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Identifying and Characterizing Very Low-mass Spectral Blend Binaries with Machine Learning Methods
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Identifying and Characterizing Very Low-mass Spectral Blend Binaries with Machine Learning Methods
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Journal Article
Identifying and Characterizing Very Low-mass Spectral Blend Binaries with Machine Learning Methods
2026
Overview
We present an approach to identifying and characterizing unresolved, very low mass spectral blend binaries composed of late M, L, and T dwarfs using machine learning methodologies. We generated and evaluated a series of hierarchical random forest models to distinguish spectral blends from single very low-mass dwarfs, and to classify their primary and secondary components. Models were trained on a sample of single and synthesized binary templates generated from empirical spectra. We explored various aspects of the design of our models and found that models trained on a full range of single and binary combinations have the best performance for identification and component classification. These models achieve binary identification recall and precision of ≳85%, median component classification errors of ≲ 0.1 subtypes, and systematic classification uncertainties of ≲ 1 subtype, outperforming index-based methods in terms of fidelity, range, and speed. Optimal performance is achieved for binaries composed of L and T dwarf primaries and late L and T dwarf secondaries. When applied to the spectra of previously confirmed very low-mass binaries, model performance is degraded due to the prevalence of systems with similar component types, but remains high in the optimal performance range. We propose potential improvements to these models, which can be used to explore binary populations among the thousands to millions of very low-mass stars and brown dwarfs anticipated with large-scale spectral surveys such as SPHEREx and Euclid.
Publisher
IOP Publishing
Subject
