THE BLOW UP OF THE SOLUTION OF FRACTIONAL ORDINARY DIFFERENTIAL EQUATIONS

Consider the initial value problem of (non-fractional) ordinary differential equation = ( ), 0 < < ∞. (0) = > 0. (1) When ( ) = , the solution of the problem (1) is ( ) = [( − 1)( − )]  where = . If 1 < < ∞ then ( ) ⟶ ∞ as ⟶ . It means that can not extend globally in time or is said to blow up in finite time. Many mathematicians have discussed the blow up of the solution of the (non fractional) ordinary/partial differential equations. One can know the discussion about this in [2] or [3].

When ( ) = , the solution of the problem (1) is where = . If 1 < < ∞ then ( ) ⟶ ∞ as ⟶ . It means that can not extend globally in time or is said to blow up in finite time. Many mathematicians have discussed the blow up of the solution of the (non fractional) ordinary/partial differential equations. One can know the discussion about this in [2] or [3].
In this paper, we will discuss the blow up of the solution of the initial value problem of fractional ordinary differential equation where is Riemann-Liouville fractional derivative operator defined as and Γ is Gamma function with 0 < < 1. As for fractional differential equations, one can read more completely about it, for an example, in [3]. Specifically, we will find the sufficient condition so that the solution of the problem (2) exists uniquely. Moreover, we will also find the sufficient condition so that the solution blows up in finite time. The result about the blow up notion for fractional ordinary differential (2), as a ordinary diferential equation part of fractional semilinear parabolic equation, will be useful to describe the blow up notion for fractional semilinear parabolic equation itself.

MAIN RESULT
In order to discuss the blow up notion, of course, we must determine the solution of the problem (2) first. Consider It follows that Then we have , ( ) for some ∈ (0, ∞). By the initial condition, For an example, we will find the solution of the problem (2) for , ( ) = ( ) .
The non trivial solution is Therefore, we have If > 1 then ( ) → ∞ as → . It means that the solution blows up in finite time < ∞. This result is similar to that of the problem of (1), the initial value problem of (non fractional) ordinary differential equation.
Next, we will find the sufficient condition so that the problem (2) has a unique solution. Suppose that is a function defined as We will investigate the existence and the uniqueness of the solution . Consider It is clear that 0 < ( ) < 1 based on our assumption. By Contraction Mapping Principle, the solution exists uniquely.
After discussing the existence and the uniqueness of the solution, we discuss the sufficient condition so that the solution blows up in finite time. Suppose that Consider that Because of (3), we conclude that lim → ( ) = ∞. It means that the solution blows up in finite time .

CONCLUSION
Based on our discussion in preceding section, we have two main results concerning the blow up of the solution of the problem (2).
The following theorem gives us the sufficient condition so that the problem (2) has a unique solution. Then the initial value problem of fractional ordinary differential equation (2) has a unique solution.
The next theorem gives us the sufficient condition so that the solution of the problem (2) blows up in finite time.