@article{oai:nifs-repository.repo.nii.ac.jp:00010566,
 author = {IDA,  Katsumi and FUJITA,  Takaaki},
 issue = {3},
 journal = {Plasma Physics and Controlled Fusion},
 month = {Jan},
 note = {0000-0002-0585-4561, The differences and similarities between the internal transport barriers (ITBs) of tokamak and helical plasmas are reviewed. By comparing the characteristics of the ITBs in tokamak and helical plasmas, the mechanisms of the physics for the formation and dynamics of the ITB are clarified. The ITB is defined as the appearance of discontinuity of temperature, flow velocity, or density gradient in the radius. From the radial profiles of temperature, flow velocity, and density the ITB is characterized by the three parameters of normalized temperature gradient, $R/{L}_{T}$, the location, ${\rho }_{\mathrm{ITB}}$, and the width, W/a, and can be expressed by 'weak' ITB (small $R/{L}_{T}$) or 'strong' (large $R/{L}_{T}$), 'small' ITB (small ${\rho }_{\mathrm{ITB}}$) or 'large' ITB (large ${\rho }_{\mathrm{ITB}}$), and 'narrow' (small W/a) or 'wide' (large W/a). Three key physics elements for the ITB formation, radial electric field shear, magnetic shear, and rational surface (and/or magnetic island) are described. The characteristics of electron and ion heat transport and electron and impurity transport are reviewed. There are significant differences in ion heat transport and electron heat transport. The dynamics of ITB formation and termination is also discussed. The emergence of the location of the ITB is sometimes far inside the ITB foot in the steady-state phase and the ITB region shows radial propagation during the formation of the ITB. The non-diffusive terms in momentum transport and impurity transport become more dominant in the plasma with the ITB. The reversal of the sign of non-diffusive terms in momentum transport and impurity transport associated with the formation of the ITB reported in helical plasma is described. Non-local transport plays an important role in determining the radial profile of temperature and density. The spontaneous change in temperature curvature (second radial derivative of temperature) in the ITB region is described. In addition, the key parameters of the control of the ITB and future prospects are discussed.},
 title = {Internal Transport Barrier in Tokamak and Helical Plasmas},
 volume = {60},
 year = {2018}
}