Experimental Tests of the Theory of Poloidal Rotation in the DIII-D Tokamak

The goal of this dissertation was to develop a novel technique for measuring ion poloidal rotation and then using that technique to test poloidal rotation theories. The new poloidal rotation diagnostic has been developed on the DIII-D tokamak. This diagnostic uses charge exchange recombination spectroscopy to measure toroidal rotation on the high- and low-field side of the tokamak midplane to determine the poloidal rotation from a divergence-free description of flow within flux-surfaces. Measurements are made such that no atomic physics calculations are needed to account for the energy dependence of the charge exchange cross section. New techniques for creating magnetic equilibrium reconstructions and performing the spatial calibration have been developed to ensure the accuracy of this new diagnostic. Measurements are made in the core of DIII-D where the spatial resolution is significantly improved when compared to the direct measurement of the poloidal rotation.;This diagnostic has been used to investigate impurity poloidal rotation in the core of a variety of plasmas. For the first time on DIII-D, mean poloidal flow spin-up coincident with the formation of an internal transport barrier has been observed. The various measurements of poloidal rotation have been compared with theoretical predictions. Disagreement with neoclassical calculations have been found in H-mode, QH-mode, and the core of internal transport barrier plasmas. The effect of turbulent driven Reynolds stress and fast-ion friction have been investigated as well, and it has been determined that either of these effects, on their own, is insufficient to explain the discrepancy with neoclassical predictions. Modeling results indicate that these effects that are not included in standard neoclassical calculations are important for calculating the poloidal rotation.