X-ray Spectroscopy via Temporal Decomposition

We present a novel way to fit solar flare X-ray spectra that offers more sensitivity to physical flare parameters than traditional approaches to spectroscopy. We decouple physically distinct emission types in solar flare X-ray spectra using timing behaviors, a technique we call time-decomposed spectroscopy. By fitting the shapes of particular time series to others across a time interval, we extract X-ray emission of distinct physical origins before any forward modeling. We perform spectroscopy on the original and time-decomposed spectra and find good agreement, with physical reasons for the few disagreements. In general, the time decomposition technique provides more precise results than those of traditional spectroscopy. The thermal and nonthermal energies are better constrained by more than an order of magnitude using the time decomposition approach, relative to traditional spectroscopy. We explain mathematically how and why the technique works using the multifractal formalism, and show that fractality is one way to choose appropriate light curves for this analysis. We speculate about applications to different wavelengths for solar data analysis, as well as applications to other physics subfields and domains.