Slow dynamo modes in compact Riemannian plasma devices from Brazilian spherical tokamak data

Anti-dynamo modes are usually found in spheromaks plasma devices experiments due to the fact that Cowlings anti-dynamo theorem is naturally applied to axisymmetric devices and flows. In this paper full consideration is given to the existence of slow dynamo modes in the case of compact Riemannian plasma devices without boundaries, such as tokamaks, stellarators and torsatrons. It is shown that a perturbed untwisted flow given by a decaying mode magnetic field is able to generate a slow twisted dynamo plasma flow where the unperturbed flow is also a steady flow. When the slow dynamo limit is obtained for high Reynolds magnetic numbers Rm, the unperturbed plasma flow achieve equilibrium as in spheromaks. A Riemann metric of a twisted thick magnetic flux tube with a very low aspect ratio is used in the computations. The data of aspect ratio and other data obtained from the Brazilian spherical tokamak at the National institute for space research (INPE) are used to obtain a numerical estimate for the maximum magnetic growth rate of the magnetic field of the slow dynamo action as γ1max ≈ 0.26 a × v1θ B1s for a toroidal initial magnetic field B0 ≈ 0.4T and an aspect data tokamak of 1.5. For a tokamak internal radius of a ≈ 0.2m one obtains a maximum growth rate for the slow dynamo as γ1max ≈ 1.3× v1θ B1s , where v1θ is the poloidal perturbed diffusive flow. The safety factor is given by q ≈ −1 which is q < 1 implying stability of spherical tokamak plasma. Slow dynamos have been recently given in the literature as an example of Vishik’s anti-fast dynamo theorem [Phys Plasmas 15 (2008)], which can also been tested in plasma experimental devices.Key-words:anti-dynamo theorems, slow dynamos.