Two-component systems allow for a much larger range of possible phenomena than their one-component counterparts. An important idea that was first proposed by
Alan Turing is that a state that is stable in the local system can become unstable in the presence of
diffusion. A linear stability analysis however shows that when linearizing the general two-component system : \begin{pmatrix} \partial_t u \\ \partial_t v \end{pmatrix} = \begin{pmatrix} D_u &0 \\0&D_v \end{pmatrix} \begin{pmatrix} \partial_{xx} u\\ \partial_{xx} v \end{pmatrix} + \begin{pmatrix} F(u,v)\\G(u,v)\end{pmatrix} a
plane wave perturbation : \tilde{\mathbf{q}}_{\mathbf{k}}(\mathbf{x},t) = \begin{pmatrix} \tilde{u}(t)\\\tilde{v}(t) \end{pmatrix} e^{i \mathbf{k} \cdot \mathbf{x}} of the stationary homogeneous solution will satisfy :\begin{pmatrix} \partial_t \tilde{u}_{\mathbf{k}}(t)\\ \partial_t \tilde{v}_{\mathbf{k}}(t) \end{pmatrix} = -k^2\begin{pmatrix} D_u \tilde{u}_{\mathbf{k}}(t)\\ D_v\tilde{v}_{\mathbf{k}}(t) \end{pmatrix} + \mathbf{R}^{\prime} \begin{pmatrix}\tilde{u}_{\mathbf{k}}(t) \\ \tilde{v}_{\mathbf{k}}(t) \end{pmatrix}. Turing's idea can only be realized in four
equivalence classes of systems characterized by the signs of the
Jacobian of the reaction function. In particular, if a finite wave vector is supposed to be the most unstable one, the Jacobian must have the signs : \begin{pmatrix} +&-\\+&-\end{pmatrix}, \quad \begin{pmatrix} +&+\\-&-\end{pmatrix}, \quad \begin{pmatrix} -&+\\-&+\end{pmatrix}, \quad \begin{pmatrix} -&-\\+&+\end{pmatrix}. This class of systems is named
activator-inhibitor system after its first representative: close to the ground state, one component stimulates the production of both components while the other one inhibits their growth. Its most prominent representative is the
FitzHugh–Nagumo equation :\begin{align} \partial_t u &= d_u^2 \,\nabla^2 u + f(u) - \sigma v, \\ \tau \partial_t v &= d_v^2 \,\nabla^2 v + u - v \end{align} with which describes how an
action potential travels through a nerve. Here, and are positive constants. When an activator-inhibitor system undergoes a change of parameters, one may pass from conditions under which a homogeneous ground state is stable to conditions under which it is linearly unstable. The corresponding
bifurcation may be either a
Hopf bifurcation to a globally oscillating homogeneous state with a dominant wave number or a
Turing bifurcation to a globally patterned state with a dominant finite wave number. The latter in two spatial dimensions typically leads to stripe or hexagonal patterns. Image:Turing_bifurcation_1.gif| Noisy initial conditions at
t = 0. Image:Turing_bifurcation_2.gif| State of the system at
t = 10. Image:Turing_bifurcation_3.gif| Almost converged state at
t = 100. For the Fitzhugh–Nagumo example, the neutral stability curves marking the boundary of the linearly stable region for the Turing and Hopf bifurcation are given by :\begin{align} q_{\text{n}}^H(k): &{}\quad \frac{1}{\tau} + \left (d_u^2 + \frac{1}{\tau} d_v^2 \right )k^2 & =f^{\prime}(u_{h}),\\[6pt] q_{\text{n}}^T(k): &{}\quad \frac{\kappa}{1 + d_v^2 k^2}+ d_u^2 k^2 & = f^{\prime}(u_{h}). \end{align} If the bifurcation is subcritical, often localized structures (
dissipative solitons) can be observed in the
hysteretic region where the pattern coexists with the ground state. Other frequently encountered structures comprise pulse trains (also known as
periodic travelling waves), spiral waves and target patterns. These three solution types are also generic features of two- (or more-) component reaction–diffusion equations in which the local dynamics have a stable limit cycle Image:reaction_diffusion_spiral.gif| Rotating spiral. Image:reaction_diffusion_target.gif| Target pattern. Image:reaction_diffusion_stationary_ds.gif| Stationary localized pulse (dissipative soliton). ==Three- and more-component reaction–diffusion equations==