Kepler, CoRoT and future space missions should give us an estimate of how common small, rocky planets are in the galaxy. But there is much we can do from Earth, as Jay Farihi told the Royal Astronomical Society’s 2010 meeting today. Farihi’s team used data from the Sloan Digital Sky Survey to conclude that rocky worlds emerge around at least a small percentage of A- and F-class stars. The method: Analyze the position, motion and spectra of white dwarfs found in the SDSS survey. Farihi was interested in the presence of elements heavier than hydrogen and helium in the stellar atmospheres.

Finding calcium, magnesium or iron in the atmosphere of a white dwarf is, Farihi believes, evidence of rocky debris, and the new work shows that at least 3 percent and as much as 20 percent of all white dwarfs may be contaminated in this way. Such elements should have sunk below the photosphere in the high gravity of a white dwarf, leading to the belief that any visible contamination must be the result of external causes. Farihi sees the heavier elements as debris left over from what once may have been planetary systems containing terrestrial worlds around these stars.

Assuming this is the case, then, we can take this debris as evidence for the existence of such systems around A- and F-class stars. Moreover, the composition of the debris shows that many of these stars are polluted with material containing water. Says Farihi:

“In our own Solar System with at least one watery, habitable planet, the asteroid belt – the leftover building blocks of the terrestrial planets – is several percent water by mass. From our study of white dwarfs, it appears there are basic similarities found among asteroid-like objects around other stars; hence it is likely a fraction of these white dwarfs once harbored watery planets, and possibly life.”

Why focus on planets or planetesimals as the source of the heavy metal contamination? Farihi demonstrates in the paper on this work that there are no correlations between calcium abundances and the distribution of these stars in relation to interstellar materials that could have been the source. Two thirds of the stars under study are located above the galactic gas and dust layer, and study of their motion shows long residence in areas where interstellar materials are all but absent. Assuming planetary materials as the cause of this signature, the paper adds:

…at least 3.5% of white dwarfs appear to be polluted by circumstellar matter, the remains of rocky planetary systems. This translates directly into a similar lower limit for the formation of terrestrial planets at the main-sequence progenitors of white dwarfs, primarily A- and F-type stars of intermediate mass. While this fraction is likely to be significantly higher…, it is difficult to quantify without a commensurate examination of all the cool SDSS white dwarfs, which is beyond the scope of this paper. The appearance of hydrogen in DZA stars suggests a common origin for both heavy elements and hydrogen, and indicates DZA star pollution by water-rich minor planets may be semicontinuous on Myr timescales.

White dwarf spectral classification schemes use an initial letter D followed by letters describing secondary features of the spectrum, which is what the DZA reference above is all about. More on white dwarf classifications here.

The significance of this work is that it rules out the interstellar medium as the source for the metal pollutants in white dwarfs like these. Two conclusions follow: At least a small percentage of A- and F-class stars build terrestrial planets (‘terrestrial’ meaning small, rocky worlds) whose debris supplies the heavy elements, and “…the pattern of hydrogen abundances in DZ stars is likely a reflection of the diversity of water content in extrasolar planetesimals.”

The paper is Farihi et al., “Rocky planetesimals as the origin of metals in DZ stars,” accepted by Monthly Notices of the Royal Astronomical Society (abstract).

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