The causal structure of galactic astrophysics
This addresses the challenge of interpreting astrophysical data more accurately for researchers, though it is incremental as it adapts existing causal discovery methods to a new domain.
The authors tackled the problem of distinguishing physical mechanisms in astrophysics that are degenerate based on correlations alone by applying causal discovery to large datasets, demonstrating the method on ~500,000 low-redshift galaxies from the Nasa Sloan Atlas.
Data-driven astrophysics currently relies on the detection and characterisation of correlations between objects' properties, which are then used to test physical theories that make predictions for them. This process fails to utilise information in the data that forms a crucial part of the theories' predictions, namely which variables are directly correlated (as opposed to accidentally correlated through others), the directions of these determinations, and the presence or absence of confounders that correlate variables in the dataset but are themselves absent from it. We propose to recover this information through causal discovery, a well-developed methodology for inferring the causal structure of datasets that is however almost entirely unknown to astrophysics. We develop a causal discovery algorithm suitable for large astrophysical datasets and illustrate it on $\sim$5$\times10^5$ low-redshift galaxies from the Nasa Sloan Atlas, demonstrating its ability to distinguish physical mechanisms that are degenerate on the basis of correlations alone.