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We present high-resolution (~8 km s^-1^) spectra of the QSO Q0201+365 obtained with HIRES, the echelle spectrograph on the 10 m W. M. Keck Telescope. Although we identify over 80% of the absorption features and analyze several of the more complex metal-line systems, we focus our analysis on the damped Lyα system at z = 2. 462. Ionization simulations suggest the hydrogen in this system is significantly neutral and all of the observed metals are predominantly singly ionized. We measure accurate abundances for Fe, Cr, Si, and Ni and place a lower limit on the abundance of Zn: Fe/H = -0. 830 +/- 0. 051, Cr/H = -0. 902 +/- 0. 064, Si/H = -0. 376 +/- 0. 052, Ni/H = -1. 002 +/- 0. 054, and Zn/H > -0. 562 +/- 0. 064. We give evidence suggesting the actual Zn abundance is Zn/H~ -0. 262, implying the highest metallicity observed at a redshift z > 2. The relative abundances of these elements remains constant over essentially the entire system (~150 km s^-1^ in velocity space), suggesting it is well mixed. Furthermore, we use the lack of abundance variations to infer properties of the dust responsible for element depletion. Finally, we discuss the kinematic characteristics of this damped Lyα system, comparing and contrasting it with other systems. The low-ion line profiles span ~200 km s^-1^ in velocity space and have an asymmetric shape with the strongest feature on the red edge. These kinematic characteristics are consistent with a rotating disk model.
Prochaska et al. (Tue,) studied this question.
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