Local existence of strong solutions to the k-ε model equations for turbulent flows

In this paper, we are concerned with the local existence of strong solutions to the k-ε model equations for turbulent flows in a bounded domain \(\Omega\subset\mathbb{R}^{3}\). We prove the existence of unique local strong solutions under the assumption that the turbulent kinetic energy and the initial density both have lower bounds away from zero.

Turbulence is a natural phenomenon, which occurs inevitably when the Reynolds number of flows becomes high enough (10⁶ or more). In this paper, we consider the k-ε model equations [1, 2] for turbulent flows in a bounded domain Ω⊂ \(\mathbb{R}^{3}\) with smooth boundary,

with

where \(\delta_{ij}=0\) if \(i\neq j\), \(\delta_{ij}=1\) if \(i=j\), and μ, \(\mu_{t}\), \(\mu_{e}\), \(C_{1}\), and \(C_{2}\) are five positive constants satisfying \(\mu+\mu_{t}=\mu_{e}\), and n⃗ is the unit outward normal to ∂Ω.

Equations (1.1)-(1.10) are derived from combining the effect of turbulence on the time-averaged Navier-Stokes equations with the k-ε model equations. The unknown functions ρ, u, h, k, and ε denote the density, velocity, total enthalpy, turbulent kinetic energy, and the rate of viscous dissipation of turbulent flows, respectively. The expression of the pressure p has been simplified here, which indeed has no bad effect on our study.

In partial differential equations, the k-ε equations belong to the compressible ones. In this regard, we will refer to the classical compressible Navier-Stokes equations and compressible MHD equations, which are also research mainstreams, to carry out our study.

For compressible isentropic Navier-Stokes equations, the first question provoking our interest is the existence of the weak solutions. Lions [3, 4] proved the global existence of weak solutions under the condition that \(\gamma >\frac{3n}{n+2}\), where γ is the same as in (1.10) and n is the dimension of space. Later, Feireisl [5, 6] improved his result to \(\gamma>\frac{n}{2}\). The condition satisfied by γ is to prove the existence of renormalized solutions, which were introduced by DiPerna and Lions [7]. When the initial data are general small perturbations of non-vacuum resting state, Hoff [8] proved the global existence of weak solutions provided \(\gamma>1\). The existence of strong solutions is another problem provoking our interest in the research of Navier-Stokes equations. It has been proved that the density will be away from vacuum at least in a small time interval provided the initial density is positive. If the initial data have better regularity, the compressible isentropic Navier-Stokes equations will admit a unique local strong solution under various boundary conditions [9–12]. However, when the initial vacuum is allowed, it was shown recently in [9] that the isentropic one will have a local strong solution in the case that some compatibility conditions are satisfied initially. Choe and Kim [13] obtained the unique local strong solutions for full compressible polytropic Navier-Stokes equations under a similar condition in [9]. In [13], the technique the authors used is mainly the standard iteration argument and the key point of their success is the estimate for the \(L^{2}\) norm of the gradient of the pressure. In the process of studying the condition of a local solution becoming a global one, Xin [14] proved that the smooth solutions will blow up in finite time when an initial vacuum is allowed.

As for compressible MHD equations, the research directions, which mainly contain first the existence of weak and strong solutions and second the condition of weak solutions becoming a strong or even classical one and the local becoming a global one, are similar to that of Navier-Stokes equations. For example, Hu and Wang [15–17] obtained the local existence of weak solutions to the compressible isentropic MHD equations. Rozanova [18] proved the local existence of classical solutions to the compressible barotropic MHD equations provided both the mass and energy are finite. Fan and Yu in [19] proved the existence and uniqueness of strong solutions to the full compressible MHD equations. The method Fan and Yu [19] used is similar to that in [13], for example, they are both dependent on the standard iteration argument and the estimate for the \(L^{2}\) norm of the gradient of the pressure.

In this paper, we consider the existence of strong solutions to the k-ε model equations (1.1)-(1.10) in a bounded domain \(\Omega\subset\mathbb{R}^{3}\). Our method is similar to that in [19] and [13]. However, in the process of applying the method to the k-ε model equations, we find that the regularity of the solutions should be higher, which is induced by the higher nonlinearity in the compressible Navier-Stokes equations and compressible MHD equations than that in [19] and [13]. In fact, when we make the difference of the nth and the \((n+1)\)th cases of equation (2.4) and integrating the result, we inevitably arrive at the term \(\int\partial_{j}\overline{\rho}^{n+1}\partial_{j}\rho^{n+1}\cdot \overline{h}^{n+1}\). Therefore, we have to use integration by parts, which leads to two terms as \(\int\overline{\rho}^{n+1}\partial _{j}\partial_{j}{\rho}^{n+1}\cdot\overline{h}^{n+1}\) and \(\int\overline{\rho}^{n+1}\partial_{j}{\rho}^{n+1}\cdot \partial_{j}\overline{h}^{n+1}\). Then, by the Hölder and Young inequalities, it turns out that \(\Vert \nabla^{2}\rho^{n+1}\Vert _{L^{3}}\) and \(\Vert \nabla\rho^{n+1}\Vert _{L^{\infty}}\) should be bounded. Thus, we need \(\Vert \rho \Vert _{H^{3}}\) to be bounded for an a priori estimate. Therefore, from the mass equation enough regularity of the velocity field should be imposed. Moreover, due to the strong-coupling property of the k-ε equations, we need a corresponding high regularity of the unknown functions k and ε.

Stated simply, the high nonlinearity of the k-ε equations leads to the necessity of high regularity of some unknown functions and thus leads to much difficulties for the a priori estimates. Besides, physically, when the turbulent kinetic energy k vanish, the turbulence will disappear and the k-ε model equations will degenerate into the Navier-Stokes equation. Therefore, without loss of generality, we assume throughout this paper that the turbulent kinetic energy k has a positive lower bound away from zero, namely, \(0< m< k\) with m a constant.

To conclude this introduction, we give the outline of the rest of this paper: In Section 2, we consider a linearized problem of the k-ε equations and derive some local-in-time estimates for the solutions of the linearized problem. In Section 3, we prove the existence theorem of the local strong solution of the original nonlinear problem.

Using the density equation (1.1), we could change (1.1)-(1.10) into the following equivalent form:

Then we consider the following linearized problem of (2.1):

with

where v, π, and θ are known quantities on \((0,T_{1})\times\Omega\) with \(T_{1}>0\).

Here we also impose the following regularity conditions on the initial data:

For the known quantities v, π, θ, we assume that \(v(0)=u_{0}\), \(\pi(0)=k_{0}\), \(\theta(0)=\varepsilon_{0}\), and

for some fixed constants \(c_{i}\) satisfying \(1< c_{0}< c_{i}\) (\(i=1,2,\ldots,6\)) and some time \(T_{2}>0\). Here

For simplicity, we set another small time T as \(T =\min\{ c_{0}^{-6\gamma-16}c_{1}^{-10}c_{2}^{-8}c_{3}^{-8}c_{4}^{-2} c_{5}^{-2}c_{6}^{-4} , T_{1} , T_{2}\}\) and all of the T in Section 2 are defined as this.

Remark 2.1

Here it should be emphasized that throughout this paper, C denotes a generic positive constant which is only dependent on m, γ, and \(\vert \Omega \vert \), but independent of \(c_{i}\) (\(i=0,1,2,\ldots,6\)).

Remark 2.2

From the physical viewpoint, we assume that the turbulent kinetic energy k has a positive lower bound away from zero, namely, \(0< m< k\) with m a constant. We do not know whether \(0< m< k\) holds afterwards if the initial turbulent kinetic energy \(k_{0}>m\).

In this section we aim to prove the following local existence theorem of the linearized system (2.2)-(2.6).

Theorem 2.1

There exists a unique strong solution \((\rho,u,h,k,\varepsilon)\) to the linearized problem (2.2)-(2.8) and (2.9) in \([0,T]\) satisfying the estimates (2.99) and (2.100) as well as the regularity

In the following part, we decompose the proof of Theorem 2.1 into some lemmas.

Lemma 2.1

There exists a unique strong solution ρ to the linear transport problem (2.2) and (2.9) such that

for \(0\leq t\leq T\).

Proof

First, applying the particle trajectory method to the equation (2.3), we easily deduce

and thus

Second, by simple calculation, we have

applying the Gronwall and Hölder’s inequalities, one gets

for \(0\leq t\leq T\).

Next, from the equation (2.2), one obtains

for \(0\leq t\leq T\).

Thus, we complete the proof of Lemma 2.1. □

Next, we estimate the velocity field u.

Lemma 2.2

There exists a unique strong solution u to the initial boundary value problem (2.3) and (2.9) such that

for \(0\leq t\leq T\).

Proof

We only need to prove the estimates. Differentiating the equation (2.3) with respect to t, then multiplying both sides of the result by \(u_{t}\) and integrating over Ω, we derive that

where we have used the equation (2.2) and integration by parts. We will estimate \(I_{i}\) (\(i=1,2,\ldots,5\)) item by item.

First, because ρ has a lower bound away from zero, we easily deduce \(\Vert u_{t}\Vert _{L^{2}}\leq C\Vert \sqrt{\rho}u_{t}\Vert _{L^{2}}\). Therefore, using the Hölder, Sobolev, and Young inequalities and (2.10), we have

where \(\eta>0\) is a small number to be determined later.

Next, to evaluate \(\Vert \nabla u\Vert _{L^{3}}^{2}\) in (2.17), we can first the Sobolev interpolation inequality to get

Then applying the standard elliptic regularity result to the equation (2.3) and using (2.18), we have

thus the Young inequality and (2.10) yield

Combining (2.17), (2.18), and (2.19), and using the Young inequality, we get

By integration by parts, we have

On the other hand, we easily have

and

Combining (2.14)-(2.16) and (2.20)-(2.24), we get

setting \(\eta=\frac{1}{c_{1}}\) and using the Gronwall inequality, we derive

for \(0\leq t\leq T\), where we have used the fact that \(\lim _{t\rightarrow0}(\Vert \sqrt{\rho}u_{t}\Vert _{L^{2}}^{2}+\Vert u\Vert _{H^{1}}^{2})\leq Cc_{0}^{5+2\gamma}\).

Next, by (2.19) and (2.26), we deduce

which implies (2.12) by (2.26).

Next, we will estimate \(\int_{0}^{t}\Vert u\Vert _{H^{4}}^{2}\,\mathrm{d}t\). By the standard elliptic regularity result of the equation (2.3), we have

By simple calculation, the first term of the right-hand side of (2.28) can be controlled as

In order to estimate \(\Vert \nabla^{2}u_{t}\Vert _{L^{2}}\), differentiating the equation (2.3) with respect to t yields

applying the standard elliptic regularity result to (2.30) and using (2.26), one obtains

therefore, the key point is to estimate \(\Vert \rho u_{tt}\Vert _{L^{2}}\). Because we have the fact \(\Vert \rho u_{tt}\Vert _{L^{2}}\leq C\Vert \sqrt{\rho} u_{tt}\Vert _{L^{2}}\), we could first estimate \(\Vert \sqrt{\rho} u_{tt}\Vert _{L^{2}}\) as follows.

Multiplying both sides of (2.30) by \(u_{tt}\) and integrating the result over Ω yield

Using the Hölder, Sobolev, and Young inequalities and (2.10) and (2.26), we get

inserting (2.33)-(2.38) to (2.32), then integrating the result over \((0,t)\), we derive

where we have used the equation (2.3) to get \(\lim_{t\rightarrow 0}\Vert \nabla u_{t}(t)\Vert _{L^{2}}^{2}\leq Cc_{0}^{2\gamma+4}\).

So, combining (2.29), (2.31), and (2.39), we obtain

In the following, we shall estimate the rest terms of the inequality (2.28).

For the second term of the inequality (2.28), direct calculation yields

therefore, we have to evaluate \(\Vert u\Vert _{H^{3}}\). In fact, applying the standard elliptic regularity result to the equation (2.3), we obtain

we could estimate the right-hand side of (2.42) item by item.

First, from (2.26), we have \(\Vert u_{t}\Vert _{L^{2}}\leq Cc_{0}^{\frac{5}{2}+\gamma}\), thus

Second, using the Sobolev interpolation inequality and the Young inequality, we get

Third, due to (2.11), we easily derive

Last, by simple calculation, one gets

Combining (2.39) and (2.42)-(2.46), we deduce

Next, by simple calculation, the third and fourth terms on the right-hand side of (2.28) can be estimated as

Combining (2.26), (2.28), (2.40), (2.41), and (2.47)-(2.48), one deduces

for \(0\leq t\leq T\).

Thus, we complete the proof of Lemma 2.2. □

In the following part, we estimate the turbulent kinetic energy k.

Lemma 2.3

There exists a unique strong solution k to the initial boundary value problem (2.5) and (2.9) such that

for \(0\leq t\leq T\).

Proof

We only need to prove the estimates. Differentiating the equation (2.5) with respect to t, then multiplying both sides of the resulting equation by \(k_{t}\) and integrating over Ω, we get

we could evaluate \(K_{i}\) (\(i=1,\ldots,6\)) as follows.

First, using a similar method to deriving (2.15), (2.20), (2.16), respectively, one has

Next, differentiating \(G^{\prime}\) with respect to t and inserting the result thus obtained into \(K_{4}\) yield

Last, direct calculation leads to

On the other hand, we easily get

Combining (2.52)-(2.60), we obtain

setting \(\eta=c_{1}^{-1}\) and using the Gronwall inequality, we deduce

for \(0\leq t\leq T\), where we have used the fact that \(\lim _{t\rightarrow0}(\Vert \sqrt{\rho}k_{t}\Vert _{L^{2}}^{2}+\Vert k\Vert _{H^{1}}^{2})\leq Cc_{0}^{5}\).

Then, by the standard elliptic regularity result of the equation (2.5) and using (2.62), we have

and

To evaluate \(\int_{0}^{t}\Vert k\Vert _{H^{3}}^{2}\,\mathrm{d}t\), we will estimate the right-hand side of (2.64) item by item.

In fact, we derive by using (2.62) and (2.63) that

and

Therefore, inserting (2.65)-(2.68) to (2.64) and integrating the result thus obtained over \((0,t)\), one gets

for \(0\leq t\leq T\).

Combining (2.62), (2.63), and (2.69), we complete the proof of Lemma 2.3. □

In the next part, we estimate the viscous dissipation rates of the turbulent flows ε.

Lemma 2.4

There exists a unique strong solution ε to the initial boundary value problem (2.6) and (2.9) such that

for \(0\leq t\leq T\).

Proof

We only need to prove the estimates. Differentiating the equation (2.6) with respect to t, then multiplying both sides of the result by \(\varepsilon_{t}\) and integrating over Ω, one obtains

We could evaluate \(E_{4}\) and \(E_{5}\) in the first place. Because π has an upper and a lower bound away from zero, direct calculation yields

and

Next, using an argument similar to that used in deriving (2.53), (2.54), (2.55), (2.60), and (2.59), respectively, one gets

and finally

Combining (2.72)-(2.79), one obtains

setting \(\eta=c_{1}^{-1}\) and using the Gronwall inequality, one obtains

for \(0\leq t\leq T\), where we have used the fact that \(\lim _{t\rightarrow0}(\Vert \sqrt{\rho}\varepsilon_{t}\Vert _{L^{2}}^{2}+\Vert \varepsilon \Vert _{H^{1}}^{2})\leq Cc_{0}^{5}\).

Next, applying the standard elliptic regularity result to the equation (2.6) and using (2.81), we have

therefore, by the Young inequality and (2.81), one deduces

Thus, we complete the proof of Lemma 2.4. □

Finally, we estimate the total enthalpy h.

Lemma 2.5

There exists a unique strong solution h to the initial boundary value problem (2.4) and (2.9) such that

for \(0\leq t\leq T\).

Proof

We only need to prove the estimates. Differentiating equation (2.4) with respect to t, multiplying both sides of the result equation by \(h_{t}\) and integrating over Ω, one obtains

First of all, using similar methods of deriving the estimates (2.15), (2.20), and (2.16), respectively, one has

Second, differentiating the equation (2.2) with respect to t yields

Therefore, by direct calculation and using (2.89), we derive

Third, simple calculation and (2.26) lead to

Next, by direct calculation, we know that \(\nabla p_{t}= \gamma(\gamma -1)\rho^{\gamma-2}\rho_{t}\nabla\rho +\gamma\rho^{\gamma-1}\nabla\rho_{t}\). Therefore,

Last, simple calculation yields \(\vert S_{kt}^{\prime} \vert \leq C\vert \nabla v\vert \vert \nabla v_{t}\vert +C\rho^{\gamma-1}\vert \rho_{t}\vert \vert \nabla\rho \vert ^{2} +C\rho^{\gamma-1}\vert \nabla\rho_{t}\vert \vert \nabla\rho \vert \), thus

Furthermore, we easily have

and

Consequently, combining (2.85)-(2.95), one deduces

setting \(\eta=c_{1}^{-1}\) and using the Gronwall inequality, we get

for \(0\leq t \leq T\), where we have used the fact that \(\lim _{t\rightarrow0}(\Vert \sqrt{\rho}h_{t}\Vert _{L^{2}}^{2}+\Vert h\Vert _{H^{1}}^{2})\leq Cc_{0}^{5}\).

Next, using (2.97) and the standard elliptic regularity result of the equation (2.4), one obtains

then the Young inequality and (2.97) yield

Thus, we have finished the proof of Lemma 2.5. □

Next, let us define \(c_{i}\) (\(i=1,\ldots,6\)) as follows:

then we conclude from Lemma 2.1 to Lemma 2.5 that

and

for \(0\leq t\leq T\).

Using a standard proof as that in [13], we complete the proof of Theorem 2.1.  □

Theorem 3.1

There exist a small time \(T^{*}>0\) and a unique strong solution \((\rho ,u,h,k,\varepsilon) \) to the initial boundary value problem (1.1)-(1.10) such that

Proof

Our proof will be based on the iteration argument and on the results in the last section (especially Theorem 2.1).

First, using the regularity effect of the classical heat equation, we can construct functions (\(u^{0}=u^{0}(x,t)\), \(k^{0}=k^{0}(x,t)\), \(\varepsilon ^{0}=\varepsilon^{0}(x,t)\)) satisfying \((u^{0}(x,0), k^{0}(x,0), \varepsilon^{0}(x,0)) =(u_{0}(x), k_{0}(x), \varepsilon_{0}(x))\) and

Therefore it follows from Theorem 2.1 that there exists a unique strong solution \((\rho^{1},u^{1}, h^{1},k^{1},\varepsilon^{1})\) to the linearized problem (2.2)-(2.6) with v, π, θ replaced by \(u^{0}\), \(k^{0}\), \(\varepsilon^{0}\), respectively, which satisfies the regularity estimates (2.99) and (2.100). Similarly, we construct approximate solutions \((\rho^{n},u^{n},h^{n},k^{n},\varepsilon^{n})\), inductively, as follows: assuming that \(u^{n-1}\), \(k^{n-1}\), \(\varepsilon^{n-1}\) have been defined for \(n\geq1\), let \((\rho^{n},u^{n},h^{n},k^{n},\varepsilon^{n})\) be the unique solution to the linearized problem (2.2)-(2.6) with v, π, θ replaced by \(u^{n-1}\), \(k^{n-1}\), \(\varepsilon^{n-1}\), respectively. Then it follows from Theorem 2.1 that there exists a constant \(\widetilde{C}>1\) such that

for all \(n\geq1\). Throughout the proof, we denote by C̃ a generic constant depending only on m, M, γ, \(|\Omega| \), and \(c_{0}\), but independent of n. Next, we will show that the full sequence \((\rho ^{n},u^{n},h^{n},k^{n},\varepsilon^{n})\) converges to a solution to the original nonlinear problem (1.1)-(1.10) in a strong sense.

Define \(\overline{\rho}^{n+1}=\rho^{n+1}-\rho^{n}\), \(\overline {u}^{n+1}=u^{n+1}-u^{n}\), \(\overline{h}^{n+1}=h^{n+1}-h^{n}\), \(\overline {k}^{n+1}=k^{n+1}-k^{n}\), \(\overline{\varepsilon}^{n+1}=\varepsilon ^{n+1}-\varepsilon^{n}\), \(\overline{p}^{n+1}=p^{n+1}-p^{n}=(\rho^{n+1})^{\gamma}-(\rho ^{n})^{\gamma}\).

Then, by equations (2.2)-(2.6), we deduce that (\(\overline{\rho}^{n+1}\), \(\overline{u}^{n+1}\), \(\overline{h}^{n+1}\), \(\overline{k}^{n+1}\), \(\overline{\varepsilon }^{n+1}\), \(\overline{p}^{n+1}\)) satisfy the following equations:

where

To evaluate \(\Vert \overline{\rho}^{n+1}\Vert _{L^{2}}\), multiplying both sides of the equation (3.3) by \(\overline{\rho}^{n+1}\) and integrating the result over Ω, we get

Applying integration by parts to the second term of the second equality of (3.10) and using the Hölder, Sobolev, and Young inequalities yield

where (3.2) has been used and \(0<\eta<1\) is a small constant to be determined later.

Next, multiplying both sides of (3.4) by \(\overline{u}^{n+1}\) and integrating the result thus derived over Ω, one obtains

Using the Hölder, Sobolev, and Young inequalities and (3.2), we estimate \(L_{1}\), \(L_{2}\), and \(L_{3}\), respectively, as follows:

Then one deduces by integration by parts that

and

Inserting (3.13)-(3.17) to (3.12) and using inequality \(\Vert \overline{u}^{n+1}\Vert _{L^{2}}\leq\widetilde{C}\Vert \sqrt{\rho ^{n+1}}\overline{u}^{n+1}\Vert _{L^{2}}\), one has

Then, multiplying both sides of (3.5) by \(\overline{h}^{n+1}\) and integrating the result thus got over Ω, one obtains

First, using similar methods of deriving (3.13), (3.14), and (3.15), respectively, one easily obtains

Second, simple calculation leads to

By the differential mean value theorem, the first integral of (3.23) can be controlled as

By the equation (3.3), the second integral on the right-hand side of (3.24) can be estimated as

Then the second integral on the right-hand side of (3.23) can be controlled as

Next, applying integration by parts to the third integral on the right-hand side of (3.23), we easily get

Consequently, combining (3.23)-(3.27) and using the Hölder, Sobolev, and Young inequalities and (3.2), one obtains

Finally, we evaluate \(M_{5}\). Direct calculation yields

Then, applying a similar method to deriving (3.28), one deduces

Consequently, inserting (3.20)-(3.22), (3.28), and (3.30) into (3.19), one gets

For the turbulent kinetic energy k, using a similar method of deriving (3.19), one easily deduces from equation (3.6) that

We first evaluate \(N_{4}\). Using the inserting items technique, one easily gets

Using the Hölder, Sobolev, and Young inequalities and (3.2), we have

Second, we estimate \(N_{5}\). Using a similar method to deriving (3.33) and (3.34), we have

Next, using a similar method to deriving the estimates of (3.13), (3.14), and (3.15), respectively, one easily gets

Consequently, inserting (3.34)-(3.38) to (3.32), one deduces

Next, multiplying both sides of (3.7) by \(\overline {\varepsilon}^{n+1}\) and integrating the result over Ω, one gets

Using an argument similar to that used in deriving (3.13), (3.14), and (3.15), respectively, we obtain

Next, direct calculation leads to

Finally, using a similar method of deriving the estimate of \(Q_{4}\), one deduces

Consequently, inserting (3.41)-(3.45) to (3.40), one derives

In the end, combining (3.11), (3.18), (3.31), (3.39), and (3.46), and setting \(\varphi^{n+1}(t)=\Vert \overline{\rho}^{n+1}\Vert _{L^{2}}^{2} +\Vert \sqrt{\rho^{n+1}}\overline{u}^{n+1}\Vert _{L^{2}}^{2} +\Vert \sqrt{\rho^{n+1}}\overline{h}^{n+1}\Vert _{L^{2}}^{2} +\Vert \sqrt{\rho^{n+1}}\overline{k}^{n+1}\Vert _{L^{2}}^{2} +\Vert \sqrt{\rho^{n+1}}\overline{\varepsilon}^{n+1}\Vert _{L^{2}}^{2}\), we get

Setting \(I_{\eta}^{n}(t)=\widetilde{C}(1+\eta^{-1}+\Vert u_{t}^{n}\Vert _{L^{3}}^{2} +\Vert h_{t}^{n}\Vert _{L^{3}}^{2} +\Vert k_{t}^{n}\Vert _{L^{3}}^{2} +\Vert \varepsilon_{t}^{n}\Vert _{L^{3}}^{2})\) and applying the Gronwall inequality to (3.47) yield

where it should be noted that \(\varphi^{n+1}(0)=0\).

Since

setting \(\widetilde{T}\leq\eta<1\), we have

for \(t\leq\widetilde{T}\).

By (3.48)-(3.50), integrating (3.47) from \([0,t]\), one derives

for \(T^{*}:=\min\{T, \widetilde{T}\}\).

Therefore, we have

Thus, choosing η such that \(C\eta\exp (\widetilde{C})\leq \frac{1}{2}\), one deduces

Therefore, we conclude that the full sequence \((\rho ^{n},u^{n},h^{n},k^{n},\varepsilon^{n})\) converges to a limit \((\rho,u,h, k,\varepsilon)\) in the following strong sense: \(\rho^{n}\rightarrow\rho\) in \(L^{\infty}(0,T;L^{2}(\Omega))\); \((u^{n},h^{n},k^{n},\varepsilon^{n})\rightarrow(u,h,k,\varepsilon)\) in \(L^{2}(0,T;H^{1}(\Omega))\). It is easy to prove that the limit \((\rho,u,h,k,\varepsilon)\) is a weak solution to the original nonlinear problem. Furthermore, it follows from (3.2) that \((\rho,u,h,k,\varepsilon)\) satisfies the following regularity estimates:

This proves the existence of a strong solution. Then we can easily prove the time continuity of the solution \((\rho, u, h, k, \varepsilon)\) by adapting the arguments in [9, 13]. Finally, we prove the uniqueness. In fact, assume \((\rho_{1}, u_{1}, h_{1}, k_{1}, \varepsilon_{1})\) and \((\rho_{2}, u_{2}, h_{2}, k_{2}, \varepsilon_{2})\) be two strong solutions to the problem (1.1)-(1.10) with the regularity (3.1). Let \((\overline{\rho}, \overline{u}, \overline{h}, \overline{k}, \overline{\varepsilon}) =(\rho_{1}-\rho_{2}, u_{1}-u_{2}, h_{1}-h_{2}, k_{1}-k_{2}, \varepsilon_{1}-\varepsilon_{2})\). Then following the same argument as in the derivations of (3.11), (3.18), (3.31), (3.39), and (3.46), we can prove that

for some \(R(t)\in L^{1}(0, T^{*})\). Thus, by the Gronwall inequality, we conclude that \((\overline{\rho}, \overline{u}, \overline{h}, \overline{k}, \overline{\varepsilon}) =(0, 0, 0, 0, 0)\) in \((0,T^{*})\times\Omega\). This completes the proof of Theorem 3.1. □

The research of BY was partially supported by the National Natural Science Foundation of China (No. 11471103).

Authors and Affiliations

1. School of Mathematics and Information Science, Henan Polytechnic University, Henan, 454000, China

   Baoquan Yuan & Guoquan Qin

Corresponding author

Correspondence to Baoquan Yuan.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

The authors contributed equally in this article. They read and approved the final manuscript.

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