Abstract:
We investigate the interplay between morphology, specific star formation rate (sSFR), and local environment
using a sample of 7408 galaxies from the fourth-generation Sloan Digital Sky Survey Mapping Nearby Galaxies
at Apache Point Observatory survey. Our analysis spans stellar masses from dwarf to massive galaxies, enabling a unified view of how stellar mass and environment regulate galaxy evolution. Galaxies are classified by morphology (ellipticals (E), lenticulars (S0s), early-type spirals (ETS), and late-type spirals (LTS)) and local
environmental density, with star formation activity traced using sSFR. Low-mass galaxies (log(M /M ) < 10) are predominantly star-forming and dominated by LTS, whereas high-mass galaxies (log(M /M ) 10) are dominated by ETS and are largely quenched. By separating dwarf (log(M /M ) 9.5) and intermediate-mass galaxies (9.5 < log(M /M ) < 10), we find that dwarf galaxies remain predominantly star-forming with only weak environmental dependence, whereas intermediate-mass galaxies exhibit clearer environmental trends toward quenching. Using the D4000 index as a tracer of long-term stellar population aging, we further show that dwarf E and S0s host systematically younger stellar populations than their intermediate-mass counterparts, implying reduced quenching efficiency and more gradual environmental processing in the dwarf regime. This distinction is not evident among spiral galaxies, whose stellar population properties are comparatively insensitive to the dwarf
versus nondwarf classification. Overall, these results indicate that the commonly defined low-mass galaxy
population is not homogeneous and that dwarf and intermediate-mass galaxies show systematically different
evolutionary trends. Treating them separately is therefore essential for interpreting galaxy evolution in the lowmass regime.