New nickel opacities and their impact on stellar models

TL;DR

This study introduces new nickel opacity data computed with the SCO-RCG code and assesses their impact on stellar models, revealing significant differences at lower temperatures and potential effects on pulsation driving.

Contribution

The paper provides newly computed nickel monochromatic cross sections and evaluates their influence on stellar opacity and pulsation models, improving upon previous extrapolated data.

Findings

Nickel Rosseland opacities are up to six times higher at lower temperatures with new data.

The global stellar opacity in the Z-bump is only marginally affected, but pulsation driving may be impacted.

Discrepancies between new and previous opacity data vary with temperature and data source.

Abstract

The chemical element nickel is of particular interest in stellar physics. In the layers in which the Fe-peak elements dominate the mean opacity (the so-called Z-bump), Ni is the second contributor to the Rosseland opacity after iron, according to the Opacity Project data. Reliable nickel cross sections are therefore mandatory for building realistic stellar models, especially for main-sequence pulsators such as $\beta$ Cep and slowly pulsating B stars, whose oscillations are triggered by the $\kappa$-mechanism of the Fe-peak elements. Unfortunately, the Opacity Project data for Ni were extrapolated from those of Fe, and previous studies have shown that they were underestimated in comparison to detailed calculations. We investigate the impact of newly computed monochromatic cross sections on the Rosseland mean opacity of Ni and on the structure of main-sequence massive pulsators. We compare our results with the widely used Opacity Project and OPAL data. Monochromatic cross sections for Ni were obtained with the SCO-RCG code. The Toulouse-Geneva evolution code was used to build the stellar models. With the new data, the Rosseland opacities of Ni are roughly the same as those of the Opacity Project or OPAL at high temperatures ($\log\ T>6$). At lower temperatures, significant departures are observed; the ratios are up to six times higher with SCO-RCG. These discrepancies span a wider temperature range in the comparison with OPAL than in comparison with the Opacity Project. For massive star models, the results of the comparison with a structure computed with Opacity Project data show that the Rosseland mean of the global stellar mixture is only marginally altered in the Z-bump. The maximum opacity is shifted towards slightly more superficial layers. A new maximum appears in the temperature derivative of the mean opacity, and the driving of the pulsations should be affected.