Usui, T.; Sakarchi, J.; Duchen, P.; Hart, S.; Turcotte, M.; Xu, S.; Angert, A.; Germain, R. M.

Despite the prevailing view that ecological divergence drives speciation, we know little about when or how nascent lineages evolve the ecological differences needed to coexist upon secondary contact. Here, we apply ecological coexistence theory to quantify the potential for coexistence among 126 allopatric lineages of the globally distributed duckweed Spirodela polyrhiza. Using competition experiments simulating secondary contact, we found that rapid accumulation of niche differences stabilized coexistence to permit sympatry among potentially interbreeding lineages. Competition against sister-species Spirodela intermedia further showed that niche differences accumulate more slowly post-speciation, revealing that niche differences enabling coexistence evolve well before timescales at which speciation is complete. Our findings suggest that rapid coexistence may thus contribute to time-lags in speciation, shaping both the origin and maintenance of biodiversity.