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Center for Nonlinear Studies |
Superluminous supernova (SLSN) lightcurves exhibit a superior diversity compared to their regular luminosity counterparts in terms of rise and decline timescales, peak luminosities and overall shapes. It remains unclear whether this striking variety arises due to a dominant power input mechanism involving many underlying parameters, or due to contributions by different progenitor channels. In this work, we propose that a systematic quantitative study of SLSN lightcurve timescales and shape properties, such as symmetry around peak luminosity, can be used to characterize these enthralling stellar explosions. We find that applying clustering analysis on the properties of model SLSN lightcurves, powered by either a magnetar spin down or a supernova ejecta-circumstellar interaction mechanism, can yield a distinction between the two, especially in terms of lightcurve symmetry. We show that most events in the observed SLSN sample with well- constrained lightcurves and early detections strongly associate with clusters dominated by the circumstellar interaction models. Magnetar spin down models also show association at a lower degree but have difficulty in reproducing fast evolving and fully symmetric lightcurves. We believe this is due to the truncated nature of the circumstellar interaction shock energy input as compared to decreasing but continuous power input sources like magnetar spin down and radioactive Ni-56 decay. Our study demonstrates the importance of clustering analysis in characterizing SLSNe based on high cadence photometric observations that will be made available in the near future by surveys like LSST, ZTF and Pan- STARRS.
Host: Wes Even