Rice plants cope with flash floods using either an "escape strategy" involving rapid shoot elongation or a "quiescence strategy" involving survival underwater with minimal activity. In previous studies, leaf elongation and growth in shoot biomass during complete submergence were greater in O. glaberrima than in O. sativa. To clarify the mechanism of rapid shoot elongation under submergence of O. glaberrima, we studied the effects of root aerenchyma formation and photosynthetic activity of leaves under submergence on post-submergence recovery. O. glaberrima cv. TOG6876, O. sativa cv. REXMONT and O. sativa cv. MILYANG23 were used. TOG6876 and REXMONT exhibit shoot elongation in response to submergence. MILYANG23 elongated slowly when submerged. Twenty-day old seedlings were submerged for 7 days. During submergence, the shoot elongation rates were higher in TOG6876 than in REXMONT and the lowest in MILYANG23. In submerged TOG6876 and MILYANG23, the increase of shoot biomass during post-submergence was significantly larger than in REXMONT. During submergence, the maximal quantum yield of photosystem II (Fv/Fm) of the upper developed leaf decreased earlier in REXMONT than in TOG6876 and MILYANG23. At 3 days after submergence, root aerenchyma formation was observed in TOG6876 and REXMONT but not in MILYANG23. The physiological mechanism responsible through the chlorophyll breakdown and photodamage in submerged leaves of O. glaberrima might be different from the shoot-elongation cultivar in O. sativa.