove a lower bound for the regularized problem. Proposition . Let μ be the ﬁrst eigenvalue of ⎧ ⎨–u = μu,

x ∈ ,

⎩u = ,

x ∈ ∂,

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and let e be the associated positive eigenfunction such that e L () = . Assume that p+ –    p– –  ae dx dt > μ ,  <

< and  < η < ( ) . If u η =  satisﬁes u η = G η (σ , f (u+ η ) +   QT T    – σ ) for some σ ∈ [, ], then u η L∞ (QT ) ≥ r , where  γp+   m– QT ae dx dt – μ T r = min , , m M γp (x) =

p(x) , p(x) – 

p– p+ – , γ , = min γ (x) = p p p– –  p+ –     + M = KL (QT ) + p – + Cp+ ,p(x) max |∇e | || p+ – – γp p γp+ = max γp (x) =

± × max aL (QT ) + ||T γp T

γp± – γp±

,

+

Cp+ ,p(x) is the embedding constant of Lp () into Lp(x) (), and || is the Lebesgue measure of the domain . Proof We argue by contradiction. If not, then for each σ ∈ [, ] and r ∈ (, r ), there exists a u η =  such that uεη = G η (σ , f (u+εη ) +  – σ ), with u η L∞ (QT ) ≤ r. For clarity, we divide the proof into four steps. Step . Note that, by Proposition ., u η >  in QT . Taking φ ∈ C∞ () and multiplying

p(x)–  ∂u η + η  ∇ σ um + u η – div ∇ σ um

η + u η

η ∂t

 = a – K(ξ , t)u η (ξ , t – τ ) dξ u η +  – σ

(.)

by

φ , u η

integrating over QT and using the T-periodicity of u η , we obtain

K(ξ , t)u η (ξ , t

a– QT



– τ ) dξ φ dx dt + QT

 φ +η div ∇ σ um

η + u η u η 

=– QT

( – σ )

p(x)– 

φ dx dt u η

∇ σ um dx dt

η + u η

:= (R).

(.) 

Step . Using ∇u η ∇( uφ η ) = |∇φ| – u η |∇( uφ η )| , we have φ dx dt u η QT 

p(x)– m ∇ σ u + u η  + η  σ mum– + ∇u η ∇ φ = dx dt

η

η u η QT

p(x)– m ∇ σ u + u η  + η  σ mum– + |∇φ| dx dt =

η

η

p(x)– m ∇ σ u + u η  + η  ∇ σ um + u η ∇

η

η

(R) =

QT

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 p(x)– m ∇ σ u + u η  + η  σ mum– + u ∇ φ dx dt

η

η

η u η QT p(x)– m ∇ σ u + u η  + η  σ mum– + |∇φ| dx dt.

η

η

≤ QT



 m– m– ) and  < <  , we have σ mum– Since r < r ≤ ( m

η + ≤ mu η + <

(R) ≤ QT p+ – 

≤

QT

=

QT

+

+ < . Hence

p(x)– m ∇ σ u + u η  + η  |∇φ| dx dt

η

p+ – 

 

p+ – 

η

m p– – ∇ σ u + u η p(x)– + η  |∇φ| dx dt

η m ∇ σ u + u η p(x)– |∇φ| dx dt

η

p– – 

|∇φ| dx dt.

(.)

QT

Thanks to the p(x)-Hölder’s inequality in variable exponent space, we have

m ∇ σ u + u η p(x)– |∇φ| dx

η

p(x)–   m γp (x) |∇φ| p(x) + ∇ σ u η + u η L () – – γp p L  ()   ≤ + – Cp+ ,p(x) |∇φ| p+ – γp p L  ()

≤

± m ∇ σ u + u η p(x) dx γp . × max

η

(.)

 γp±

Noting that

T



<  and using Hölder’s inequality, we have

m ∇ σ u + u η p(x) dx

η

 γp±

dt

≤T

– ±

γp

QT

m ∇ σ u + u η p(x) dx dt

η

 γp±

.

(.)

Integrating (.) over [, T] and noting (.), we get

QT

m ∇ σ u + u η p(x)– |∇φ| dx dt

η

≤

  + – Cp+ ,p(x) |∇φ| p+ – γp p L  ()

× max QT

m ∇ σ u + u η p(x) dx dt

η

 γp±

T

γp± – γp±

.

(.)

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Step . Multiplying (.) by σ um

η + u η , integrating over QT , noticing the T-periodicity 

 m– of u η and  < r < r ≤ ( m ) < , we deduce

QT

m ∇ σ u + u η p(x) dx dt

η

p(x)– m ∇ σ u + u η  + η  ∇ σ um + u η  dx dt

η

η

≤ QT

au η um

η + u η dx dt + ( – σ )

≤ QT

QT

um

η + u η dx dt

 ≤ u η m+ L∞ (QT ) + u η L∞ (QT ) aL (QT ) + ( – σ ) u η m L∞ (QT ) + u η L∞ (QT ) ||T ≤ rm+ + r aL (QT ) + rm + r ||T ≤ r aL (QT ) + ||T . Substituting this inequality into (.), we have

QT

m ∇ σ u + u η p(x)– |∇φ| dx dt

η

  + Cp+ ,p(x) |∇φ| p+ – – γp p L  ()

≤

γ ± –

γ± pγ ± × max r aL (QT ) + ||T p T p     γp– γp+  + ,p(x) |∇φ| p+ +  r C ≤ p γp– p– L  ()

± × max aL (QT ) + ||T γp T

γp± – γp±

.

(.)

Substituting (.) into (.) and noticing that  (R) ≤ 

p+ –

p+ – 

 –

+ –

 γp ≤ p

, we get

   + + – r γp Cp+ ,p(x) |∇φ| p+ – γp p L  ()

± × max aL (QT ) + ||T γp T

γp± – γp±

+

p+ – 

η

p– – 

|∇φ| dx dt.

(.)

QT

p+ –

Considering that  < η < (  ) p– – , from (.) and (.), we have

a–

QT

K(ξ , t)u η (ξ , t – τ ) dξ φ  dx dt

+ –

≤

|∇φ| dx dt + p QT

   + r γp Cp+ ,p(x) |∇φ| p+ + – – γp p L  ()

± × max aL (QT ) + ||T γp T

γp± – γp±

.

(.)

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Step . We claim

 +

QT

ae dx dt – μ T ≤ r γp M,

(.)

from which we will derive a contradiction. First, to show (.), let φ = e in (.). Using the fact that ∇e ∈ (C  ())N and noting e L () =  and |∇e | dx = μ , we get

QT

ae dx dt – μ T

≤

p+ –

   + + r γp Cp+ ,p(x) |∇e | p+ γp– p– L  () γ ± –

± p ± × max aL (QT ) + ||T γp T γp

T K(ξ , t)u η (ξ , t – τ ) dξ e dx dt + 

+ –

≤ p

  r + γp– p–

 γp+



Cp+ ,p(x) max |∇e | || p+

γ ± –

± p ± × max aL (QT ) + ||T γp T γp + KL (QT ) r     + + ≤ r γp p – + Cp+ ,p(x) max |∇e | || p+ – – γp p

± × max aL (QT ) + ||T γp T

γp± – γp±

+ KL (QT )

 +

= r γp M. Now the deﬁnition of r and (.) yield r ≤

QT

ae dx dt – μ T M

γp+

≤ r,

(.)

which is clearly a contradiction to the assumption that r ∈ (, r ). This completes the proof. Theorem . Let r be as given in Proposition .. Then deg(u – T η (, u+ ), Br , ) =  for all  < r < r . Proof In view of Proposition ., for any ﬁxed r ∈ (, r ), we have proved that u = G η (σ , f (u+ ) +  – σ ) for all u ∈ ∂Br , σ ∈ [, ]. So the Leray-Schauder topological degree deg(u – G η (σ , f (u+ ) +  – σ ), Br , ) is well deﬁned for all σ ∈ [, ]. Thanks to the homotopy invariance of the topological degree, we have deg u – G η , f u+ , Br ,  = deg u – G η , f u+ +  , Br ,  .

(.)

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Also, from Proposition ., we infer that u = G η (, f (u+ ) + ) admits no nontrivial solution in Br . Moreover, u η =  is not a solution of u = G η (, f (u+ ) + ). So deg(u – G η (, f (u+ ) + ), Br , ) = . Together with (.), we have deg(u – T η (, u+ ), Br , ) = .

4 Existence of nontrivial nonnegative solution to (1.1) Theorem . Assume K(x, t) ≥  for a.e. (x, t) ∈ QT and T QT ae dx dt > μ . Then problem (.) has a nontrivial nonnegative periodic solution. Proof We consider the regularized problem (.). By Theorem . and Theorem ., we conclude that there exist R and r, independent of and η, with R > r > , such that deg u – G η , f u+ , BR \Br ,  =  p+ –

for  < <  and  < η < (  ) p– – . Using the solvability of the Leray-Schauder degree, we conclude that the regularized problem (.) admits a nontrivial nonnegative solution u η in BR \Br . ,p(x) p– p(x) ()) with |∇um (QT ) and that a solution to We prove that um

η ∈ L (, T; W

η | ∈ L problem (.) is obtained as a limit of u η as , η → . We proceed in several steps. Step . In view of K(x, t) ≥ , choosing C = aL∞ (QT ) , we have

p(x)–  ∂u η + η  ∇ um + u η ≤ Cu η . – div ∇ um

η + u η

η ∂t

(.)

Multiplying (.) by um

η + u η , integrating over QT and noting the T-periodicity of u η and the boundedness of u η , we have

m p(x) ∇u dx dt

η

QT

≤ QT

p(x)– m ∇ u + u η  + η  ∇ um + u η  dx dt

η

η

≤C QT

 um+

η + u η dx dt ≤ M,

(.)

where M is a positive constant independent of and η. Moreover,

T 

– ∇um pp(x) dt

η L ()

=

[,T]∩{t:|∇um

η |Lp(x) () >}

m p– ∇u p(x)

+

≤

()

dt

m p– ∇u p(x)

()

η L

[,T]∩{t:|∇um

η |Lp(x) () ≤}

[,T]∩{t:|∇um

η |Lp(x) () >}

≤

QT

η L

dt

m p(x) ∇u dx dt + T

η

m p(x) ∇u dx dt + T ≤ M + T.

η

(.)

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–

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–

,p(x)

p p So um ()) and um

η ∈ L (, T; W

η is uniformly bounded in the space L (, T; ,p(x) m W ()). Thus, up to subsequence if necessary, we may assume that u η um ∈ – ,p(x) Lp (, T; W ()). In what follows, our main goal is to prove that u is a weak solution of problem (.). Step . The following relation is obvious:

QT

p(x)– m ∇ u + u η  + η  ∇ um + u η  dx dt

η

η

≥ QT

m ∇ u + u η p(x) dx dt.

η

(.)

From (.) and (.), we have

QT

m ∇ u + u η p(x) dx dt ≤ C.

η

(.)

Owing to the embedding results in the variable exponent space, one has m ∇ u + u η  ≤ C,p(x) ∇ um + u η p(x)

η

η L () L () ± m p ∇ u + u η p(x) dx ≤ C,p(x) max .

η

(.)

Integrating (.) over [, T] and using Hölder’s inequality, we have

T



∇ um + u η  dt

η L ()

≤ C,p(x) max QT

m ∇ u + u η p(x) dx dt

η

 p±

T

– ± p

.

(.)

From (.) and (.), there exists a positive constant C independent of and η, such that

QT

m ∇ u + u η  dx dt ≤ C.

η

(.)

In the following, we prove

QT

m p(x)– p(x) ∇ u + u η  + η  ∇ um + u η p(x)– dx dt ≤ C.

η

η

First, denote Kp (x) =

p(x) , p(x) – 

– Kp = min Kp (x),

+ Kp = max Kp (x),

(p(x) – ) , Kp (x) = p(x)

– Kp = min Kp (x),

+ Kp = max Kp (x),

(p(x) – ) , p(x) – 

– Kp = min Kp (x),

+ Kp = max Kp (x).

(x) = Kp

(.)

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A straightforward computation shows that

QT

m p(x)– p(x) ∇ u + u η  + η  ∇ um + u η p(x)– dx dt

η

η

≤ QT

p+ – m p(x) p– –   ∇ u + u η p(x)– + η  ∇ um + u η p(x)– dx dt

η

η

p+ – +  Kp

≤

QT

p+ – +  Kp

≤



+ Kp

≤ Mp QT

m p(x) ∇ u + u η p(x)– ∇ um + u η + ∇ um + u η p(x)– dx dt

η

η

η

QT

m p(x) ∇ u + u η p(x) + ∇ um + u η p(x)– dx dt

η

η

m ∇ u + u η p(x) dx dt +

η

QT

m p(x) ∇ u + u η p(x)– dx dt .

η

(.)

By the p(x)-Hölder’s inequality, we have

m p(x) ∇ u + u η p(x)– dx

η

p(x)   m (x) + ∇ u η + u η p(x)– LKp (x) () || Kp – – L () Kp Kp 

K+ –   p , || Kp ≤ + max || – – Kp Kp ≤

± m  K ∇ u η + u η dx p . × max

(.)

Integrating (.) over [, T], using the p(x)-Hölder’s inequality again, we get

QT

m p(x) ∇ u + u η p(x)– dx dt

η

≤

 

K+

+ – –   p , || Kp max T Kp , T Kp + max || – – Kp Kp

× max QT

m ∇ u + u η  dx dt

η

 ± Kp

.

(.)

Substituting (.), (.), and (.) into (.), we derive (.). Therefore, there exists a p(x)

H ∈ (L p(x)– (QT ))N such that p(x)– m ∇ u + u η  + η  ∇ um + u η H,

η

η

(.)

p(x)

weakly in (L p(x)– (QT ))N as , η → . ∂um Step . Using a method analogous to [], we get ∂t η L (QT ) ≤ C, where C is independent ,p(x) ,p(x) p– ()), and W () →compact of and η. Since um

η is uniformly bounded in L (, T; W m Lp(x) () → L (), by compactness theorem (Corollary  in []), it follows that um

η → u – in Lp (, T; Lp(x) ()). Thus, we have

∂ϕ + H∇ϕ – auϕ + uϕ K(ξ , t)u (ξ , t – τ ) dξ dx dt –u ∂t QT

=

(.)

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for any ϕ ∈ C  (QT ) satisfying ϕ(x, T) = ϕ(x, ) for x ∈ and ϕ(·, t)|∂ =  for t ∈ [, T] –

,p(x)

(and hence, by density, for any ϕ ∈ C(QT ) ∩ Lp (, T; W

()) with |∇ϕ| ∈ Lp(x) (QT ) and

T-periodicity). The continuity of u follows from similar Hölder estimates in []. Step . It remains to verify for any ϕ ∈ C  (QT ),

m p(x)– m ∇u ∇u ∇ϕ dx dt =

QT

(.)

H∇ϕ dx dt. QT

We consider matrix function (Y ) = (|Y | + η) (p(x) – )(|Y | + η) 

p(x)– 

p(x)– 

Y . Then (Y ) = (|Y | + η)

YY is a positive deﬁnite matrix. Choosing v ∈ L T

p–

p(x)– 

I+

,p(x) (, T; W ())

with |∇v| ∈ Lp(x) (QT ), by mean value theorem, there exists a matrix Y such that m ∇ u η + u η – (∇v), ∇ um

η + u η – ∇v m = (Y ) ∇ um

η + u η – ∇v , ∇ u η + u η – ∇v ≥ ,

(.)

which gives

≤ QT

p(x)–

m ∇ u + u η  + η  ∇ um + u η

η

η

p(x)– – |∇v| + η  ∇v ∇ um

η + u η – v dx dt

p(x)– m ∇ u + u η  + η  ∇ um + u η  dx dt =

η

η

QT

–

QT

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇v dx dt

η

η

–

|∇v| + η

QT

p(x)– 

∇v∇ um

η + u η – v dx dt.

(.)

Multiplying the equation

p(x)–  ∂u η + η  ∇ um + u η – div ∇ um

η + u η

η ∂t

 = a – K(ξ , t)u η (ξ , t – τ ) dξ u η

by um

η + u η , integrating over QT and using T-periodicity of u η , one has

QT

p(x)– m ∇ u + u η  + η  ∇ um + u η  dx dt

η

η

= QT

 a – K(ξ , t)u η (ξ , t – τ ) dξ um+

η + u η dx dt.

(.)

Li and Gao Boundary Value Problems 2014, 2014:77 http://www.boundaryvalueproblems.com/content/2014/1/77

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Thus, (.) and (.) imply

QT

p(x)– m ∇ u + u η  + η  ∇ um + u η ∇v dx dt

η

η

+

|∇v| + η

p(x)– 

QT

≤ QT

∇v∇ um

η + u η – v dx dt

 a – K(ξ , t)u η (ξ , t – τ ) dξ um+

η + u η dx dt.

Letting , η → , by (.), we have

|∇v|p(x)– ∇v∇ um – v dx dt

H∇v dx dt + QT

QT

a – K(ξ , t)u (ξ , t – τ ) dξ um+ dx dt.

≤ QT

(.)

Let ϕ = um in (.) and, by the T-periodicity of u, we get

m

H∇u dx dt = QT

K(ξ , t)u (ξ , t – τ ) dξ um+ dx dt.



a– QT

(.)

Combining (.) with (.), we obtain

≤

H – |∇v|p(x)– ∇v ∇ um – v dx dt.

(.)

QT

Taking v = um – λϕ, with λ >  and ϕ ∈ C  (QT ), we get

≤

p(x)– m ∇ u – λϕ ∇ϕ dx dt. H – ∇ um – λϕ

(.)

QT

Letting λ →  in (.) yields

≤

p(x)– m ∇u ∇ϕ dx dt. H – ∇um

(.)

QT

On the other hand, if we take v = um + λϕ, with λ >  and ϕ ∈ C  (QT ) and let λ → , we get

≥

p(x)– m ∇u ∇ϕ dx dt. H – ∇um

(.)

QT

From (.) and (.) we have (.). This completes the proof of Theorem ..

Appendix In this appendix, we prove Lemma . for the reader’s convenience. Proof of Lemma . Deﬁne the following sequence: k s = k + d –

d , s

s = , , , . . . ,

Li and Gao Boundary Value Problems 2014, 2014:77 http://www.boundaryvalueproblems.com/content/2014/1/77

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where d is to be determined later. Then (.) implies the recursive relationship ϕ(ks+ ) ≤

Mα (s+)α β ϕ (ks ) + ϕ γ (ks ) , α d

s = , , , . . . .

(.)

By induction, one has ϕ(ks ) ≤

ϕ(k ) , rs

s = , , , . . . ,

(.)

where r >  is to be chosen. In fact, if (.) is right, then Mα (s+)α ϕ β (k ) ϕ γ (k ) + sγ ϕ(ks+ ) ≤ dα rsβ r Mα (s+)α ϕ β (k ) + ϕ γ (k ) dα rsδ α (s+)α β– ϕ (k ) + ϕ γ – (k ) ϕ(k ) M  = s+ . r dα r[s(δ–)–] ≤

α

α

αδ

We choose r =  δ– and M dαδ– (ϕ β– (k ) + ϕ γ – (k )) ≤ . Consequently, these choices guar) antee ϕ(ks+ ) ≤ ϕ(k . From (.) and ϕ(t) is nonnegative and nonincreasing, we have ders+ duced the result.

Competing interests The authors declare that they have no competing interests. Authors’ contributions All authors contributed equally to the manuscript and approved the ﬁnal version. Acknowledgements The authors would like to thank the anonymous referees for their valuable comments on and suggestions regarding the original manuscript. This work was supported by National Science Foundation of China (11271154), by Key Lab of Symbolic Computation and Knowledge Engineering of Ministry of Education and by the 985 program of Jilin University. Received: 19 October 2013 Accepted: 20 March 2014 Published: 02 Apr 2014 References 1. R˚užiˇcka, M: Electrorheological Fluids: Modeling and Mathematical Theory. Lecture Notes in Mathematics, vol. 1748. Springer, Berlin (2000) 2. DiBenedetto, E: Degenerate Parabolic Equations. Universitext. Springer, New York (1993) 3. Fragnelli, G, Nistri, P, Papini, D: Non-trivial non-negative periodic solutions of a system of doubly degenerate parabolic equations with nonlocal terms. Discrete Contin. Dyn. Syst. 31, 35-64 (2011) 4. Ladyženskaja, OA, Solonnikov, VA, Ural’ceva, NN: Linear and Quasilinear Equations of Parabolic Type. Translations of Mathematical Monographs, vol. 23. Am. Math. Soc., Providence (1968) Translated from the Russian by S. Smith 5. Sun, J, Yin, J, Wang, Y: Asymptotic bounds of solutions for a periodic doubly degenerate parabolic equation. Nonlinear Anal. 74, 2415-2424 (2011) 6. Tsutsumi, M: On solutions of some doubly nonlinear degenerate parabolic equations with absorption. J. Math. Anal. Appl. 132, 187-212 (1988) 7. Wang, J, Gao, W: Existence of nontrivial nonnegative periodic solutions for a class of doubly degenerate parabolic equation with nonlocal terms. J. Math. Anal. Appl. 331, 481-498 (2007) 8. Allegretto, W, Nistri, P: Existence and optimal control for periodic parabolic equations with nonlocal terms. IMA J. Math. Control Inf. 16, 43-58 (1999) 9. Huang, R, Wang, Y, Ke, Y: Existence of non-trivial nonnegative periodic solutions for a class of degenerate parabolic equations with nonlocal terms. Discrete Contin. Dyn. Syst., Ser. B 5, 1005-1014 (2005) 10. Nakao, M: Periodic solutions of some nonlinear degenerate parabolic equations. J. Math. Anal. Appl. 104, 554-567 (1984) 11. Pang, PYH, Wang, Y, Yin, J: Periodic solutions for a class of reaction-diﬀusion equations with p-Laplacian. Nonlinear Anal., Real World Appl. 11, 323-331 (2010)

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12. Diening, L, Harjulehto, P, Hästö, P, R˚užiˇcka, M: Lebesgue and Sobolev Spaces with Variable Exponents. Lecture Notes in Mathematics, vol. 2017. Springer, Heidelberg (2011) 13. Fragnelli, G: Positive periodic solutions for a system of anisotropic parabolic equations. J. Math. Anal. Appl. 367, 204-228 (2010) 14. Guo, B, Gao, W: Study of weak solutions for parabolic equations with nonstandard growth conditions. J. Math. Anal. Appl. 374, 374-384 (2011) 15. Wu, Z, Yin, J, Wang, C: Elliptic & Parabolic Equations. World Scientiﬁc, Hackensack (2006) 16. Simon, J: Compact sets in the space Lp (0, T; B). Ann. Mat. Pura Appl. (4) 146, 65-96 (1987) 17. Porzio, MM, Vespri, V: Hölder estimates for local solutions of some doubly nonlinear degenerate parabolic equations. J. Diﬀer. Equ. 103, 146-178 (1993)

10.1186/1687-2770-2014-77 Cite this article as: Li and Gao: Existence of nonnegative nontrivial periodic solutions to a doubly degenerate parabolic equation with variable exponent. Boundary Value Problems 2014, 2014:77

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Existence of nonnegative nontrivial periodic solutions to a doubly degenerate parabolic equation with variable exponent

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