Spectral features of presolar diamonds in the laboratory and in carbon star atmospheres

TL;DR

This study measures the spectral features of presolar diamonds from meteorites and CVD samples, incorporating them into stellar models to understand their formation and role in carbon star atmospheres.

Contribution

It provides the first laboratory measurements of presolar diamond absorption spectra and integrates these into stellar atmosphere models to explore their formation and influence.

Findings

Diamonds cause heating of upper stellar layers.

Diamonds reduce C2H2 abundance in models.

Spectral features of diamonds are weak but potentially important for dust nucleation.

Abstract

Laboratory analyses on fine-grained diamond residues from primitive meteorites have shown that nano-diamonds represent the most abundant form of presolar dust preserved in meteoritic samples. The presolar diamonds carry isotopic anomalies which indicate a very complex formation history. Several groups of diamonds may exist with origin in different types of stars. In order to identify the sites of formation observationally, we have extracted presolar diamonds from the Allende meteorite and measured the monochromatic absorption coefficient in a form which is useful for stellar atmosphere calculations. The monochromatic absorption coefficient was measured in the wavelength ranges 400--4000 cm-1 (2.5--25 micron) and 12200--52600 cm-1 (190--820 nm). We have made identical laboratory measurements on CVD diamonds as on the meteoritic diamonds, in order to get a more solid basis for the interpretation of the diamond spectrum. The monochromatic absorption coefficient for the presolar diamonds was incorporated in self-consistent carbon star photospheric models. The main influence of the diamond dust in our photospheric models is a heating of the upper photospheric layers and a reduction of the C2H2 abundance. Due to the relatively small absorption coefficient of the diamonds compared to other stellar dust grains, their spectral appearance is weak. However, the weak interaction of the diamonds with the radiation field may give them an important role in the dust nucleation process. The gas pressure will stay high and the gas will be much closer to hydrostatic equilibrium during possible diamond nucleation than is normally the case in dust forming stellar regions, and therefore allow ample time for the nucleation process.