Spectral Mixture Modeling with Laboratory Near-Infrared Data I: Insights into Compositional Analysis of Europa
Abstract
Europa's surface composition and physical characteristics are commonly constrained using spectral deconvolution through linear mixture (LM) modeling and radiative transfer-based (RT) intimate mixture modeling. Here, I compared the results of these two spectral modeling- LM versus RT- against laboratory spectra of water (H2O) ice and sulfuric acid octahydrate (SAO; H2SO4·8H2O) mixtures measured at near-infrared wavelengths (1.2-2.5 μm) with grain sizes of 90-106 μm (Hayes and Li, 2025). The modeled abundances indicate that the RT more closely reproduces the laboratory abundances, with deviations within 5% for both H2O ice and H2SO4·8H2O with 100 μm grains. In contrast, the LM shows slightly larger discrepancies, typically ranging from 5-15% from the true abundances. Interestingly, both LM and RT tend to consistently overestimate the abundance of H2SO4·8H2O and underestimate H2O ice across all mixtures. Nonetheless, when H2SO4·8H2O either dominates (>80% as observed on Europa's trailing hemisphere; Carlson et al. 2005) or is present only in trace amounts (10% on areas in Europa's leading hemisphere; Dalton III et al. 2013; Ligier et al. 2016), both the LM and RT render acceptable results within 10% uncertainty. Thus, spectral modeling using the RT is preferred for constraining the surface composition across Europa, although the LM remains viable in specific compositional regimes.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.