Improved Companion Mass Limits for Sirius A with Thermal Infrared Coronagraphy Using a Vector-apodizing Phase Plate and Time-domain Starlight-subtraction Techniques

We use observations with the infrared-optimized Magellan Adaptive Optics (MagAO) system and Clio camera in 3.9 mu m light to place stringent mass constraints on possible undetected companions to Sirius A. We suppress the light from Sirius A by imaging it through a grating vector-apodizing phase plate coronagraph with a 180 degrees dark region (gvAPP-180). To remove residual starlight in postprocessing, we apply a time-domain principal-components-analysis-based algorithm we call PCA-Temporal, which uses eigen time series rather than eigenimages to subtract starlight. By casting the problem in terms of eigen time series, we reduce the computational cost of postprocessing the data, enabling the use of the fully sampled data set for improved contrast at small separations. We also discuss the impact of retaining fine temporal sampling of the data on final contrast limits. We achieve postprocessed contrast limits of 1.5 x 10(-6)-9.8 x 10(-6) outside of 0.'' 75, which correspond to planet masses of 2.6-8.0 M (J). These are combined with values from the recent literature of high-contrast imaging observations of Sirius to synthesize an overall completeness fraction as a function of mass and separation. After synthesizing these recent studies and our results, the final completeness analysis rules out 99% of >= 9 M (J) planets from 2.5 to 7 au.

Automated summary

Using Magellan Adaptive Optics (MagAO) system and Clio camera in infrared light, we set strict mass constraints on potential undetected companions to Sirius A. Employing the grating vector-apodizing phase plate coronagraph and the eigen time series approach, we achieve improved contrast and computational efficiency in postprocessing the data. By combining these results with previous studies, we can conclude that 99% of >= 9 M (J) planets are ruled out within the range of 2.5 to 7 au.