Role of isotopes in microturbulence from linear to saturated Ohmic confinement regimes

The first-principle gyrokinetic numerical experiments investigating the isotopic dependence of energy confine-ment achieve a quantitative agreement with experimental empirical scalings, particularly in Ohmic and L-mode tokamak plasmas. Mitigation of turbulence radial electric field intensity | delta E-r| (2) and associated poloidal delta E x B fluctuating velocity with the radial correlation length l(cr) oc M-i(0.11) strongly deviating from the gyro-Bohm scaling is identified as the principal mechanism behind the isotope effects. Three primary contributors are classified: the deviation from gyro-Bohm scaling, zonal flow, and trapped electron turbulence stabilization. Zonal flow enhances isotope effects primarily through reinforcing the inverse dependence of turbulence decorrelation rate on isotope mass with omega(c )alpha M-i(-0.76) , which markedly differs from the characteristic linear frequency. The findings offer insights into isotope effects, providing critical implications for energy confinement optimization in tokamak plasmas.