The Dynamic Mutation Characteristics of Thermonuclear Reaction in Tokamak

The stability and bifurcations of multiple limit cycles for the physical model of thermonuclear reaction in Tokamak are investigated in this paper. The one-dimensional Ginzburg-Landau type perturbed diffusion equations for the density of the plasma and the radial electric field near the plasma edge in Tokamak are established. First, the equations are transformed to the average equations with the method of multiple scales and the average equations turn to be a Z 2-symmetric perturbed polynomial Hamiltonian system of degree 5. Then, with the bifurcations theory and method of detection function, the qualitative behavior of the unperturbed system and the number of the limit cycles of the perturbed system for certain groups of parameter are analyzed. At last, the stability of the limit cycles is studied and the physical meaning of Tokamak equations under these parameter groups is given.


Introduction
Periodic solution theory is mainly about the existence and stability of periodic solution of dynamical systems. The bifurcation theory of periodic solution, as the main method to study the periodic solution, reveals the connection between the topology of the solutions and the parameters. The investigation and application of bifurcations and chaos of nonlinear dynamical systems are frontier topics in the world.
Recently, a large number of important results of multiple limit cycles of polynomial planar vector fields have been achieved. Arnol' d [1] examined the problem on equivariant fields and their topologically versal deformations in the functional space of all equivariant fields and these results yield the first approximation for the stability loss problem. Perko [2] studied the local bifurcation and global behavior of oneparameter families of limit cycles of a planar analytic system. They obtained some new results on the global behavior of one-parameter families of limit cycles. Wang and Mao [3] gave an algorithm for computing the Lyapunov values and a new criterion for determining the centers of planar polynomial systems which have quartic nonlinear terms. They found that there are 11 small limit cycles in a kind of planar polynomial systems. Chan et al. [4] showed that the numerical examples of different quadratic differential systems had three limit cycles surrounding one singular point. Li [5] investigated Hilbert's 16th problem and bifurcations of planar polynomial vector fields and gave the detection function method of two dimensional Hamiltonian systems. Armengol and Joan [6] perturb a vector field with a general polynomial perturbation of degree and study the maximum number of limit cycles that can bifurcate from the period annulus of the origin in terms of and . Their approach is based on the explicit computation of the Abelian integral that controls the bifurcation and on a new result for bounding the number of zeroes of a certain family of real functions. Han and Li [7] obtained some new lower bounds of Hilbert number ( ), and ( ) grows at least as rapidly as (1/2 ln 2) ( +2) 2 ln( + 2) for all large . Zhao and Fan [8] studied the number of small amplitude limit cycles in arbitrary polynomial systems with degree , denoted by ( ), and obtained the lower bounds for (6) − (14) and proved that ( ) ≥ 2 if ≥ 23. They also showed that the least growth order of ( ) is equal to that of ( ) (in [9]); however, the growth coefficient of ( ) is 25/18 that of ( ).
The symmetry of dynamical systems is also widely studied by many researchers and a lot of results have been achieved.

2
The Scientific World Journal Li et al. [10] analyzed a 6 -equivariant perturbed polynomial Hamiltonian system of degree 5 and found that there exist at most 24 limit cycles. Li et al. [9] investigated a rotoractive magnetic bearings (AMB) system with the timevarying stiffness and found that there exist, respectively, at least 17, 19, 21, and 22 limit cycles under four groups of parametric controlling conditions. Li et al. [11] investigated the bifurcation of multiple limit cycles of a 2 -equivariant perturbed polynomial Hamiltonian system of degree 5 and found that the 2 -equivariant fields have up to 23 limit cycles. Li et al. [12] studied bifurcations of limit cycles at three fine focuses for a class of 2 -equivariant nonanalytic cubic planar differential systems proved that there exist 12 small amplitude limit cycles created from the critical points.
In recent years, theories are widely used in mechanical systems. An important issue is the bifurcation of multiple limit cycles for Tokamak system. The Tokamak is the most promising device so far to attain the conditions for fusion. It is a toroidal device (shaped like a car tire) in which a vacuum vessel contains a plasma ring confined by twisting magnetic fields. In the past 20 years, researches and applications of the Tokamak have great achievements, especially with the implementation of the construction named EAST (Experimental Advanced Superconducting Tokamak). EAST is one of Chinese national fusion projects.
In this paper, the mechanism of the transition from Lmode to H-mode in Tokamak is an important and difficult problem. We mainly discussed the transition phenomenon between low confinement mode (L-mode) and high confinement mode (H-mode) observed in Tokamak. S. Itoh and K. Itoh [13] presented a new model of the transition from L-mode to H-mode in the Tokamak plasmas and discussed the catastrophic phenomenon of it. Viana [14] used a Hamiltonian description for magnetic field lines in a large aspect ratio Tokamak for describing the effect of resonant helical windings in a perturbative way, taking into account the toroidal correction. Zhang and Cao [15] found that in Tokamak there existed not only the static L-mode to Hmode transition but also to the dynamic L-mode to Hmode transition, and the Hopf bifurcation and limit cycle oscillations correspond to the L-mode to H-mode transition near the plasma edge in Tokamak.
This paper focuses on the bifurcations of multiple limit cycles for a Ginzburg-Landau type perturbed transport equation which can describe the L-mode to H-mode transition near the plasma edge in Tokamak. The average equation of Tokamak system turns out to be a 2 -equivariant perturbed Hamiltonian system. Using the bifurcation theory and the method of detection function, the number of limit cycles of the average equation under a certain group of parameters is given. The stability of these limit cycles is analyzed and the diffusion coefficients of H-mode and L-mode are obtained.

Equation of Motion and Perturbation Analysis
We get the nondimensional formulations by using the method in [16]. The one-dimensional Ginzburg-Landau type perturbed diffusion equations for the density of the plasma and the radial electric field near the plasma edge in Tokamak can be written as where and are the density of the particle near the plasma edge and the normalized radial electric field, respectively. ( ) and 1 are the diffusion coefficients of the density and electric field, ( , ) is the total current effect, and 1 , Ω 1 , 2 , and Ω 2 are the amplitudes and frequencies of the particle perturbation and the controlling radial electric field. It is known that ( ), ( , ), and ,respectively, satisfy the following equations: where max and min , respectively, denote the diffusion coefficients of H-mode and L-mode, the parameters V , , , , , , and 0 are constants, and V , , , and are the Alfven velocity, the light velocity, the magnetic field which is parallel to the poloidal direction in Tokamak, and the characteristic magnetic field, respectively.
In order to analyze the diffusion of the particle and the stability and bifurcations of the normalized radial electric field near the plasma edge in Tokamak, some transformations may be introduced as follows: where ( ) V( ) and ( ) ( ) are small perturbed terms. Substituting (2) and (3) into (1), we have the following equations: Eliminate V andV ; then we can geẗ We assume that the uniform solution of (5) can be represented in the form ( , ) = 0 ( 0 , 1 , 2 , . . .) + 1 ( 0 , 1 , 2 , . . .) The Scientific World Journal 3 Then, the differential operators are given as where = / , = 0, 1. The main work of this paper focuses on the 1/2 subharmonic resonance-primary parametric resonance, because this resonant case is the most common case which may be exhibited in system (5). To simplify the procedure of the analysis, without loss of generality, we may assume that where is a detuning parameter. Substituting (6)-(8) into (5), and we get the averaged equations of (5): Then (9a) and (9b) can be rewritten as follows: Let 41 = 23 = 21 = 14 = 32 = 12 = 0 and 10 = 01 ; the system ((10a) and (10b)) turns out to be a 2 -equivariant perturbed Hamiltonian system with 17 free parameters.

The Dynamic Characteristics of Thermonuclear Reaction in Tokamak
In Section 2, the Ginzburg-Landau Tokamak system turns out to be a 2 -equivariant Hamiltonian system of degree 5. We will give a procedure of controlling parameters to obtain more limit cycles of the system ((10a) and (10b)).

The Method of Detection Functions.
In this section, the method of detection functions will be described briefly based on references [8,17]. Let ( , ) be a real polynomial of degree , and let ( , ) and ( , ) be two different real polynomials of degree , respectively. We consider a perturbed Hamiltonian system in the following form: where 0 < ≪ 1 is a small parameter and the level energy curves ( , ) = ℎ of the unperturbed Hamiltonian system ((10a) and (10b)) =0 contain at least a family of closed orbits Γ ℎ for ℎ ∈ (ℎ , ℎ ).

Consider the Abelian integral
We define the function which is called a detection function corresponding to the periodic family {Γ ℎ }. The graph of = (ℎ) in the plane (ℎ, ) is called a detection curve, where ℎ is the area inside Γ ℎ . Theorem 1 (bifurcation of limit cycles). We have the following three statements on the local and global bifurcations.
(3) The total number of isolated zeros of the Abelian integral is an upper bound for the number of limit cycles of system ((11a) and (11b)) after taking into account their multiplicity.
In this paper, we only consider a special case that Proposition 2. Under the conditions of UP, the Hamiltonian function (15) has the diagram as shown in Figure 1 and the 2equivariant Hamiltonian vector field ((14a) and (14b)) has the phase portraits as shown in Figure 2. Figure 3 illustrates the changing process of the phase portraits for system ((14a) and (14b)) as the variable ℎ changes from −∞ to +∞. In the aforementioned case, there are nine different families (Γ ℎ ) ( = 0, 1, . . . , 8) of closed orbits and several homoclinic or heteroclinic loops for unperturbed system ((14a) and (14b)) as the variable ℎ changes from −∞ to +∞.

The Qualitative Behavior of Perturbed System ((10a) and
(10b)). Based on the results obtained above, we can analyze the qualitative nonlinear characteristics of the perturbed system ((10a) and (10b)). The detection functions corresponding It follows that, under the parameter conditions of UP and PG, the system ((10a) and (10b)) has the graphs of detection curves as shown in Figure 4.

Proposition 3.
When =̃satisfies (20), for the parameter groups of UP and PG and small > 0, the system ((10a) and (10b)) has at least 22 limit cycles with the configuration shown in Figure 5.
The Scientific World Journal 5 Figure 2: Families of closed orbits defined by system ((10a) and (10b)) with UP is given.

The Analysis of Stability
Based on the local and global bifurcation theory and the results of paper [14,18], we have two propositions which describe the properties of the detection function at the boundary values of ℎ.
Then one has From the theorems above, we can also prove the following results.
(1) If Γ ℎ contracts inwards as ℎ increases, then the stability of limit cycles mentioned in Theorem 4 and the sign of (ℎ 2 ) in Theorem 5 have the opposite conclusion.
On the basis of the method of the theorems above, we have the following analyses of stability.

The Physical Meaning of Tokamak Equations under the UP and PG Parameter Groups
The relationship between the actual parameters of the physical equations and the parameter conditions UP and PG will be discussed in the following parts and the results will be explained following the theory of multiple limit cycle bifurcation.

Conclusions
This paper focuses on the bifurcations of multiple limit cycles for a Tokamak system. First, the method of multiple scales and normal form theory are employed to obtain the average equation in the Tokamak system, which has the form of a 2 -symmetric perturbed polynomial Hamiltonian system of degree 5. Then, with the bifurcation theory of planar dynamical system and the method of detection functions, the bifurcations of multiple limit cycles of the averaged equation are analyzed. Finally, the dynamical behavior of the Tokamak system under a group of parameters condition is given. One control condition of parameters is given to obtain 22 limit cycles of the Tokamak system. Ten of them are stable and the others are unstable. The Hopf bifurcation and limit cycles in averaged equation ((10a) and (10b)) correspond to the Lmode to H-mode transition near the plasma edge in Tokamak. It implies that the amplitude modulated oscillations can jump from one limit cycle to another with a change of the initial conditions. Because different limit cycles are located in different energy planes of ((10a) and (10b)), motion of the Tokamak system can jump from a lower energy plane to a higher energy plane.