We test a principle-level prediction from an age-dependent gravity framework using the public MaNGA DynPop DR17 catalogs. The prediction is that younger galaxies, at fixed stellar mass, should show larger mass-to-light discrepancies between dynamical and stellar-population estimates. We join three public DynPop products (JAM dynamical catalogs, stellar-population/star-formation-history catalogs, and circular-velocity-curve tables), apply quality cuts, and split 5,952 galaxies into eight stellar-mass bins of 744 galaxies each, then compare the youngest and oldest quartiles within each bin. The raw mass-to-light discrepancy (DML) is larger for young galaxies in 8/8 mass bins (observed SPS) and 6/8 bins (intrinsic SPS). A component decomposition shows that this raw result is mostly driven by the SPS denominator: older stellar populations have higher stellar mass-to-light ratios, as standard stellar-population synthesis predicts. Under a collinearity-free control model removing SPS mass-to-light, metallicity, and structural variables, a smaller dynamical residual persists in 7/8 mass bins across all three SPS control sets. Parametric dark-matter fractions do not show the same signal. The strongest controlled residual tracks the dust-carrying SPS definition. We present this as a proof of concept and invitation to specialist replication, not a detection claim.
Louis McGinty (Wed,) studied this question.
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