Existence of positive solutions for a generalized and fractional ordered Thomas-Fermi theory of neutral atoms

The singular boundary value problem we discuss is as follows:

where \(1<\alpha\leq2\), \(\lambda>0\) is a parameter, \({}^{\mathrm{C}}D_{0^{+}}^{\alpha}\) is the Caputo fractional derivative. We present the existence of positive solutions for a fractional boundary value problem modeled from the Thomas-Fermi equation subjected to Sturm-Liouville boundary conditions.

The Thomas-Fermi model (see [1–3]), named after Llewellyn Thomas and Enrico Fermi, is a quantum mechanical theory of electronic structure within many-body systems. In 1927, Thomas and Fermi independently conceived this statistical model applying it to approximate the distribution of electrons in an atom. The Thomas-Fermi model leads to the nonlinear second order differential equation

The boundary conditions under discussion include three circumstances as follows:

1. (i)

   for the neutral atom with Bohr radius ρ, the boundary conditions are

   $$y(0)=1,\qquad \rho y'(\rho)=y(\rho); $$
2. (ii)

   for the ionized atom, the boundary conditions are

   $$y(0)=1,\qquad y(\rho)=0; $$
3. (iii)

   for the isolated neutral atom, the boundary conditions are

   $$y(0)=1,\qquad \lim_{x\rightarrow\infty}y(x)=0. $$

As we know fractional calculus has played a more and more significant role in engineering, science technology, economy and other fields (see [4–13]) just owing to the reason that fractional derivatives could not only have the equation much briefer but also lead to a better description that seems closer to reality. Standing on this point, our theory applies to the generalized equation

where we suppose

1. (I)

   \(1<\alpha\leq2\), \(\alpha_{i}, \beta_{i}\geq0\), \(i= 1, 2\), \(\lambda>0\), \(\frac{\beta_{1}}{\beta_{1}+\beta_{2}}<\frac{\alpha_{1}}{\alpha_{2}}\leq1\), \(f: [0,1]\times[0, +\infty)\rightarrow(0, +\infty)\) is a given continuous function, \(q: (0,1]\rightarrow(0, +\infty)\) is continuous and \(0<\int_{0}^{1}q(t)\, dt<+\infty\).

In order to get a better understanding of our work, let us retrospect some recent attractive results on the existence of positive solutions for boundary value problems.

Agarwal and O’Regan [14] discussed the two-point boundary value problem

where \(a>0\) is fixed. They presented an upper and lower solution theory for boundary value problems modeled from the Thomas-Fermi equation subjected to boundary conditions related to the neutral atom with Bohr radius.

Zhang [15] considered the existence and multiplicity of positive solutions for the nonlinear fractional differential equation boundary value problem

where \(1<\alpha\leq2\) is a real number, \(D_{0^{+}}^{\alpha}\) is the Caputo fractional derivative, \(f: [0,1]\times(0, +\infty)\rightarrow(0, +\infty)\) is a given continuous function. Their results are based on a fixed point theorem on cones.

Sun and Wen [16] investigated the nonlinear third order ordinary equation

with the boundary conditions

Via using the properties of Green’s function and Guo-Krasnosel’skii’s fixed point theorem, Zhao et al. [17] studied the existence of positive solutions for the following boundary value problem:

Su and Zhang [18] proved an existence result for the problem

where \(1<\alpha\leq2\), \(0<\beta\leq1\), \(a_{i}, b_{i}\geq0\), \(i=1,2\), \(a_{1}b_{1}+a_{1}b_{2}+a_{2}b_{1}>0\), \({}^{\mathrm{C}}D_{0^{+}}^{\alpha}\) is the Caputo fractional derivative and \(f: [0,1]\times(0, +\infty)\rightarrow(0, +\infty)\) is a given continuous function.

Zhai and Xu [19] established the existence and uniqueness of positive solutions to a class of four-point boundary value problem of Caputo fractional differential equations for any given parameter:

where \(1<\alpha\leq2\), \(0\leq\xi\leq\eta\leq1\), \(0\leq\mu_{1}\), \(\mu_{2}\leq 1\), \(\lambda>0\) is a parameter, \(f(t, x): [0, 1]\times R^{+}\rightarrow R^{+}\) is continuous and increasing in x for each \(t\in[0, 1]\).

Moreover, there are also many interesting research works on the existence of solutions of boundary value problems, readers can refer to [20–25].

After reading the previous results, it hits on the head that we might turn to problem (1.1). Now let us have a look at the novel contributions of this work. First, we generalize the Thomas-Fermi equation, the second order ordinary differential equation, into a fractional order. Second, f is a function varying along with two variables t and u instead of being constrained by only one variable u. Third, the problem is a singular one, as \(q(t)\) may be singular at \(t=0\). Last but not the least, the existence and multiplicity of the positive solutions depend on a parameter λ.

This paper is organized as follows. In Section 2, we retrospect some preliminaries and lemmas. In Section 3, our results about the existence of positive solutions of problem (1.1) are obtained. The multiplicity of existence of positive solutions for problem (1.1) is debated in Section 4.

For the convenience of the readers, we give some background material from fractional calculus theory to facilitate analysis of boundary value problem (1.1).

Definition 2.1

([4])

The Riemann-Liouville fractional integral of order \(\alpha>0\) of a function \(y:(0,+\infty)\to\mathbb{R}\) is given by

provided the right-hand side is pointwise defined on \((0,+\infty)\).

Definition 2.2

([4])

The Caputo fractional derivative of order \(\alpha>0\) of a continuous function \(y:(0,+\infty)\to\mathbb{R}\) is given by

where n is the smallest integer greater than or equal to α, provided the right-hand side is pointwise defined on \((0,+\infty)\).

Lemma 2.1

([5])

The Caputo derivative of a power function is

given, in particular, \({}^{\mathrm{C}}D_{0^{+}}^{\alpha}t^{\mu}=0\), \(\mu=0,1,\ldots,n-1\), where \({}^{\mathrm{C}}D^{\alpha}_{0^{+}}\) is the Caputo fractional derivative, n is the smallest integer greater than or equal to α.

There are some reduced properties between the Riemann-Liouville type fractional derivative and the Caputo one.

Lemma 2.2

([6])

If \(\alpha=n\) is an integer, the Caputo fractional derivative of order α is the usual derivative of order n. Additionally, the following properties are well known: \(I_{0^{+}}^{\alpha}I_{0^{+}}^{\beta}f(t)= I_{0^{+}}^{\alpha+\beta} f(t)\), \({}^{\mathrm{C}}D_{0^{+}}^{\alpha}I_{0^{+}}^{\alpha}f(t)= f(t)\), \(\alpha>0\), \(f\in C[0,1]\).

From the definition of Caputo derivative and Lemma 2.1, we can obtain the following statement.

Lemma 2.3

([4])

Let \(\alpha>0\). Then the fractional differential equation

has a unique solution

where n is the smallest integer greater than or equal to α.

Lemma 2.4

([4])

Let \(\alpha>0\). Assume that \(u\in C^{n}[0,1]\). Then

for some \(c_{i}\in\mathbb{R}\), \(i=0,1,2,\ldots,n-1\), where n is the smallest integer greater than or equal to α.

With the help of Lemmas 2.1, 2.3 and 2.4, we present the Green’s function for boundary value problem of fractional differential equation.

Lemma 2.5

Let \(h\in C(0,1)\cap L(0,1)\) and \(1<\alpha\leq 2\). Take \(\Delta=\alpha_{2}\beta_{1}-\alpha_{1}\beta_{1}-\alpha_{1}\beta_{2}<0\). Then the fractional differential equation boundary value problem

has a unique solution

where

Proof

We may apply Lemma 2.4 to reduce equation (2.1) to an equivalent integral formula

Then

From \(\alpha_{1}u(0)+\alpha_{2}u'(0)=0\), \(\beta_{1}u(1)+\beta_{2}u'(1)=0\), we have

Therefore, the unique solution of problem (2.1) is

The proof is complete. □

Lemma 2.6

Let \(1<\alpha\leq 2\). Then the following fractional differential equation boundary value problem

has a unique solution

In the following discussion, we denote

Next we present some useful properties of the Green’s function.

Lemma 2.7

The Green’s function \(G(t,s)\) obtained in Lemma  2.5 has these properties as follows:

1. (i)

   \(G(t,s)\in C([0,1]\times [0,1))\) and \(G(t,s)>0\) for \(t, s \in(0, 1)\);

2. (ii)

   there exists a positive function \(\gamma\in C(0,1)\) such that

   $$ \min_{t\in[\frac{1}{4}, \frac{3}{4}]} G(t,s) \geq \gamma(s)M(s), \qquad \max_{t\in[0, 1]} G(t,s) \leq M(s),\quad s \in (0, 1), $$

   (2.5)

   where

   $$M(s)=-\frac{(\alpha_{1}\beta_{1}+\alpha_{1}\beta_{2})(1-s)^{\alpha-1}}{\Delta \Gamma(\alpha)} -\frac{\alpha_{2}\beta_{2}(1-s)^{\alpha-2}}{\Delta\Gamma(\alpha-1)},\qquad \gamma(s)\geq \frac{1}{4}. $$

Proof

From the expression of \(G(t, s)\), it is clear that \(G(t,s)\in C([0,1]\times[0,1))\) and \(G(t,s)>0\) for \(s, t\in(0, 1)\).

Here we define

Then, obviously, \(g_{1}(t,s)\) is a continuous function for \(t\in [\frac{1}{4}, \frac{3}{4}]\) and \(g_{2}(t,s)\) is decreasing with respect to t. Hence, we have

Thus, we get

Let

From hypothesis (I), we see

Hence the statements in Lemma 2.7 are proved. □

Our main results are typically based on the following fixed point theorem.

Lemma 2.8

([7])

Let B be a Banach space, and let \(K\subset B\) be a cone. Assume that \(\Omega_{1}\), \(\Omega_{2}\) are open and bounded subset of B with \(0\in\Omega_{1}\), \(\bar{\Omega}_{1}\subset\Omega_{2}\), and let \(T:K\cap(\bar{\Omega}_{2}\setminus\Omega_{1})\rightarrow K\) be a completely continuous operator such that

1. (i)

   \(\|Tu\|\leq\|u\|\), \(u\in K\cap\partial\Omega_{1}\) and \(\|Tu\|\geq\|u\|\), \(u\in K\cap\partial\Omega_{2}\) or

2. (ii)

   \(\|Tu\|\geq\|u\|\), \(u\in K\cap\partial\Omega_{1}\) and \(\|Tu\|\leq\|u\|\), \(u\in K\cap\partial\Omega_{2}\).

Then T has a fixed point in \(K\cap (\bar{\Omega}_{2}\setminus\Omega_{1})\).

In this section, we establish the existence of positive solutions for problem (1.1) in terms of different values of the parameter λ.

From Lemmas 2.5 and 2.6, we know that proving the existence of positive solutions for fractional differential boundary value problem (1.1) is equivalent to discussing the existence of positive solutions for the problem

then \(u=v+\varphi\) must be the solution of problem (1.1), and vice versa.

Let \(X=C^{1}[0,1]\) with norm \(\|u\|=\max_{t\in[0,1]}|u(t)|\), \(u\in X\). Clearly, X is a Banach space. Take

Then it is easy to see that P is a positive cone in X.

Define an operator \(T: P\rightarrow X\) by

Noting that the possible singular point of q is 0 and M maybe singular only at 1, we are able to show that \(\int_{0}^{1} M(s)q(s)\, ds\) is well defined by hypothesis (I), Lemma 2.7 and the convergence of \(\int_{0}^{1} M(s)\, ds\) and \(\int_{0}^{1}q(s)\, ds\). From this, it is easy to see that the operator T is also well defined.

Denote

Lemma 3.1

Assume that (I) holds. Then the pair of equations (3.1) and (3.2) is equivalent to the nonlinear integral equation

In other words, every solution of (3.1) and (3.2) is also a continuous solution of (3.3) and vice versa.

Proof

Let \(v\in X\) be a solution of (3.1) and (3.2); as the same method of proving Lemma 2.5, we can get that v is a solution of (3.3).

On the other hand, let v be a continuous solution of (3.3) on \([0,1]\). Then define

From Lemmas 2.1 and 2.2, we have

One can verify easily that \(\alpha_{1}v(0)+\alpha_{2}v'(0)=0\), \(\beta_{1}v(1)+\beta_{2}v'(1)=0\). Therefore, v is a continuous solution of (3.1) and (3.2). The proof is completed. □

Lemma 3.1 indicates that the solution of problems (3.1) and (3.2) coincides with the fixed point of the operator T.

Incidentally, we have the following dispensable lemma at hand.

Lemma 3.2

The operator \(T: P\rightarrow P\) is completely continuous.

Proof

Obviously, \(Tv(t)\geq0\). Then first we are going to prove that the operator \(T: P\rightarrow X\) is continuous. Actually, for each \(v_{n}, v\in P\) and \(v_{n}\rightarrow v\), we get

Since f is continuous, for any \(\varepsilon>0\), there exists \(N\in \mathbb{N}\) such that \(\vert f(s, v_{n}(s)+\varphi(s))-f(s, v(s)+\varphi(s))\vert <\varepsilon\), when \(n>N\). Hence,

So it is sufficient to say that T is continuous.

For \(v\in P\), by Lemma 2.7, we have

On the other hand,

Thus, we obtain

therefore, \(T: P\rightarrow P\).

Let \(\Omega\subset P\) be bounded. Then there exists a positive constant \(Q>0\) such that \(\|v\|\leq Q\) for all \(v\in\Omega\). Take \(L=\max_{t\in[0,1],\|v\|\leq Q}|f(t, v(t)+\varphi(t))|+1\). Then, for each \(v\in\Omega\), from Lemma 2.7, we have

Hence, \(T(\Omega)\) is bounded.

Next we are about to prove that for all \(\varepsilon>0\), each \(v\in P\), \(t_{1}, t_{2} \in[0, 1]\), \(t_{1}< t_{2}\), let \(\eta=\min \{\frac{1}{2}, \frac{\varepsilon}{L_{1}} \}\), we have \(|Tv(t_{2})-Tv(t_{1})|<\varepsilon\), when \(t_{2}-t_{1}<\eta\). In fact, for each \(v\in\Omega\), we have

Since we have proved \(\int_{0}^{1}(1-s)^{\alpha-2}q(s)\, ds<\infty\) and \(\int_{0}^{1}q(s)\, ds<\infty\), we can just define

Then \((Tv)'(t)\leq L_{1}\).

Whence,

By the Arzela-Ascoli theorem, the operator \(T: P\rightarrow P\) is completely continuous. The proof is completed. □

For convenience, we give some denotations:

Theorem 3.1

Assume that \((I_{1}f_{\infty})^{-1}=0\) if \(f_{\infty}=\infty\) and \((I_{2}F_{0})^{-1}=\infty\) if \(F_{0}=0\). If \(I_{1}f_{\infty}> I_{2}F_{0}\) holds, then for each

the boundary value problem (1.1) has at least one positive solution.

Proof

Choose \(\varepsilon>0\) sufficiently small such that

By the definition of \(F_{0}\), we see that there exists \(r_{1}>0\) such that

So if \(v\in\partial P\) with \(\|v\|=r_{1}\), then by (3.7) and (3.8), we see

Hence, if we choose \(\Omega_{1}=\{v\in X: \|v\|< r_{1}\}\), then \(\|Tv\|\leq\|v\|\) for \(v\in P\cap\partial\Omega_{1}\).

Let \(r_{2}>0\) be a constant such that

If \(v\in\partial P\) with \(\|v\|=r_{3}=\max\{2r_{1}, r_{2}\}\), then by (3.7) and (3.9) we have

Thus, if we define \(\Omega_{2}=\{v\in X: \|v\|< r_{3}\}\), then \(\|Tv\|\geq\|v\|\) for \(v\in P\cap\partial\Omega_{2}\).

Then, by Lemma 2.8, we find that T has a fixed point \(v\in P\cap(\bar{\Omega}_{2}\setminus\Omega_{1})\) with \(r_{1}\leq\|v\|\leq r_{3}\), therefore, v is a positive solution of (3.1) and (3.2), then \(v+\varphi\) is a positive solution of (1.1). The proof is completed. □

Theorem 3.2

Assume that \((I_{1}f_{0})^{-1}=0\) if \(f_{0}=+\infty\) and \((I_{2}F_{\infty})^{-1}=\infty\) if \(F_{\infty}=0\). If \(I_{1}f_{0}> I_{2}F_{\infty}\) holds, then for each

the boundary value problem (1.1) has at least one positive solution.

Proof

Let λ be endowed with (3.10) and \(\varepsilon>0\) be such that

By the definition of \(f_{0}\), we see that there exists \(r_{1}>0\) such that

Hence, if \(v\in\partial P\) with \(\|v\|=r_{1}\), then by the same method used in Theorem 3.1, we get \(\|Tv\|\geq\|v\|\). Furthermore, if we choose \(\Omega_{1}=\{v\in X: \|v\|< r_{1}\}\), then \(\|Tv\|\geq\|v\|\) for \(v\in P\cap\partial\Omega_{1}\). In the next, we choose \(r_{2}>0\) subjected to

We discuss two cases as follows.

Case 1. Assume that f is bounded. Then there exists a certain constant \(L>0\) such that \(f(t, v+\varphi(t)) \leq Lr_{3}\) for \(v\in (0, +\infty)\). We define \(r_{3}=\max\{2r_{1}, r_{2}\}\) and \(v\in\partial P\) with \(\|v\|=r_{3}\), then

Therefore, \(\|Tv\|\leq\|v\|\) for \(v\in\partial P_{r_{3}}=\{v\in P: \|v\|< r_{3}\}\).

Case 2. Assume that f is unbounded. Then there exists some constant \(r_{4}>\max\{2r_{1}, r_{2}\}\) such that \(f(t, v+\varphi(t)) \leq f(t, r_{4}+\varphi(t))\) for \(0< v \leq r_{4}\). Let \(v\in\partial P\) with \(\|v\|=r_{4}\). Then, from (3.11) and (3.13), we have

It is sufficient to show that \(\|Tv\|\leq\|v\|\) for \(v\in\partial P_{r_{3}}=\{v\in P: \|v\|< r_{4}\}\). Then we take \(\Omega_{2}=\{v\in X: \|v\|< r_{5}=: \max\{r_{3}, r_{4}\}\}\), then \(\|Tv\|\leq\|v\|\) for \(v \in P\cap\partial\Omega_{2}\). From Lemma 2.8, operator T has a fixed point \(v\in P\cap(\bar{\Omega}_{2}\setminus\Omega_{1})\) with \(r_{1}\leq\|v\| \leq r_{5}\). It is clear enough that v is a positive solution of (3.1) and (3.2), then \(v+\varphi\) is a positive solution of (1.1). The proof is completed. □

Theorem 3.3

Suppose that there exist constants \(r_{2}>r_{1}>0\) for all \(t\in[0,1]\), the following condition holds:

Then the boundary value problem (1.1) has at least one positive solution.

Proof

Choose \(\Omega_{1}=\{v\in X: \|v\|< r_{1}\}\), then for \(v\in P\cap\partial\Omega_{1}\), we have

On the other hand, choose \(\Omega_{2}=\{v\in X: \|v\|< r_{2}\}\), then for \(v\in P\cap\partial\Omega_{2}\), we have

Therefore from Lemma 2.8, operator T has a fixed point \(v\in P\cap(\bar{\Omega}_{2}\setminus\Omega_{1})\) with \(r_{1}\leq\|v\| \leq r_{2}\). It is clear enough that v is a positive solution of (3.1) and (3.2), then \(v+\varphi\) is a positive solution of (1.1). The proof is completed. □

Theorem 3.4

Suppose that the following condition holds:

Then the boundary value problem (1.1) has no positive solution.

Proof

Assume to the contrary that \(v+\varphi\) is a positive solution of (1.1), v is a positive solution of (3.1) and (3.2). Then

which comes to a contradiction and completes the proof. □

Theorem 3.5

Suppose that the following condition holds:

Then the boundary value problem (1.1) has no positive solution.

Proof

The proof of Theorem 3.5 is similar to that of Theorem 3.4, therefore omitted. □

Example 3.1

Consider the boundary value problem

Then

By a direct calculation, we get

From Theorem 3.1, we see if

then problem (1.1) has at least one positive solution. From Theorem 3.4, if

we see that problem (1.1) has no positive solution. By Theorem 3.5, if

then we obtain that problem (1.1) has no positive solution.

Here we are about to give some results on the existence of multiple positive solutions. The following two lemmas will be of use to prove our main results.

Lemma 4.1

Assume that there exists a constant \(c>0\) such that \(\max_{0\leq v\leq c}f(t,v+\varphi(t))\leq \frac{c}{\lambda I_{2}}\) for all \(t\in[0,1]\). Then

Proof

If \(v\in P\) with \(\|v\|=c\), then

the proof is complete. □

Lemma 4.2

Assume that there exists a constant \(c>0\) such that \(\min_{\frac {1}{4}c\leq v\leq c}f(t,v+\varphi(t))\geq \frac{c}{\lambda I_{1}}\) for all \(t\in[0,1]\). Then

Proof

If \(v\in P\) with \(\|v\|=c\), then for \(t\in [\frac{1}{4},\frac{3}{4}]\) we have \(v(t)\geq\frac{1}{4}\|v\|\). Therefore, we have

so the proof is complete. □

Theorem 4.1

Assume that there are constants \(0< c_{1}< c_{2}< c_{3}< c_{4}\) such that

1. (i)

   \(\max_{0\leq v\leq c_{i}}f(t,v+\varphi(t))\leq \frac{c_{i}}{\lambda I_{2}}\) for all \(t\in[0,1]\), \(i= 1,4\) and

2. (ii)

   \(\min_{\frac{1}{4}c_{i}\leq v\leq c_{i}}f(t,v+\varphi(t))\geq \frac{c_{i}}{\lambda I_{1}}\) for all \(t\in[0,1]\), \(i= 2,3\).

Then the boundary value problem (1.1) has at least two positive solutions.

Proof

If

then from Lemmas 4.1 and 4.2, we have

and

Now from Lemma 2.8 we get that T has two fixed points, one in each of two sets \(P\cap(\bar{\Omega}_{4}\setminus\Omega_{3})\) and \(P\cap(\bar{\Omega}_{2}\setminus\Omega_{1})\). This completes the proof. □

In the same way, we can obtain the following result.

Theorem 4.2

Assume that there are constants \(0< c_{1}< c_{2}< c_{3}< c_{4}\) such that

1. (i)

   \(\max_{0\leq v\leq c_{i}}f(t,v+\varphi(t))\leq \frac{c_{i}}{\lambda I_{2}}\) for all \(t\in[0,1]\), \(i= 2,3\), and

2. (ii)

   \(\min_{\frac{1}{4}c_{i}\leq v\leq c_{i}}f(t,v+\varphi(t))\geq \frac{c_{i}}{\lambda I_{1}}\) for all \(t\in[0,1]\), \(i= 1,4\).

Then the boundary value problem (1.1) has at least two positive solutions.

For an arbitrary positive integer n, we can choose proper constants to meet expectation of f, so that problem (1.1) has at least n positive solutions.

Theorem 4.3

Assume that there are constants \(0< c_{1}< c_{2}< c_{3}<\cdots<c_{2n-1}<c_{2n}\) such that

1. (i)

   \(\max_{0\leq v\leq c_{i}}f(t,v+\varphi(t))\leq \frac{c_{i}}{\lambda I_{2}}\) for all \(t\in[0,1]\), \(i= 1,4,\ldots, 4k-3+\frac{3(1+(-1)^{n})}{2}\) and

2. (ii)

   \(\min_{\frac{1}{4}c_{i}\leq v\leq c_{i}}f(t,v+\varphi(t))\geq \frac{c_{i}}{\lambda I_{1}}\) for all \(t\in[0,1]\), \(i= 2,3,\ldots, 4k-2+\frac{1+(-1)^{n}}{2}\),

where \(k=1,2,\ldots, [\frac {n+1}{2} ]\). Then the boundary value problem (1.1) has at least n positive solutions.

The authors sincerely thank the reviewers for their valuable suggestions and useful comments that have led to the present improved version of the original manuscript. This research is supported by the Natural Science Foundation of China (11571202, 61374074), Natural Science Outstanding Youth Foundation of Shandong Province (JQ201119) and supported by Shandong Provincial Natural Science Foundation (ZR2012AM009, ZR2013AL003).

Authors and Affiliations

1. School of Mathematical Science, University of Jinan, Jinan, Shandong, 250022, P.R. China

   Wenquan Feng, Shurong Sun & Ying Sun

Corresponding author

Correspondence to Shurong Sun.

Competing interests

The authors declare that the study was realized in collaboration with the same responsibility. All authors read and approved the final manuscript.

Authors’ contributions

The authors declare that they have no competing interests.

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